The subject matter of the teachings described herein relates generally to surface cleaning apparatuses. In one embodiment, the apparatus is an upright surface cleaning apparatus and is optionally operable in a floor cleaning mode and an above floor cleaning mode.
The following is not an admission that anything discussed below is part of the prior art or part of the common general knowledge of a person skilled in the art.
Various types of surface cleaning apparatus are known including upright vacuum cleaners and extractors. Typically, an upright vacuum cleaner includes an upper section, including an air treatment member such as one or more cyclones and/or filters, drivingly mounted to a surface cleaning head. An up flow conduit is typically provided between the surface cleaning head and the upper section. In some such vacuum cleaners, a spine, casing or backbone extends between the surface cleaning head and the upper section for supporting the air treatment member. The suction motor may be provided in the upper section.
U.S. Pat. No. 7,188,388 (Best) discloses a multi-use vacuum cleaner with a detachable cyclonic vacuum module. The vacuum cleaner may be used as an upright vacuum cleaner when the detachable vacuum module is mounted to the base or the detachable vacuum module may be detached and used by itself. The detachable vacuum module includes a vacuum motor, a motor driven fan, a cyclonic dirt separator and a hose.
US patent publication No. US 2015/0096143 (Conrad) discloses an upright vacuum cleaner with a removable hand vacuum cleaner. The upright vacuum cleaner may be used in different cleaning modes including use as an upright vacuum cleaner when the hand vacuum cleaner is mounted to the handle.
This summary is intended to introduce the reader to the more detailed description that follows and not to limit or define any claimed or as yet unclaimed invention. One or more inventions may reside in any combination or sub-combination of the elements or process steps disclosed in any part of this document including its claims and figures.
A surface cleaning apparatus, such as an upright surface vacuum cleaner, may be used to clean floors and other surfaces. When in use, it sometimes desirable to clean beneath furniture and other objects that are resting on the floor, such as beds, couches, tables and the like. Often, the space beneath the furniture (i.e. the distance between the floor and the lower surface of furniture) can be relatively narrow, and may be about 6-8 inches in some instances. Configuring a vacuum cleaner to help clean underneath such furniture, preferably using its primary surface cleaning head, may help users clean hard to access areas.
Optionally, a vacuum cleaner can be configured so that its surface cleaning head can fit underneath furniture, and can have a height that is less than the height beneath the furniture. Using such a configuration may allow the vacuum cleaner to extend under furniture up to the depth (front to back) of the surface cleaning head. However, the upper section will limit the extent to which the surface cleaning head can extend under furniture. For example, in Best, the surface cleaning head is not operable when the detachable cyclonic vacuum module has been removed from the upright section. Therefore, when the vacuum cleaner is used to clean under furniture, the extent to which the cleaning head may pass under furniture is limited by the height of the surface cleaning head (from the floor to the upper end of the surface cleaning head) and the depth (front to back) of the upright section.
In Conrad, in one mode, the hand vacuum cleaner may be removed from the handle but may remain in air flow communication with the surface cleaning head via a flexible hose. In this mode, the depth of the upright section (front to back) is reduced since the hand vacuum cleaner has been removed. Therefore, the extent to which the depth of the upright section inhibits cleaning under furniture is reduced. However, this design requires a user to remove and carry the hand vacuum cleaner
In accordance with this disclosure, an upright surface cleaning apparatus, such as an upright vacuum cleaner, is configured so that the surface cleaning head and at least a portion, and optionally all, of the upright section of the vacuum cleaner is sized to fit beneath furniture having a lower surface positioned close to the floor, such as a bed or a couch. Preferably, the portion of the upright section that can fit underneath the furniture includes a cleaning unit provided on the upper section, which itself may include an air treatment member assembly and suction motor. Configuring the cleaning unit to fit beneath furniture while mounted to the upright section, and making it moveable into a suitable orientation/alignment so as to be moved beneath the furniture, allows part if not all of the upright section to be positioned beneath furniture such that the surface cleaning head may clean the entire floor that underlies furniture. Accordingly, a user may be able to extend a sufficient portion of the upright section of the vacuum cleaner beneath a couch such that the entire area under the couch can be cleaned without requiring the couch to be moved, or the use of secondary cleaning tools like wands and/or crevice tools.
When the upright section is rotated rearwardly into an orientation suitable for low profile cleaning (i.e. beneath furniture), the upright section with the air treatment member may extend substantially horizontally from the surface cleaning head (i.e., the upright section may have been rotated rearwardly about 90°). Therefore, if the upright section has a small depth in the forward/backward direction, then the upright section will have a relatively short height in the upward direction when oriented for low profile cleaning. In accordance with one aspect of this disclosure, the depth in the forward/backward direction is generally reduced and the width of the upright section in the left/right, lateral direction may be adjusted so as to be greater than the depth so as to provide a vacuum cleaner which has good dirt separation efficiency and suitable dirt storage capacity for use to clean a house. Optionally, the cleaning unit may have a generally rectangular, slab like configuration, such that it has a generally rectangular shape in a top plan view.
To help reduce the depth of the upright section, components of the upright section of the surface cleaning apparatus may be at least partially, and optionally entirely, overlapped with each other. For example, portions of the air flow path may be positioned behind and/or beside portions of the air treatment member assembly. The suction motor may be positioned below, and may underlie at least portions of the air treatment member assembly (including for example, a cyclone chamber and/or a dirt collection chamber). Configuring the components vertically in this manner may help reduce the front/back depth of the cleaning unit. Positioning the suction motor below the air treatment member assembly may help lower the centre of gravity of the upright section, which may help maneuverability. Optionally, the air inlet of the suction motor may be substantially aligned with the air outlet of the air treatment member (such as a cyclone chamber), which may help reduce the overall size of the cleaning unit and/or the length and complexity of the air flow path therethrough.
Alternately, or in addition, to help reduce the depth of the upright section/cleaning unit of the surface cleaning apparatus, the amount of material/housings that are provided in front of or behind the operating components (such as the air treatment member assembly and/or the suction motor) may be reduced. For example the cleaning unit (which may comprise one or more air treatment members and the suction motor) may not be provided with a surrounding support structure. Instead, the cleaning unit may itself be rotatably mounted to the surface cleaning head and may have the drive handle attached thereto.
Alternately, or in addition, the upright section may be configured such that the air treatment member assembly forms the front and/or rear face of the cleaning unit, and may extend almost the entire depth of the cleaning unit (and optionally the entire depth), such that the overall depth of the cleaning unit may be the depth of the air treatment member assembly. This may help provide an air treatment member assembly that has an acceptable size and dirt collection volume, while keeping the overall depth in an acceptable range. Similarly, the components may be sized such that the depth of the air treatment member assembly is not substantially greater than the depth (i.e. diameter if vertically oriented) of the suction motor, and vice versa. For example, the depth of the air treatment member assembly may be the same as the diameter of the suction motor ±2 inches. This may allow both components to be an acceptable size, while helping to keep the overall depth of the cleaning unit in an acceptable range.
If the dirt collection region in the apparatus is external the air treatment member, e.g. a dirt collection chamber that is external a cyclone chamber, some and preferably all of the dirt collection region may be positioned laterally beside the cyclone chamber. Accordingly, the dirt collection region may not be positioned forward of the forward most part of the air treatment member and/or rearward of the rearward most part of the air treatment member, thereby reducing the depth of the cleaning unit. The dirt collection region can be located on only one side lateral of the air treatment member, or alternatively dirt collection regions (either discrete regions or portions of a common region) may be positioned on both lateral sides of the cyclone chamber. The volume of the portions of the dirt collection region that are laterally beside the cyclone chamber may be more than 50%, 60%, 70%, 80% or 90% of the total volume of the dirt collection region. Optionally, the dirt outlet on the cyclone chamber may be on a lateral side of the cyclone chamber, and be in communication with the laterally positioned dirt collection chamber.
Optionally, portions of the air flow path, including portions of the above floor cleaning assembly may be configured in a non-circular shape, and oriented so that their depth in the forward/rearward direction is less than their length or width. This may help reduce the overall depth of the apparatus while maintaining, and may help nest portions of the air flow path with other portions of the apparatus.
Optionally, the apparatus may include additional filters in the air flow path between a dirty air inlet and a clean air outlet, including one or more pre-motor filter(s) and post-motor filter(s). The suction motor may be laterally centered in the cleaning unit, and a post-motor filter and clean air outlet may be provide on at least one, and optionally both of the lateral sides of the suction motor. If on both sides, the cleaning unit may include two clean air outlets, each preceded by a respective post-motor filter. Providing the post-motor filters and clean air outlets on the lateral sides of the suction motor, as opposed to forward or rearward of the suction motor, may help reduce the depth of the cleaning unit and upright section. Optionally, providing a post-motor filter below the suction motor as an alternative to the laterally positioned filters, or in addition thereto, may also help provide a desired amount of filtration while helping to control the overall depth.
Preferably, to help move the upright section of the vacuum cleaner beneath an object, at least a portion of the upright section, such as the cleaning unit, may be moveable so as to be oriented into a low profile, generally horizontal position—such that the cleaning unit is substantially parallel to the floor being cleaned. That is, the vacuum cleaner may be configurable in a storage position (where the upright section is generally upright), an upright mode floor cleaning position (where the upright section is inclined rearwardly from the surface cleaning head) and a low profile floor cleaning mode (in which at least the cleaning unit portion of the upright section is parallel or at least substantially parallel to the surface being cleaned). This may help the cleaning unit to be moved beneath the object.
To move the cleaning unit into the low profile cleaning position, the drive handle may be bendable or otherwise reconfigurable. This may allow a user to continue holding the same grip portion in the different modes, and may help reduce the need to lower the grip portion down to the floor by requiring a user to bend over. Instead, the grip portion may remain at a more comfortable position, while allowing the cleaning unit to be oriented horizontally. For example, the handle may include a pivot joint or other suitable mechanism, whereby an upper handle portion may be pivotal relative to the cleaning unit. The pivot joint can preferably be lockable, to help a user secure the handle in one or more of its possible positions.
To help facilitate above floor cleaning, the surface cleaning apparatus may include an above floor cleaning assembly, which may optionally include a flexible hose and a generally rigid cleaning wand. The wand and hose may form part of the air flow path in the floor cleaning modes as well (and be detached for above floor cleaning), or alternatively may not form part of the air flow path in the floor cleaning mode.
In accordance with a first aspect of this disclosure, a surface cleaning apparatus is provided wherein in top plan view, the first and second laterally opposed sides and one of the front side and the rear side of the air treatment member assembly is generally rectangular in top plan view. An advantage of this design is that positioning components of the cleaning unit is this configuration reduces the depth of the cleaning unit. For example, instead of positioning a dirt collection chamber around a cyclone chamber, the dirt collection chamber or chambers may be positioned laterally beside the cyclone chamber and the dirt collections chamber(s) may be square or rectangular in top plan view when the upright section is in the upright position.
In accordance with this aspect, there is provided an upright surface cleaning apparatus having a surface cleaning head with a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be mounted to the surface cleaning head and may be moveable between a generally upright position and a rearwardly inclined in use position. The upright section may include an air treatment member assembly and a suction motor. The air treatment member assembly may have a longitudinally extending air treatment member assembly axis, first and second laterally opposed sides, a front side and a rear side. The air treatment member assembly may include an air treatment member and a dirt collection region that is positioned laterally from the air treatment member (i.e., lateral being a direction to the right or left side of the surface cleaning apparatus from the perspective of a user standing behind the surface cleaning apparatus and facing forwardly towards the front of the surface cleaning head.). The suction motor may be positioned below at least one of the air treatment member and the dirt collection region. The first and second laterally opposed sides and at least one of the front side and the rear side of the air treatment member assembly may be generally rectangular in top plan view when the upright section is in the upright position.
The other of the one of the front side and the rear side of the air treatment member assembly may have a portion that extends outwardly in a direction of the central longitudinal axis of the surface cleaning head when the upright section is oriented to extend generally upwardly from the surface cleaning head. The portion may also extend along a length of the air treatment member assembly in a direction of the longitudinally extending air treatment member assembly axis.
The suction motor may underlie at least one of the air treatment member and the dirt collection region. The inlet of the suction motor may be aligned with an air outlet of the air treatment member.
The air treatment member may have a dirt outlet provided on a lateral side of the air treatment member.
A depth of the air treatment member assembly in a direction of the central longitudinal axis may be about equal to a diameter of the suction motor, and/or may be the same as the diameter of the suction motor ±2 inches.
A maximum depth of the upright section in a direction of the central longitudinal axis may be 6 inches or less, and may be 4 inches or less.
A depth of the air treatment member in a direction of the central longitudinal axis may be about equal to a diameter of the suction motor.
The depth of the air treatment member assembly may be the same as the diameter of the suction motor ±2 inches.
A maximum depth of the upright section in a direction of the central longitudinal axis may be 6 inches or less, and may be 4 inches or less.
In accordance with this aspect of the teachings described herein, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be mounted to the surface cleaning head and may be moveable between a generally upright position and a rearwardly inclined in use position. The upright section may include a cyclone bin assembly and a suction motor. The cyclone bin assembly may have a longitudinally extending cyclone bin assembly axis, first and second laterally opposed sides, a front side and a rear side, the air treatment member assembly comprising a cyclone and a dirt collection chamber external to and positioned laterally from the cyclone. The suction motor may be positioned below at least one of the cyclone and the dirt collection chamber. The first and second laterally opposed sides and one of the front side and the rear side of the cyclone bin assembly may be generally rectangular in top plan view when the upright section is in the upright position.
The other of the one of the front side and the rear side of the cyclone bin assembly may have a portion that extends outwardly in a direction of the central longitudinal axis of the surface cleaning head when the upright section is oriented to extend generally upwardly from the surface cleaning head. The portion may also extend along a length of the cyclone bin assembly in a direction of the longitudinally extending cyclone bin assembly axis. The portion may be rounded in transverse section.
An inlet of the suction motor may be aligned with an air outlet of the cyclone.
The cyclone may have a laterally directed dirt outlet.
A diameter of the cyclone may be about equal to a diameter of the suction motor.
A maximum depth of the upright section in a direction of the central longitudinal axis may be 6 inches or less, and may be 4 inches or less.
In accordance with this aspect of the teachings described herein, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be mounted to the surface cleaning head and may be moveable between a generally upright position and a rearwardly inclined in use position. The upright section may include an air treatment member assembly and a suction motor positioned below the air treatment member assembly. The air treatment member assembly may have a longitudinally extending air treatment member assembly axis, first and second laterally opposed sides, a front side and a rear side. The air treatment member assembly may be generally rectangular in top plan view when the upright section is in the upright position other than at least one of the front and rear sides having an outward protrusion that extends in the direction of the longitudinally extending air treatment member assembly axis.
A maximum depth of the upright section in a direction of the central longitudinal may be is 6 inches or less, and may be 4 inches or less.
In accordance with another aspect of this disclosure, a surface cleaning apparatus has an upper section wherein components are vertically aligned. For example, a push handle of the upper section may be positioned such that the drive axis extends through the air treatment member assembly and the suction motor housing and a rotatable mount of the upper section underlies the upright section when the upright section is in the generally upright position. An advantage of this design is the depth of the upper section may be reduced while providing a maneuverable surface cleaning head.
In accordance with this aspect, there is provided an upright surface cleaning apparatus that may include a surface cleaning head having a front end, a rear end, rear wheels, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may have a cleaning unit and a push handle. The cleaning unit may include an air treatment member assembly having an air treatment member and a suction motor housing having a suction motor therein. The push handle may include a longitudinally extending member having a longitudinally extending drive axis and a hand grip portion provided at an upper end of the longitudinally extending member wherein the drive axis extends through the air treatment member assembly and the suction motor housing. A rotatable mount may rotatably mount the upright section with respect to the surface cleaning head about an upright section axis wherein the rotatable mount underlies the upright section when the upright section is in the generally upright position.
Axis of rotation of the rear wheels may underlie the air treatment member assembly when the upright section is in the generally upright position.
The suction motor may underlie the air treatment member assembly when the upright section is in the generally upright position.
The drive axis may be located a distance from the front end of the surface cleaning head that is generally the same as a distance the rotatable mount is located from the front end.
The air treatment member assembly may also include a dirt collection region exterior to and laterally spaced with respect to the air treatment member and an up flow duct that is positioned behind the dirt collection region.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of the dirt collection region in a direction of the central longitudinal axis. A rear side of the up flow duct may be located proximate a rear side of the air treatment member.
The air treatment member may have a depth in a direction of the central longitudinal axis that is generally equal to a depth of the dirt collection region in a direction of the central longitudinal axis and a depth of the up flow duct in a direction of the central longitudinal axis.
The push handle may be rotatable relative to the cleaning unit about a laterally extending axis wherein the laterally extending axis is positioned above the air treatment member when the upright section is in the generally upright position.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, rear wheels, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may have a cleaning unit and a push handle. The cleaning unit may include an air treatment member assembly having an air treatment member, a dirt collection region exterior to and laterally spaced with respect to the air treatment member and a suction motor housing having a suction motor therein. The suction may be is beneath the air treatment member assembly when the upright section is in the generally upright position. An up flow duct may be positioned behind the dirt collection region. The push handle may include a longitudinally extending member having a longitudinally extending drive axis and a hand grip portion provided at an upper end of the longitudinally extending member. A rotatable mount may rotatably mount the upright section with respect to the surface cleaning head about an upright section axis. The rotatable mount may underlie the upright section when the upright section is in the generally upright position.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of the dirt collection region in a direction of the central longitudinal axis and a rear side of the up flow duct is located proximate a rear side of the air treatment member.
The air treatment member may have a depth in a direction of the central longitudinal axis that is generally equal to a depth of the dirt collection region in a direction of the central longitudinal axis and a depth of the up flow duct in a direction of the central longitudinal axis.
An axis of rotation of the rear wheels may underlie the air treatment member assembly when the upright section is in the generally upright position.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, rear wheels, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. A cleaning unit may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The cleaning unit may include a front face having a forward most portion provided in a front plane that is transverse to a forward direction of travel of the surface cleaning head, a rear face having a rearward most portion provided in a rear plane that is transverse to the forward direction. An air treatment member assembly may include an air treatment member, a dirt collection region exterior to the air treatment member and a suction motor therein. The suction motor may underlie the air treatment member assembly when the cleaning unit is in the generally upright position. A push handle may have a longitudinally extending member with a longitudinally extending drive axis and a hand grip portion provided at an upper end of the longitudinally extending member. A rotatable mount may rotatably mount the upright section with respect to the surface cleaning head about an upright section axis. The air treatment member, the dirt collection region an axis of rotation of the rear wheels and the rotatable mount may be located between the front and rear planes.
The rotatable mount may underlie the air treatment member assembly when the cleaning unit is in the generally upright position.
The axis of rotation of the rear wheels may underlie the air treatment member assembly when the cleaning unit is in the generally upright position.
The suction motor may underlie the air treatment member assembly when the cleaning unit is in the generally upright position.
The drive axis may be located a distance from the front end of the surface cleaning head that is generally the same as a distance the rotatable mount is located from the front end.
The dirt collection region may be laterally spaced with respect to the air treatment member and an up flow duct is positioned behind the dirt collection region.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of the dirt collection region in a direction of the central longitudinal axis and a rear side of the up flow duct is located proximate a rear side of the air treatment member.
The air treatment member may have a depth in a direction of the central longitudinal axis that is generally equal to a depth of the dirt collection region in a direction of the central longitudinal axis and a depth of the up flow duct in a direction of the central longitudinal axis.
A maximum depth of the cleaning unit in a direction of the central longitudinal axis may be 6 inches or less and may be 4 inches or less.
In accordance with another aspect of this disclosure, a surface cleaning apparatus is provided with a surface cleaning head wherein the rear wheels of the surface cleaning head have a diameter that is greater than a depth of the portion of the dirt collection region that is exterior to the air treatment member. An advantage of this design is the depth of the upper section may be reduced while providing a maneuverable surface cleaning head.
In accordance with this aspect, there is provided an upright surface cleaning apparatus that may have a surface cleaning head having a front end, a rear end, rear wheels having a diameter, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may include an air treatment member assembly including an air treatment member and a dirt collection region. At least a portion of the dirt collection region may be exterior to and laterally spaced with respect to the air treatment member. A housing may include a suction motor therein. The diameter of the rear wheels may be greater than a depth of the portion of the dirt collection region in a direction of the central longitudinal axis.
The housing may have a motor housing portion which houses the suction motor and a lateral portion laterally spaced from the motor housing portion. The lateral portion may have a depth in a direction of the central longitudinal axis that is less than a depth of the central portion.
The housing may have a central portion which houses the suction motor and a lateral portion laterally spaced from the central portion wherein the lateral portion has a depth in a direction of the central longitudinal axis that is less than a depth of the central portion. The lateral portion may house a post motor filter.
The dirt collection region may be located above the lateral portion when the upright section is in the generally upright position.
The motor housing portion may underlie the air treatment member.
The air treatment member may include a cyclone chamber and the dirt collection region comprises a dirt collection chamber.
The suction motor may be generally laterally aligned with an air outlet of the cyclone chamber.
The upright section may include an up flow duct positioned behind the lateral portion. The lateral portion may house a post motor filter.
The up flow duct may be located proximate a rear side of the motor housing portion.
The motor housing portion may have a depth in a direction of the central longitudinal axis that is generally equal to a depth of the lateral portion in a direction of the central longitudinal axis and a depth of the up flow duct in a direction of the central longitudinal axis.
An axis of rotation of the rear wheels may be located rearward of the lateral portion and may underlie the upright section when the upright section is in the generally upright position.
The upright section may include a cleaning unit that contains the air treatment member assembly and suction motor and a drive handle extending from an upper end of the cleaning unit. A maximum depth of the cleaning unit in a direction of the central longitudinal axis may 6 inches or less, and may be 4 inches or less.
The upright section further may include an up flow duct that has a length in a lateral direction that is transverse to the central longitudinal axis that is greater than a depth of the up flow duct in a direction of the central longitudinal axis.
The length of the up flow duct may be more than twice the depth of the up flow duct. The up flow duct may be rectangular or ovaloid.
In accordance with another aspect of this disclosure, an upper section of a surface cleaning apparatus utilizes non-rounded air flow ducts. For example, one or more air flow conduits may be a parallelogram in cross section transverse to the air flow direction through the conduit (e.g., square or rectangular), elliptical or the like. The longer dimension of the conduit preferably extends transverse to a central longitudinal axis of the surface cleaning head to thereby increase the lateral dimension of the cleaning unit while reducing the depth of the cleaning unit.
In accordance with this aspect, there is provided an upright surface cleaning apparatus that may include a surface cleaning head having a front end, a rear end, rear wheels having a diameter, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may include an air treatment member assembly having an air treatment member, a suction motor and an air flow duct. The upright section may have a motor receiving portion housing the suction motor and a lateral portion laterally spaced from the motor receiving portion. The air flow duct may be positioned laterally from the motor receiving portion. The air flow duct may have a length in a lateral direction that is transverse to the central longitudinal axis that is greater than a depth of the air flow duct in a direction of the central longitudinal axis.
The length of the up flow duct may be more than twice the depth of the up flow duct. The up flow duct may be rectangular or ovaloid in cross-section, and may include an up flow duct.
The motor receiving portion that may have a depth in a direction of the central longitudinal axis that is greater than a depth in a direction of the central longitudinal axis of the lateral portion and the air flow duct is provided in front or behind the lateral portion. The lateral portion may house a post motor filter.
A depth in a direction of the central longitudinal axis of the motor receiving portion may be approximately the same as a depth of the lateral portion in a direction of the central longitudinal axis and a depth of the air flow duct in a direction of the central longitudinal axis.
The surface cleaning head may include an up flow duct, and the upright surface cleaning apparatus may include a rotatable mount rotatably mounting the upright section with respect to the surface cleaning head about an upright section axis. The up flow duct may have a circular cross-sectional area. The air flow duct may be downstream from the up flow duct.
The air treatment member may have an air inlet having a shape that is similar to a shape of the air flow duct.
The air inlet of the air treatment member may have a height in a direction of a longitudinal axis of the upright section that is ±15% of a depth of the up flow duct in a direction of the central longitudinal axis and the air inlet of the air treatment member has a width in a direction transverse to the longitudinal axis of the upright section that is ±15% of a width of the up flow duct in a lateral direction.
The air treatment member assembly may have a dirt collection region external to and laterally spaced from the air treatment member. The dirt collection region may be located above the lateral portion when the upright section is in the generally upright position.
The motor receiving portion may underlie the air treatment member.
The air treatment member may include a cyclone and the dirt collection region may include a dirt collection chamber.
The suction motor may be generally aligned with an air outlet of the cyclone.
A flexible conduit may include a downstream end that has a transition member that is removably receivable in the air flow duct. The transition member may have, in cross-section, a length and a width and the length may be greater than the width.
The cross-sectional length of the transition member may be more than twice the cross-sectional depth of the transition member. The transition member may be rectangular or ovaloid in cross-section.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, rear wheels having a diameter, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may include an air treatment member assembly and may include an air treatment member, a suction motor and an air flow duct. The air flow duct may have a length in a lateral direction that is transverse to the central longitudinal axis that is greater than a depth of the air flow duct in a direction of the central longitudinal axis. A flexible conduit may have a downstream end that has a transition member that is removably receivable in the air flow duct. The transition member, in cross-section, may have a length and a depth and the length may be greater than the depth.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, rear wheels having a diameter, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position, the upright section comprising an air treatment member assembly comprising an air treatment member, a suction motor and an air flow duct. A flexible conduit may have a downstream end that has a transition member. The air flow duct may have a non-circular perimeter in cross-section and the transition member may have a perimeter in cross-section that is comparable to perimeter of the air flow duct.
In accordance with another aspect of this disclosure, all or a substantial portion of the dirt collection region is positioned laterally beside the air treatment member. For example, the volume of the portions of the dirt collection region that are laterally beside the cyclone chamber may be more than 50%, 60%, 70%, 80% or 90% of the total volume of the dirt collection region. Accordingly, the depth of the cleaning unit may be reduced by positioning the dirt collection chamber to not be in front and/or behind the air treatment member.
In accordance with this aspect, there is provided an upright surface cleaning apparatus that may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may include a cyclone bin assembly having a cyclone chamber and at least one dirt collection chamber exterior to the cyclone. The dirt collection chamber may have a volume and at least 60% of the volume may be positioned laterally from the cyclone.
The cyclone chamber has a laterally directed dirt outlet. The laterally directed dirt outlet may include a laterally positioned opening in a sidewall of the cyclone chamber.
The cyclone chamber may have first and second lateral sides and the at least one dirt collection chamber may be provided on only the first lateral side of the cyclone chamber.
The cyclone bin assembly may have first and second lateral sides and the cyclone chamber is provided on the first lateral side of the cyclone bin assembly and the at least one dirt collection chamber may be provided on the second lateral side of the cyclone bin assembly.
The cyclone chamber may have first and second lateral sides and a first dirt collection chamber may be provided on the first lateral side of the cyclone and a second dirt collection chamber may be provided on the second lateral side of the cyclone chamber.
The cyclone bin assembly may have first and second lateral sides and the cyclone chamber may be provided centrally between the first and second lateral sides. The dirt collection chamber may be provided on the first lateral side of the cyclone bin assembly and the second dirt collection chamber may be provided on the second lateral side of the cyclone bin assembly.
At least 80% of the volume may be positioned laterally from the cyclone chamber.
The cyclone chamber may have a depth in a direction of the central longitudinal axis that is greater than a depth of at least a portion of the at least one dirt collection chamber in the direction of the central longitudinal axis.
An up flow duct may be positioned behind the portion of the at least one dirt collection chamber.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may include an air treatment member assembly having an air treatment member and at least one dirt collection region exterior to the air treatment member. The dirt collection region may have a volume and at least 60% of the volume may be positioned laterally from the air treatment member.
The air treatment member may have a laterally directed dirt outlet. The laterally directed dirt outlet may include a laterally positioned opening in a sidewall of the air treatment member.
The air treatment member may have first and second lateral sides and the at least one dirt collection region may be provided on only the first lateral side of the air treatment member.
The air treatment member assembly has first and second lateral sides and the air treatment member is provided on the first lateral side of the air treatment member assembly and the at least one dirt collection region is provided on the second lateral side of the air treatment member assembly.
The air treatment member may have first and second lateral sides and a first dirt collection chamber may be provided on the first lateral side of the air treatment member and a second dirt collection chamber may be provided on the second lateral side of the air treatment member.
The air treatment member assembly may have first and second lateral sides, the air treatment member may be provided centrally between the first and second lateral sides. The dirt collection chamber may be provided on the first lateral side of the air treatment member assembly and the second dirt collection chamber may be provided on the second lateral side of the air treatment member assembly.
At least 80% of the volume may be positioned laterally from the air treatment member.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of at least a portion of the at least one dirt collection region in the direction of the central longitudinal axis.
An up flow duct may be positioned behind the portion of the at least one dirt collection region.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may include an air treatment member assembly comprising an air treatment member and a dirt collection region exterior to the air treatment member. The air treatment member may have first and second lateral sides and the dirt collection region may be provided on only the first lateral side of the air treatment member.
The air treatment member assembly may have first and second lateral sides and the air treatment member may be provided on the first lateral side of the air treatment member assembly. The dirt collection region may be provided on the second lateral side of the air treatment member assembly.
The air treatment member may include a cyclone.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of at least a portion of the at least one dirt collection region in the direction of the central longitudinal axis.
An up flow duct may be positioned behind the portion of the at least one dirt collection region.
In accordance with another aspect of this disclosure, the push handle of the upright surface cleaning apparatus may be positioned such that a portion of the air treatment member may be positioned laterally thereof. For example, the push handle may be positioned off centre (towards one lateral side of the upper section) thereby enabling the air treatment member to extend further rearwardly and reducing the depth of the cleaning unit.
In accordance with this aspect, there is provided an upright surface cleaning apparatus that may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. A cleaning unit may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The cleaning unit may include a support structure and an air treatment member assembly that includes an air treatment member. The support structure may be positioned rearward of a front face of the air treatment member assembly when the cleaning unit is in the generally upright position. A push handle may include a longitudinally extending member having a longitudinally extending drive axis and a hand grip portion provided at an upper end of the longitudinally extending member. A lower end of the longitudinally extending member may be mounted to the support structure and a portion of the air treatment member assembly may extend rearward of the longitudinally extending member when the cleaning unit is in the generally upright position.
A portion of the air treatment member may extend rearward of the longitudinally extending member when the cleaning unit is in the generally upright position.
The longitudinally extending member may extend generally vertically when the cleaning unit is in the generally upright position.
The support structure may include an up flow duct and the longitudinally extending member may be mounted to an upper end of the up flow duct.
The air treatment member assembly may include a dirt collection region and the up flow duct may be positioned behind the dirt collection region.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of at least a portion of the dirt collection region in the direction of the central longitudinal axis.
The up flow duct may be positioned behind the portion of the at least one dirt collection region.
The support structure may include first and second laterally spaced struts and a cross member provided on an upper end of the struts.
The struts may be positioned behind the air treatment member assembly.
The air treatment member assembly may include first and second lateral sides. A first dirt collection region external to the air treatment member may be provided on the first lateral side of the air treatment member assembly and a second dirt collection region external to the air treatment member may be provided on the second lateral side of the air treatment member assembly. A strut may be positioned behind each of the dirt collection regions. The first and second dirt collection regions may be contiguous.
The first and second dirt collection regions may be provided on either side of an air treatment member and may be isolated from each other.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of at least a portion of the first and second dirt collection regions in the direction of the central longitudinal axis.
The first strut may be positioned behind the portion of the first dirt collection region and the second strut may be positioned behind the portion of the second dirt collection region.
The drive axis may extend through the air treatment member assembly.
The air treatment member assembly may include a cyclone bin assembly and the air treatment member may include a cyclone.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. A cleaning unit may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The cleaning unit may include a support structure and an air treatment member assembly. The support structure may include first and second laterally spaced struts and a cross member provided on an upper end of the struts. The air treatment member assembly may include an air treatment member, first and second lateral sides, a first dirt collection region external to the air treatment member provided on the first lateral side of the air treatment member assembly and a second dirt collection region external to the air treatment member provided on the second lateral side of the air treatment member assembly. A strut may be positioned behind each of the dirt collection regions. A push handle may include a longitudinally extending member having a longitudinally extending drive axis and a hand grip portion provided at an upper end of the longitudinally extending member. A lower end of the longitudinally extending member may be mounted to the support structure.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. A cleaning unit may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The cleaning unit may include an up flow duct and an air treatment member assembly comprising an air treatment member. The up flow duct may be positioned rearward of a front face of the air treatment member assembly when the cleaning unit is in the generally upright position. A push handle may include a longitudinally extending member having a longitudinally extending drive axis and a hand grip portion provided at an upper end of the longitudinally extending member wherein a lower end of the longitudinally extending member is mounted to the up flow duct.
The first and second dirt collection regions may be contiguous.
The first and second dirt collection regions may be provided on either side of an air treatment member and may be isolated from each other.
In accordance with another aspect of this disclosure, the post motor filter(s) and/or the clean air outlet(s) may be provided on one or both lateral sides of the upper section. An advantage of this design is that a post motor filter need not be positioned forward and/or rearward of the suction motor. Therefore, the suction motor may essentially extend from the front to the rear of the cleaning unit thereby reducing the depth of the cleaning unit.
In accordance with this aspect, there is provided an upright surface cleaning apparatus that may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may include first and second lateral opposed sides, an air treatment member assembly comprising an air treatment member and a suction motor having first and second lateral sides. Each lateral side of the upright section may have a clean air outlet and a post-motor porous filter media located upstream of the clean air outlet.
The post-motor porous filter media may be provided on each lateral side of the suction motor.
The post-motor porous filter media may be positioned opposed to and facing each of the lateral sides of the suction motor. The suction motor may be positioned below the air treatment member.
The clean air outlets may be provided in a lower portion of the upright section. The post-motor porous filter media may be positioned below the suction motor.
The upper section may have a width in a direction transverse to the central longitudinal axis that is more than twice a depth of the upright section in the direction of the central longitudinal axis. The air treatment member may include a cyclone chamber.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may include first and second lateral opposed sides, an air treatment member assembly comprising an air treatment member and a suction motor having first and second lateral sides. The first lateral side may have a clean air outlet. A post-motor porous filter media may be located upstream of the clean air outlet. The upper section may have a width in a direction transverse to the central longitudinal axis that is more than twice a depth of the upright section in the direction of the central longitudinal axis.
The post-motor porous filter media may be provided on the first lateral side of the suction motor, wherein the first lateral side of the suction motor faces the first lateral side of the upper section.
The post-motor porous filter media may be positioned opposed to and facing the first lateral side of the suction motor. The suction motor may be positioned below the air treatment member. The clean air outlet may be provided in a lower portion of the upright section. The air treatment member may include a cyclone.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may include first and second lateral opposed sides, an air treatment member assembly comprising an air treatment member, a suction motor having first and second lateral sides and a clean air outlet. Each lateral side of the upright section may include a post-motor porous filter media located upstream of the clean air outlet. The upper section may have a width in a direction transverse to the central longitudinal axis that is more than twice a depth of the upright section in the direction of the central longitudinal axis.
The post-motor porous filter media may be positioned opposed to and facing each of the lateral sides of the suction motor.
The suction motor may be positioned below the air treatment member.
The clean air outlet may be provided in a lower portion of the upright section.
The post-motor porous filter media may be positioned below the suction motor. The air treatment member may include a cyclone.
In accordance with another aspect of this disclosure, the surface cleaning apparatus may have a telescoping push handle with a pivot joint provided therein. Optionally, one of the telescoping shafts may provide an anti-rotation lock for the pivot joint. An advantage of this design is that a user may position the cleaning unit to extend generally horizontal while still standing in a generally upright position such that the user may maneuver the surface cleaning head under furniture while in a comfortable operating position.
In accordance with this aspect, there is provided an upright surface cleaning apparatus that may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. A cleaning unit may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The cleaning unit may include an air treatment member assembly comprising an air treatment member and a suction motor. A telescoping push handle may include upper and lower telescoping longitudinally extending members which are reconfigurable between a retracted position and a first extended position. The upper telescoping longitudinally extending member may have a longitudinally extending drive axis and a hand grip portion provided at an upper end of the upper longitudinally extending member. The lower telescoping longitudinally extending member may have a first pivot joint provided at an upper end of the lower telescoping longitudinally extending member. The first pivot joint may be non-rotationally locked when the push handle is in the retracted position and the upper telescoping longitudinally extending member may be pivotal about the first pivot joint when the push handle is in the first extended position.
The upper telescoping longitudinally extending member may have a first abutment member and the first pivot joint may have a first pivot joint abutment member and the abutment members prevent rotation of the upper telescoping longitudinally extending member when the push handle is in the retracted position.
The upper telescoping longitudinally extending member may include a longitudinally extending drive shaft and the first abutment member may include a portion of the outer surface of the drive shaft whereby the portion of the outer surface is exterior to the first pivot joint when the push handle is in the first extended position.
The upper telescoping longitudinally extending member may extend through the first pivot joint when the push handle is in the retracted position.
The upper telescoping longitudinally extending member may be slideably receivable in the lower telescoping longitudinally extending member.
The first pivot joint may be located above the air treatment member.
The first pivot joint may overlie the air treatment member.
The push handle may be mounted to the cleaning unit.
A second pivot joint may be provided on longitudinally extending member and above the first pivot joint. The second pivot joint may be non-rotationally locked when the push handle is in the first extended position and the upper telescoping longitudinally extending member may be pivotal about the second pivot joint when the push handle is in a second extended position.
When the upper longitudinally extending member is in the second extended position, the upper longitudinally extending member may be further extended than when the upper longitudinally extending member is in the first extended position.
The upper telescoping longitudinally extending member may have a second abutment member and the second pivot joint may have a second pivot joint abutment member and the second abutment member and the second pivot joint abutment member prevent rotation of the upper telescoping longitudinally extending member when the push handle is in the retracted position.
The upper telescoping longitudinally extending member may include a longitudinally extending drive shaft and the second abutment member may include a portion of the outer surface of the drive shaft whereby the portion of the outer surface is exterior to the second pivot joint when the push handle is in the second extended position.
The upper telescoping longitudinally extending member may extend through the second pivot joint when the push handle is in the retracted position.
The second pivot joint may be located above the air treatment member.
The second pivot joint may overlie the air treatment member.
The upper telescoping longitudinally extending member may have first and second abutment members. The first pivot joint may have a first pivot joint abutment member and the second pivot joint may have a second pivot joint abutment member. The first abutment member and the first pivot joint abutment member may prevent rotation of the upper telescoping longitudinally extending member when the push handle is in the retracted position. The second abutment member and the second pivot joint abutment member may prevent rotation of the upper telescoping longitudinally extending member when the push handle is in the first extended position.
The upper telescoping longitudinally extending member may include a longitudinally extending drive shaft. The first abutment member may include a first portion of the outer surface of the drive shaft and the second abutment member may include a second portion of the outer surface of the drive shaft. The first portion of the outer surface may be exterior to the first pivot joint when the push handle is in the first extended position and the second portion of the outer surface may exterior to the second pivot joint when the push handle is in the second extended position.
The second portion of the outer surface of the drive shaft may be below the first portion of the outer surface of the drive shaft.
The first and second pivot joints may each overlie the air treatment member.
The push handle may be mounted to the cleaning unit.
In accordance with another aspect of this disclosure, an upright surface cleaning apparatus is provided with a flexible conduit, wherein in a floor cleaning mode the flexible conduit is positioned between a front transverse plane of the cleaning unit and a rear transverse of the cleaning unit. An advantage of this design is that the flexible conduit does not increase the depth of the upper section.
In accordance with this aspect, there is provided an upright surface cleaning apparatus that may include a surface cleaning head having a front end, a rear end, rear wheels, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. A cleaning unit may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The cleaning unit may include an air treatment member assembly having an air treatment member and a suction motor therein. The cleaning unit may have an upper end, a front side and a rear side and first and second opposed lateral sides. A push handle may have a longitudinally extending member having a longitudinally extending drive axis and a hand grip portion. An above floor cleaning assembly may include a flexible conduit having an inlet end and an outlet end. In a floor cleaning mode the above floor cleaning assembly may be positioned between a front transverse plane that extends transverse to the central longitudinal axis and is located at the front side of the cleaning unit and a rear transverse plane that extends transverse to the central longitudinal axis and is located at the rear side of the cleaning unit.
The above floor cleaning assembly may include a rigid conduit that is upstream of the flexible conduit in an above floor cleaning mode. In the floor cleaning mode, the rigid conduit may be located on a first lateral side of the air treatment member, a first portion of the flexible conduit having the outlet end may be located on a second lateral side of the air treatment member. A second portion of the flexible conduit may extend from the second lateral side of the air treatment member over an upper end of the air treatment member to the first lateral side of the air treatment member.
The rigid conduit may have an upstream end that in the floor cleaning mode is received in an up flow duct and in an above floor cleaning mode is removed from the up flow duct.
The air treatment member assembly may include a first dirt collection region that is located on the first lateral side of the air treatment member and the rigid conduit may be located behind the first dirt collection region.
The air treatment member assembly may include a second dirt collection region that is located on the second lateral side of the air treatment member and the first portion of the flexible conduit may be located behind the second dirt collection region.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of the first dirt collection region in a direction of the central longitudinal axis.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of the first dirt collection region and greater than a depth of the second dirt collection region in a direction of the central longitudinal axis. The drive axis may extend through the air treatment member assembly.
The drive axis may extend through the air treatment member assembly and, in the floor cleaning mode, the second portion of the flexible conduit may be positioned in front of the drive axis. In the floor cleaning mode, a rearward extent of a rear side of the above floor cleaning assembly may be at most a rear side of the cleaning unit.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, rear wheels, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. A cleaning unit may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The cleaning unit may include an air treatment member assembly having an air treatment member and a suction motor therein. The air treatment member may have an upper end, a front side and a rear side and first and second opposed lateral sides. A push handle may have a longitudinally extending member having a longitudinally extending drive axis and a hand grip portion. An above floor cleaning assembly may include a flexible conduit having an inlet end and an outlet end. In a floor cleaning mode a front side of the entire above floor cleaning assembly may be positioned forward of a rear side of the air treatment member.
The above floor cleaning assembly may include a rigid conduit that is upstream of the flexible conduit in an above floor cleaning mode. In the floor cleaning mode, the rigid conduit may be located on the first lateral side of the air treatment member, a first portion of the flexible conduit having the outlet end may be located on the second lateral side of the air treatment member and a second portion of the flexible conduit may extend from the second lateral side of the air treatment member over the upper end of the air treatment member to the first lateral side of the air treatment member.
The rigid conduit may have an upstream end that in the floor cleaning mode is received in an up flow duct and in an above floor cleaning mode is removed from the up flow duct.
The air treatment member assembly may include a first dirt collection region that is located on the first lateral side of the air treatment member and the rigid conduit may be located behind the first dirt collection region.
The air treatment member assembly may include a second dirt collection region that is located on the second lateral side of the air treatment member and the first portion of the flexible conduit may be located behind the second dirt collection region.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of the first dirt collection region in a direction of the central longitudinal axis.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of the first dirt collection region and greater than a depth of the second dirt collection region in a direction of the central longitudinal axis.
The drive axis may extend through the air treatment member assembly.
The drive axis may extend through the air treatment member assembly and, in the floor cleaning mode, the second portion of the flexible conduit may be positioned rearward of the drive axis.
In the floor cleaning mode, a rearward extent of a rear side of the above floor cleaning assembly may be at most a rear side of the cleaning unit.
In accordance with another aspect of this disclosure, the cleaning unit is provided with a carry handle that extends transversely. An advantage of this design is that the handle does not increase the depth of the upper section.
In accordance with this aspect, there is provided an upright surface cleaning apparatus that may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. An upright section may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The upright section may include a cleaning unit having a carry handle, an air treatment member assembly having an air treatment member, and a suction motor. The air treatment member assembly may have an upper end, a front side and a rear side and first and second opposed lateral sides. The carry handle may extend in a direction transverse to the central longitudinal axis. The carry handle may have a hand grip portion that has a length in the transverse direction that is greater than a depth of the cleaning unit in a direction of the central longitudinal axis.
The carry handle may be provided on the upper end of the air treatment member assembly.
The carry handle may overlie the upper end of the air treatment member assembly and may be positioned between the front and rear sides of the air treatment member assembly.
The air treatment member assembly may be removable from the upright section.
The cleaning unit may include a suction motor housing and the air treatment member assembly is removably mounted to an upper end of the suction motor housing.
A push handle may include a longitudinally extending member having a longitudinally extending drive axis and a hand grip portion provided at an upper end of the longitudinally extending member. A lower end of the longitudinally extending member may be pivotally mounted to the cleaning unit by a pivot joint. The pivot joint may be located above the carry handle when the cleaning unit is in the upright position. The longitudinally extending member ay be positioned between the front and rear sides of the air treatment member assembly.
A push handle may include an upper and lower longitudinally extending members, the upper longitudinally extending member having a longitudinally extending drive axis and a hand grip portion provided at an upper end of the upper longitudinally extending member. The lower longitudinally extending member may have a pivot joint provided at an upper end of the lower longitudinally extending member. The pivot joint is located above the carry handle when the upright section is in the upright position. The longitudinally extending member may be positioned between the front and rear sides of the air treatment member assembly.
A length of the carry handle in the transverse direction may be greater than twice the depth of the cleaning unit in the direction of the central longitudinal axis.
In accordance with this aspect, an upright surface cleaning apparatus may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. A cleaning unit may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The cleaning unit may include a carry handle, an air treatment member assembly comprising an air treatment member, and a suction motor. The air treatment member assembly may have an upper end, a front side and a rear side and first and second opposed lateral sides. A push handle may have a first longitudinally extending member having a longitudinally extending drive axis and a hand grip portion provided at an upper end of the first longitudinally extending member. A lower end of the first longitudinally extending member may be rotatably mounted with respect to the cleaning unit at a location above the carry handle when the upright section is in the upright position wherein the upper end of the first longitudinally extending member is rotatable forwardly.
The first longitudinally extending member may be positioned between the front and rear sides of the air treatment member assembly.
The push handle further may include a second longitudinally extending member. The first and second longitudinally extending members may be telescopically mounted with respect to each other. A rotational joint may be provided on the second longitudinally extending member and the lower end of the first longitudinally extending member may be slidably receivable in the rotational joint. The rotational joint may be in a locked position when the lower end of the first longitudinally extending member is received in the rotational joint.
The carry handle may be provided on the upper end of the air treatment member assembly, and may overlie the upper end of the air treatment member assembly.
The carry handle may be positioned between the front and rear sides of the air treatment member assembly.
The air treatment member assembly may be removable from the cleaning unit.
The cleaning unit may include a suction motor housing and the air treatment member assembly may be removably mounted to an upper end of the suction motor housing.
The carry handle may extend in a direction transverse to the central longitudinal axis. The carry handle may have a hand grip portion that has a length in the transverse direction that is greater than a depth of the cleaning unit in a direction of the central longitudinal axis.
The location at which the lower end of the first longitudinally extending member is rotatably mounted with respect to the cleaning unit may overlie the carry handle when the upright section is in the upright position.
In accordance with another aspect of this disclosure, an upright surface cleaning apparatus is provided with a push handle that is rotatably mounted with respect to the cleaning unit about a rotational joint located above the air treatment member and a flexible conduit is vertically spaced with respect to the rotational joint. An advantage of this design is that the hose and rotational joint do not increase the depth of the upper section.
In accordance with this aspect, there is provided an upright surface cleaning apparatus that may include a surface cleaning head having a front end, a rear end, a central longitudinal axis extending between the front and rear ends, first and second laterally opposed sides, a dirty air inlet and a surface cleaning head air outlet. A cleaning unit may be moveably mounted to the surface cleaning head between a generally upright position and a rearwardly inclined in use position. The cleaning unit may include an air treatment member assembly, having an air treatment member, and a suction motor. The air treatment member may have an upper end, a front side and a rear side and first and second opposed lateral sides. A push handle may include a first longitudinally extending member having a longitudinally extending drive axis and a hand grip portion provided at an upper end of the longitudinally extending member, a lower end of the longitudinally extending member is rotatably mounted with respect to the cleaning unit about a rotational joint located above the air treatment member assembly when the cleaning unit is in the upright position. An above floor cleaning assembly may include a flexible conduit having an inlet end and an outlet end. In a floor cleaning mode a first portion of the flexible conduit having the outlet end may be located on the second lateral side of the air treatment member and a second transverse portion of the flexible conduit may extend from the second lateral side of the air treatment member over the upper end of the air treatment member to the first lateral side of the air treatment member wherein the second transverse portion is vertically spaced from the rotational joint.
In the floor cleaning mode, the second transverse portion may be positioned above the rotational joint, and/or may be positioned rearward of the rotational joint.
The air treatment member assembly may include a dirt collection region that is located on the second lateral side of the air treatment member and in the floor cleaning mode the first portion of the flexible conduit may be located behind the second dirt collection region.
The air treatment member ay have a depth in a direction of the central longitudinal axis that is greater than a depth of the dirt collection region in a direction of the central longitudinal axis.
A transverse plane that extends transverse to the central longitudinal axis may extend through the air treatment member and the first portion of the flexible conduit.
The drive axis may extend through the air treatment member assembly.
In the floor cleaning mode, the second transverse portion may be positioned above the rotational joint and/or may be positioned rearward of the rotational joint.
The above floor cleaning assembly may include a rigid conduit and the air treatment member assembly may include a first dirt collection region that is located on the first lateral side of the air treatment member and a second dirt collection region that is located on the second lateral side of the air treatment member. In the floor cleaning mode, the rigid conduit may be located behind the first dirt collection region and the first portion of the flexible conduit may be located behind the second dirt collection region.
The air treatment member may have a depth in a direction of the central longitudinal axis that is greater than a depth of the first dirt collection region and greater than a depth of the second dirt collection region in a direction of the central longitudinal axis.
A transverse plane that may extend transverse to the central longitudinal axis extends through the air treatment member, the first portion of the flexible conduit and the rigid conduit.
The drive axis may extend through the air treatment member assembly.
In the floor cleaning mode, the second transverse portion is positioned above the rotational joint and/or may be positioned rearward of the rotational joint.
The push handle may be mounted to the upright section.
The push handle may include a second longitudinally extending member. The first and second longitudinally extending members may be telescopically mounted with respect to each other. A rotational joint may be provided on the second longitudinally extending member and the lower end of the first longitudinally extending member may be slidably receivable in the rotational joint. The rotational joint may be in a locked position when the lower end of the first longitudinally extending member is received in the rotational joint.
The drawings included herewith are for illustrating various examples of articles, methods, and apparatuses of the teaching of the present specification and are not intended to limit the scope of what is taught in any way.
In the drawings:
Various apparatuses or processes will be described below to provide an example of an embodiment of each claimed invention. No embodiment described below limits any claimed invention and any claimed invention may cover processes or apparatuses that differ from those described below. The claimed inventions are not limited to apparatuses or processes having all of the features of any one apparatus or process described below or to features common to multiple or all of the apparatuses described below. It is possible that an apparatus or process described below is not an embodiment of any claimed invention. Any invention disclosed in an apparatus or process described below that is not claimed in this document may be the subject matter of another protective instrument, for example, a continuing patent application, and the applicants, inventors or owners do not intend to abandon, disclaim or dedicate to the public any such invention by its disclosure in this document.
The terms “an embodiment,” “embodiment,” “embodiments,” “the embodiment,” “the embodiments,” “one or more embodiments,” “some embodiments,” and “one embodiment” mean “one or more (but not all) embodiments of the present invention(s),” unless expressly specified otherwise.
The terms “including,” “comprising” and variations thereof mean “including but not limited to,” unless expressly specified otherwise. A listing of items does not imply that any or all of the items are mutually exclusive, unless expressly specified otherwise. The terms “a,” “an” and “the” mean “one or more,” unless expressly specified otherwise.
As used herein and in the claims, two or more parts are said to be “coupled”, “connected”, “attached”, or “fastened” where the parts are joined or operate together either directly or indirectly (i.e., through one or more intermediate parts), so long as a link occurs. As used herein and in the claims, two or more parts are said to be “directly coupled”, “directly connected”, “directly attached”, or “directly fastened” where the parts are connected in physical contact with each other. As used herein, two or more parts are said to be “rigidly coupled”, “rigidly connected”, “rigidly attached”, or “rigidly fastened” where the parts are coupled so as to move as one while maintaining a constant orientation relative to each other. None of the terms “coupled”, “connected”, “attached”, and “fastened” distinguish the manner in which two or more parts are joined together.
General Description of a Vacuum Cleaner
Referring to
In the embodiment illustrated, the surface cleaning apparatus 100 is an upright-style vacuum cleaner. Optionally, the surface cleaning apparatus incorporating some or all of the features described herein could alternatively be configured as another suitable type of surface cleaning apparatus, including, for example, an extractor, a stick vac, a wet-dry vacuum cleaner and the like.
In this embodiment, the surface cleaning apparatus 100 includes an upright section 102 that is movably and drivingly connected to a surface cleaning head 104, such that the upright section 102 is movable between an upright position (
The surface cleaning apparatus 100 also includes at least one dirty air inlet 106 (
Referring to
Optionally, one or more pre-motor filters 120 may be provided in the air flow path between the air treatment member 114 and the suction motor 112, and/or one or more post-motor filters 122 may be provided in the air flow path downstream from the suction motor 112 and preferably upstream from the clean air outlet 108. The pre-motor filter 120 and post-motor filter 122 may each be any suitable type of filter, including a physical, porous media type filter such as foam or felt, and optionally may include a HEPA filter.
The apparatus 100 also includes a push handle 124 (
Surface Cleaning Head
The following is a description of a surface cleaning head that may be used by itself in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, any surface cleaning head described herein may be used with any one or more of the moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this embodiment, the surface cleaning head is configured to have a low profile (e.g., it may have a vertical height of less than 6 inches, and more preferably is less than about 4 inches and may be less than 3 inches). Accordingly, the upper and lower surfaces of the surface cleaning head may be generally planar (horizontal) and the suction motor may be provided in the upright section. Rear wheels may be provided which have a large diameter (e.g., larger than or the same height as the surface cleaning head) to enhance stability of the surface cleaning apparatus when in the upright position.
Referring to
The surface cleaning head 104 also has an upper surface 148 and an opposed lower surface 150 that faces the floor to be cleaned. The upper and lower surfaces 148 and 150 may have any suitable configuration, and in the present embodiment are each optionally configured as substantially flat, planar surfaces. The upper surface 148 lies generally in an upper plane 152, and the lower surface 150 lies generally in a lower plane 154. A vertical distance between the upper and lower planes/surfaces defines a surface cleaning head height 156 (
The downward facing dirty air inlet 106 is provided in the lower surface 150, and may be positioned toward the front end 140. Main wheels 158 are provided at the rear end 142 of the surface cleaning head 104, and are rotatable about a laterally oriented rotation axis 160 (
In addition to the main wheels 158, the surface cleaning head 104 may include one or more additional wheels to help rollingly support the surface cleaning head 104, and the rest of the apparatus 100, above the floor. For example, smaller front wheels may be provided on the lower surface 150, toward the front end 140.
Optionally, the surface cleaning head 104 may include a rotating agitating member, such as a brush 168 and the like, positioned at the dirty air inlet 106 to help dislodge debris from the surface being cleaned (
The surface cleaning head 104 may be used with a variety of differently configured upright sections 102, including, for example, the embodiments illustrated in
It will be appreciated that, as exemplified, the suction motor may be provided in the upper section. Therefore the height of the surface cleaning head may be reduced as it need not include a suction motor, thereby permitting the height of the surface cleaning head to be reduced and to thereby increase the ability of the surface cleaning head to extend under furniture having a small ground clearance.
Moveable Wheels
The following is a description of moveable wheels that may be used by itself in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the movable wheels described herein may be used with any one or more of the surface cleaning head, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, the surface cleaning head may have rear wheels that are moveable in the rearward forward/direction and/or the lateral direction. The movement may be automatic upon reconfiguring the surface cleaning apparatus between different operating positions. For example, the rear wheels may be extended when the upright section is placed in a storage position so as to enhance stability. Alternately or in addition, the rear wheels may be moved laterally inwardly in the floor cleaning position so as to enhance maneuverability.
Optionally, the offset distance 164 may be variable and/or adjustable (automatically as the configuration and/or operating mode of apparatus 100 is adjusted, or manually by a user, or a combination of both). In such embodiments, the wheels 158 may be in one location when the upright section 102 is in the upright configuration and a different position when the upright section 102 is in the use configuration. Optionally, the wheels 158 may be moved in the forward/rearward direction (thereby changing the offset distance 164) and/or the lateral spacing between the rear wheels may also be adjusted. This may allow the wheel position, balance and/or handling of the apparatus 100 to be adjusted.
Accordingly, the rear wheels may be biased to a forward position and the upper section may be drivingly connected to the rear wheels so as to move the rear wheels rearward when the upper section is moved to the upright configuration. Alternately, the rear wheels may be biased to a rearward position and the upper section may be drivingly connected to the rear wheels so as to move the rear wheels forward when the upper section is moved to the inclined floor cleaning position.
For example, referring to
An alternative embodiment of a linkage 172 is illustrated in
Alternatively, instead of being linked to movement of the upright section 102, the apparatus may be manually adjustable by a user, such that a user can manually select the forward/rearward position of the wheels 158.
Upright Section
The following is a description of an upright section that may be used by itself in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the upright section described herein may be used with any one or more of the surface cleaning head, moveable wheels, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, the components of the upright section may be arranged to reduce the depth (front to back) of the upright section. It will be appreciated that if the upright section includes a bendable wand such that the surface cleaning apparatus may be reconfigured into the low profile floor cleaning mode of
It will be appreciated that some of the dirt collection regions may be forward and/or rearward of the air treatment member however this amount is preferably minimized. For example, at least 60%, 70%, 80%, 90% or more of the dirt collection regions is laterally spaced from the air treatment member. It will also be appreciated that the shapes of the dirt collection regions may be varied but still provide one or more recesses for receiving components of the surface cleaning apparatus.
In the illustrated embodiments (see
The cleaning unit 130 may also include one or more of a lower housing 192 that houses the pre-motor filter 120 in a pre-motor filter chamber 194, the suction motor 112 in a motor housing portion and an optional post-motor filter 122 in a post-motor filter chamber 196. The cleaning unit 130 may also include the clean air outlet(s) 108.
In these embodiments, the lower housing 192 is vertically aligned with the air treatment member and is exemplified as being positioned beneath the air treatment member assembly 110, and underlies the air treatment member assembly 110. It will be appreciated that in alternate embodiments, housing 192 may be positioned above and overlying the cleaning unit 130.
As exemplified, the suction motor 112 is positioned below the air treatment member assembly 110. It will be appreciated that the suction motor 112 may be positioned below and underlie some or all of the cyclone chamber 188, the dirt collection chamber 190 or some or all of both the cyclone chamber 188 and the dirt collection chamber 190.
As exemplified in
Optionally, the air treatment member assembly 110 may also be configured to have a low-profile, slab like configuration. Referring to
As exemplified in
The cleaning unit 130 also has an upper end 206 and an opposed lower end 208. The upper and lower ends 206 and 208 may have any suitable configuration. As exemplified, the lower end 208 may have a generally flat lower face 210 that is orthogonal to the front and rear planes 198, 200 so as to seat on the lower housing 192 and provide a seal.
Optionally, the air treatment member assembly 110 may be part of the structural connection of push handle 124 to the surface cleaning head. Accordingly, the air treatment member assembly 110 may provide substantially the entire upper end 206 of the cleaning unit 130. For example, the push handle 124 may be mounted to the air treatment member assembly 110 and the cleaning unit 130 may be moveably mounted to the surface cleaning head (e.g., it may be mounted to a pivotally mounted up flow duct. In such a case, the dirt collection region(s) may be removable from the cleaning unit 130 for emptying.
Alternately, the air treatment member assembly 110 may be supported by components of the cleaning unit 130 and/or upright section 102 (e.g. lower housing 192 and support structure 212) so as to be removable from the upright section to enable the dirt collection regions to be emptied. As exemplified, the upright section comprises an upwardly extending support structure 212 (
The support structure 212 may be of any configuration and may comprise one or more vertically extending members (e.g., struts 214), which may be connected to each other by a connecting web 215 and may provide rigidity such that push handle 124 may be used to drive the surface cleaning head 104. For example, the support structure may be moveably mounted to the surface cleaning head 104 and provide a structural support for lower housing 192 and air treatment member assembly 110. An upper portion of the support structure 212 may be connected to the handle 124. It will be appreciated that if air treatment member assembly 110 is support by support structure 212, that handle 124 may be mounted to the air treatment member assembly 110. In such a case, the dirt collection region(s) may be removably mounted to the air treatment member assembly 110 for emptying. Alternately, lower portion 192 may itself be mounted to the surface cleaning head 104 and support structure 212 may extend along the length of the cleaning unit. In such a case, the upper portion of the support structure 212 may be connected to the handle 124 or the push handle 124 may be mounted to the air treatment member assembly 110.
In any such embodiment, the vertically extending members may extend generally upwardly along one of the front and rear side, preferably the rear side 246, of the air treatment member assembly 110. As exemplified, struts 214 may be provided at least partially recessed within the recesses 249 (
In the illustrated embodiment, the struts 214 are configured as generally flat, plates that have a width 251 (
Optionally, while the struts 214 are nested with the air treatment member assembly 110, a portion of support structure 212, such as the connecting web 215 may extend rearwardly of plane 199. The connecting web 215 may be configured to have a relatively thin depth in the forward/rearward direction, to help reduce the overall thickness of the cleaning unit 130, and in the illustrated example has the same wall thickness 253 as the struts 214. Optionally, the connecting web 215 may extend along the rear side of the protrusion 247 and may be positioned between the cyclone chamber 188 and the rear plane 200. Preferably, the connecting web 215 is located immediately at rear plane 199.
By connecting push handle 124 to an upper end of support structure 212, the air treatment member assembly 110 may be removeable from the cleaning unit 130 (
Optionally, the region between the struts 214 may be open, i.e. substantially free of connecting walls or structures, such that the rear sides of the air treatment member assembly 110 is exposed when seated on the cleaning unit 130. This may help reduce the weight of the cleaning unit 130. Alternatively, as illustrated in the embodiment of
Preferably, the hose 113 and a transition member 344 are laterally offset from the cyclone chamber 188, and may be at least partially nested within the recess 249 on the back of the air treatment member assembly 110, which may help reduce the overall depth 201 of the cleaning unit. As illustrated in
Together, the struts 214 and connecting web 215 may be configured to define a cavity 217 (
The embodiments of
In addition to supporting the handle 124, the support structure 212 may also be configured to include one or more air flow ducts (e.g., an up flow duct to the air treatment member assembly) at least a portion of a locking mechanism or the like for securing the air treatment member assembly 110 to the cleaning unit 130 if the air treatment member is separately removable, at least a portion of a locking mechanism or the like for securing the cleaning unit 130 to the support structure if the cleaning unit 130 is removably mounted to the support structure, a brush control actuator, storage locations for auxiliary cleaning tools and the like.
In the illustrated embodiments, the air treatment member assembly 110 is removably mounted to the cleaning unit 130 and the locking mechanism for securing the air treatment member assembly 110 includes a latch provided on the air treatment member assembly, and a complimentary catch portion on the cleaning unit. Referring, for example, to
The support structure 212 may also include one or more air flow ducts that form part of the air flow path between the dirty air inlet(s) 106 and the air treatment member assembly 110. Such ducts may be integrally formed and/or internal of the support structure 212, or may be external conduits connected to the support structure (such as wands, pipes and hoses).
It will be appreciated that, in some embodiments, the airflow conduit from the surface cleaning head 104 to the air treatment member assembly 110 may include a rigid cleaning wand 222 and/or a flexible hose 113 (see e.g.,
It will be appreciated that the portion of the air flow path that is coextensive with the cleaning unit may be part of the cleaning unit, the support structure, separate components or a combination of two or more of these options. In any such case, this portion of the air flow conduit may be positioned to help reduce the overall size of the cleaning unit 130, and preferably to help reduce the maximum depth 201 of the cleaning unit 130. For example, the air flow conduits, such as ducts 224, wands 222 and hoses 113, may be nested in recesses provided recessing portions of the front and/or rear sides of the cleaning unit or on the lateral sides of the cleaning unit.
Referring to
Accordingly, it will be appreciated that the cleaning unit 130 and the upright section 102 may be configured to have a relatively small depth 201 in the forward/backward direction. Configuring the upright section 102 to have a small depth may help facilitate positioning the cleaning unit 130 in relatively narrow spaces, such as beneath a couch, bed frame, coffee table and the like. Reducing the size of the cleaning unit 130 and/or upright section 102 may also help reduce the amount of space required to store the apparatus 100 when not in use.
Referring to
It will be appreciated that the cleaning unit 130 may be configured so that it is wider than it is deep, such that the width 238 of the cleaning unit 130 in the lateral direction (see also
It will be appreciated that the air treatment member assembly 110 may have a width 252 in a lateral direction (
Accordingly, when operated in the low profile floor cleaning mode (
Air Treatment Member Assembly
The following is a description of air treatment member assemblies that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the air treatment member assemblies described herein may be used with any one or more of the surface cleaning head, moveable wheels, upright section, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, the air treatment member assembly may be removable from the cleaning unit for emptying. The air treatment member assembly includes an air treatment member and one or more dirt collection regions. The air treatment member assembly may be removable as a sealed unit other than air inlet and outlet ports. Upper and/or lower ends of the air treatment member assembly may be openable to empty the air treatment member and the dirt collection region(s).
Referring to
In the embodiments illustrated herein, the cleaning unit 130 air treatment member assembly is removably mounted to an upper end of the suction motor housing portion 118 of the cleaning unit 130. In this embodiment, the upper end of the suction motor housing 118 may bound part or all of the axially extending walls of the pre-motor filter chamber 194, and the pre-motor filter chamber 194 may have a generally open upper face. When the air treatment member assembly 110 is seated on the upper end of the motor housing 118, the air treatment member assembly 110 may seal the open, upper face of the pre-motor filter chamber 194. In this arrangement, the lower end 250 of the air treatment member assembly 110 may form the upper wall of the pre-motor filter chamber 194. When the air treatment member assembly 110 is removed (
Optionally, the pre-motor filter chamber 194, and pre-motor filter 120 therein, may be removable from the cleaning unit 130 with the air treatment member assembly 110 (as shown in
Optionally, the upper end 244 and/or the lower end 250 of the air treatment member assembly 110 may be openable to provide access to the interior of the air treatment member assembly 110. Referring to
Optionally, the upper and lower doors 260, 262 may be opened by detaching the doors 260, 262 from the rest of the air treatment member assembly (as shown in the embodiment of
If configured to pivot, the doors 260, 262 may be connected using any suitable rotatable connection, such as a pivot joint and/or hinge. Referring to
The air treatment member assembly 110 may be formed from any suitable material, including plastic and composite materials. Preferably, at least a portion of the air treatment member assembly is formed from transparent materials so that a user can view the interior of the air treatment member assembly without having to open the upper or lower doors 260, 262.
Carry Handle
The following is a description of carry handles that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the carry handles described herein may be used with any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, the carry handle 258 is oriented so as to provide a grip area having sufficient length to enable a user to carry the air treatment member assembly 110, the cleaning unit 130 or the entire apparatus 100 while not increasing the depth of the air treatment member assembly 110 or the cleaning unit 130. For example, the cleaning unit may have a maximum depth of, e.g., less than 5 inches and possibly 4 inches or less. The carry handle may have a length of 5-8 inches, 5-7 inches or 5-6 inches so as to provide a grip length of, e.g., 4-5 inches. Accordingly, by orienting the carry handle to extend laterally (transverse to the central axis of the surface cleaning head), the user may comfortably carry the air treatment member assembly 110 without the need to increase the maximum depth of the air treatment member assembly.
As discussed previously, preferably, the air treatment member assembly 110 is removable from the upright section 102 for emptying (as exemplified in
The carry handle 258 may have any suitable configuration, and in the illustrated embodiments includes a grip portion 270 that extends along a grip axis 272 and has a grip length 274 (
Optionally, the grip length 274 can be selected so that it is equal to or greater than the depth 201 of the cleaning unit 130, and optionally may be greater than twice the depth 201 in the direction of the central longitudinal axis 144 of the air treatment member assembly 110 or of the cleaning unit 130 or of the portion of the upright section on which the cleaning unit is provided. In this arrangement, the grip portion 270 may be sized to be comfortable for the user, without being limited by the depth 201 of the cleaning unit 130, or the depth 256 of the air treatment member assembly 110, as may be the circumstance if the grip axis 272 extended in the forward/rearward direction.
For example, the grip length 274 may be selected to be between about 3 inches and about 10 inches, or more, without changing the depth 201 of the cleaning unit 130 or depth 256 of the air treatment member assembly 110. Optionally, the grip length 274 can be selected so that it is between about 60% and about 150% of the depth 201 of the cleaning unit 130. For example, for a cleaning unit 130 having a depth 201 of about 6 inches, the grip length 274 may be about 4 inches (about 60%), or about 6 inches (about 100% of the depth), e.g., in the range of 4-5 inches. If the cleaning unit depth 201 is about 4 inches, the a grip length 274 of 4 inches would be about 100% of the depth, and a grip length 274 of 6 inches would be about 150% of the depth. Providing a grip 270 with a grip length 274 that is equal to or greater than the depth 201 of the cleaning unit 130 may help provide a relatively large, comfortable grip portion 270 on a relatively thin upright section 102.
In the embodiments, the carry handle 258 is positioned close to the front side of the air treatment member assembly 110 and is proximate the front face 242 of the air treatment member assembly 110 and the front plane 198 of the cleaning unit 130, i.e. the grip axis 272 is closer to the front plane 198 than the rear plane 200. In this position, the carry handle, and the grip portion, are positioned above and overlie the upper end 244 of the air treatment member assembly 110, and in particular overlie portions of the cyclone chamber 188 and the dirt collection chamber 190. While illustrated as being at the upper end 244 of the air treatment member assembly 110, the carry handle 258 may be provided at other locations, such as along one of the lateral sides of the air treatment member assembly 110.
In the illustrated embodiments, the carry handle 258 is provided on the openable upper door 262, and moves with the upper door 262 when it is opened (
In a further alternate embodiment, the carry handle 258 may be placed on the support structure 212 (such as cross-member 216) provided that the handle 124 and its connection to the cleaning unit 130 and/or the support structure 212 (e.g., pivot joint 386) does not interfere with placing carry handle at that location.
Cyclone (Air Treatment Member) Configuration
The following is a description of cyclone configurations that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the cyclone configurations described herein may be used with any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, the air treatment member is configured to reduce the overall depth of the air treatment member assembly. Accordingly, the dirt collection region or regions are positioned external to the air treatment member. By positioning the dirt collection region or regions external to the air treatment member, a portion of a dirt collection region need not be positioned in front or behind the air treatment member (see for example
It will be appreciated that the air treatment member may be provided in the form of any suitable cyclone(s), swirl chamber or the like which are known in the surface cleaning art. In the illustrated embodiments (see
A variety of air treatment member assemblies are described herein, having different arrangements and configurations of the cyclone chambers and dirt collection chambers. Any of these air treatment member configurations may be used in combination with any of the other, compatible features described herein.
As exemplified, the cyclone chamber 188 includes a first end wall 278, a second end wall 280 axially spaced apart from the first end wall and a generally cylindrical sidewall 282 extending between the first and second end walls 278, 280. Optionally, some or all of the cyclone walls may coincide with portions of the dirt collection chamber walls, and/or may form portions of the outer surface of the cleaning unit 130 and upright section 102. Alternatively, in some examples some or all of the cyclone walls can be distinct from other portions of the cleaning unit 130, and may not overlap or be co-incident with other walls in the air treatment member assembly 110. Referring to the embodiment of
Referring to
The dirt outlet 288 (or 288a) may have any suitable configuration and be provided at any location in the cyclone chamber 188 (or 188a). For example, if a dirt collection region is provided below or above a cyclone chamber that has a longitudinal axis that extends vertically when the upright section is in the upright storage position of
Optionally each cyclone chamber may be configured to include one dirt outlet, or more than one dirt outlet. For example, a dirt outlet 288 may be provided for each dirt collection chamber 190. Referring to
As exemplified, the dirt outlets 288 may be provided toward the upper end of the cyclone chamber 188, and at the upper end 244 of the air treatment member assembly 110 itself. In contrast, both the air inlet 284 and air outlet 286 may be provided toward the opposed, lower end 280 of the cyclone chamber 188, which corresponds to about the vertical mid-point of the air treatment member assembly 110. A cyclone with this orientation may be referred to as an inverted cyclone.
In this embodiment, and in the embodiments of
In other embodiments, such as shown in
When the air treatment member assembly 110 is mounted to the upright section, the aperture 292 is in fluid communication with the pre-motor filter chamber 194. This arrangement can also help simplify the air flow path, as the air exiting the cyclone chamber 188 may travel linearly along the direction of the cyclone axis 276 directly into the pre-motor filter chamber 194 and, in the illustrated embodiments, to the suction motor 112 that is positioned beneath the air treatment member assembly 110. Reducing the number of turns/corners along this portion of the air flow path may help reduce the back pressure in the air flow path. It will be appreciated that, in some embodiments, the suction motor inlet need not be aligned with, or extend in the same direction as, the cyclone chamber air outlet.
Alternatively, the cyclone chamber 188 may be configured as an inverted cyclone but may only include a single dirt outlet 288, which in the embodiment of
Optionally, the cyclone chamber 188 may oriented in a generally upright configuration (i.e. the cyclone axis 276 (or axis 276a) is generally parallel to the handle axis 134 when the apparatus is in the upright position), but may alternatively be arranged so that the air outlet 286 is provided toward the top of the cyclone chamber 188, instead of the bottom. For example, in the embodiment of
Alternatively, instead of arranging the cyclone chamber 188 in a generally upright configuration (in which the cyclone axis 276 is substantially parallel to the handle axis 134 in the upright position), the cyclone chamber 188 may be oriented in a lateral/sideways configuration in which the cyclone axis 276 is generally horizontal when the apparatus 100 is in the storage position, and optionally the cyclone axis 276 may be substantially orthogonal to the handle axis 137 when in the upright position. In the horizontal orientation, the cyclone chamber 188 may be oriented so that the cyclone axis 276 extends substantially laterally, i.e. substantially orthogonal to the longitudinal axis 144 (
In the embodiment of
To supply air to the cyclone chamber 188, this embodiment includes an air inlet conduit 294 which, in the example illustrated is analogous to the air exit conduit 290 and, may extend from an inlet aperture 296 in the lower door 260 to the air inlet 284 in the cyclone chamber 188. In this arrangement, air travels generally upwardly into the cyclone chamber 188, rotates within the chamber, and travels downwardly from the cyclone chamber 188 to the rest of the air flow path. In the illustrated embodiment, much (and optionally all) of the dirt collection chamber 190 is located laterally between the air inlet 294 and exit conduits 290, and below the cyclone chamber 188.
Alternatively, instead of having a uniflow configuration, a laterally oriented cyclone may be configured with the air inlet and air outlet located toward the same end of the cyclone chamber. To provide air flow connections, the air treatment member assembly includes air inlet conduit 294 and air exit conduit 290 that may extend generally parallel to each other and may be located on toward the same side of the air treatment member assembly 110. As exemplified in
In the embodiment of
In the illustrated embodiments, the cyclone chambers 188 are generally cylindrical, and have a cyclone diameter 298 (
In some configurations, such as shown in
Preferably, at least one portion of each cyclone chamber is openable. For example, a least a portion of the cyclone chambers 188 and 188a may be openable. This may help facilitate access to the cyclone chamber 188 or 188a for emptying, inspection, maintenance and the like. Optionally, one or both of the end walls 278, 280 of the cyclone chamber 188 may be openable. Referring to
Alternatively, the end walls 278, 280 of the cyclone chamber 188 may be fixed, and a portion of the sidewall 282 may be openable. Examples of this configuration are shown in
In some embodiments, the cyclone chamber 188 need not be openable, as is shown in the embodiment of
It will be appreciated that, in some embodiments, the air treatment member may comprise two or more cyclone or other air treatment members in parallel with each other, rather than in series as illustrated with cyclone chambers 188 and 188a. Each cyclone chamber may include any suitable number of air inlets, air outlets and dirt outlets. For example, a cyclone may include four air inlets, one air outlet and two dirt outlets, or one air inlet, one air outlet and two dirt outlets, and the like.
Dirt Collection Chamber
The following is a description of dirt collection chambers that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the dirt collection chambers described herein may be used with any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, some and preferably all of the dirt collection chamber or chambers are positioned external to the cyclone chamber. By positioning the dirt collection chamber or chambers exterior to the air treatment member, the dirt collection chamber or chambers may be positioned in a portion of the footprint of the cleaning unit 130 in which the air treatment member is not located. In this way, the dirt collection region or regions may be located and sized so as to not increase the depth of the cleaning unit, or to limit the extent to which the depth of the cleaning unit is increased. Accordingly, if the air treatment member has a longitudinal axis that extends vertically when the upright section is in the storage position, then the dirt collection region or regions may be laterally spaced from the air treatment member and if the air treatment member has a longitudinal axis that extends horizontally when the upright section is in the storage position, then the dirt collection region or regions may be spaced above or below the air treatment member.
The air treatment member assemblies 110 used in combination with the apparatuses 100 described herein can include any suitable type and/or configuration of dirt collection chamber 190 and/or dirt collection chamber 190a to receive and retain dirt and debris separated from the dirty air flowing through the air treatment member, for example the cyclone chambers 188/188a. Optionally, the dirt collection chambers 190/190a can at least partially, laterally surround the cyclone chambers 188/188a. For example portions of the dirt collection chamber 190 can be positioned forward of the cyclone chamber 188, rearward of the cyclone chamber 188, to the left or right sides of the cyclone chamber 188, or any suitable combination thereof. Dirt chamber 190a and cyclone chamber 188a may have an analogous configuration. In addition, portions of the dirt collection chambers 190/190a can extend below and beneath the cyclone chamber (or optionally above and overlie), such that the cyclone chamber 188/188a overlies (or underlies) some or all of the dirt collection chamber 190/190a. Configuring the cyclone chamber 188 and the dirt collection chamber 190 in this manner, at least partially, may help reduce the overall size of the air treatment member assembly 110.
Optionally, the dirt collection chamber 190 may be configured so that the dirt collection chamber 190 is only positioned laterally beside the cyclone chamber 188, and that the dirt collection chamber 190 does not extend completely in front of or behind the cyclone chamber 188. Optionally, the dirt collection chamber 190 may be configured so that the maximum depth 300 (
Referring to
Optionally, instead of extending between the front and rear walls of the air treatment member assembly 110, the cyclone chamber 188 may be sized and/or positioned so that the dirt collection chamber 190 is at least partially in front or behind the cyclone chamber 188. Accordingly, the cyclone chamber will not extend all the way to the front or rear wall of the air treatment member assembly 110. This may help reduce the overall size of the air treatment member assembly 110, while providing a dirt collection chamber 190 with a desired internal volume. For example, in the embodiment of
Optionally, instead of providing dirt collection chambers 190, or portions thereof, on both lateral sides of the cyclone chamber 188, the dirt collection chamber 190 may be provided on only one lateral side of the cyclone chamber 188 and optionally may extend beneath the cyclone chamber 188. For example, in the embodiment of
In the embodiment of
Optionally, the cyclone chamber 188 need not be nested within the dirt collection chamber in the forward/rearward direction at all, and in some embodiments may be located substantially and/or entirely forward or rearward of the dirt collection chamber 190. Such configurations may allow the interior of dirt collection chamber 190 to be generally free from obstruction by the cyclone chamber 188. This may also allow the cyclone chamber 188 to be nested within the support structure 212, while the dirt collection chamber 190 remains located toward the front or rear of the cleaning unit 130. This configuration may allow different air flow path configurations, as neither the inlet nor the exit conduits 294, 290 need to pass through the interior of the dirt collection chamber 190. In the embodiment of
Optionally, the dirt collection chamber 190 may be configured so that it does not extend underlie or extend below the bottom of the cyclone chamber 188. Portions of the dirt collection chamber 190 may be positioned laterally beside the cyclone chamber 188, and portions of the dirt collection chamber 190 may extend below the bottom end of the cyclone chamber 188 without extending beneath the cyclone chamber 188. For example,
The dirt collection chamber 190 or 190a may be sized to have any suitable internal volume for holding dirt. For example, the volume of the dirt collection chamber 190 may be between about 0.5 to about 2.5 liters, from about 1 to about 2 liters, or more in some applications, and may be between about 0.5 gallon and about 1 gallon. Optionally, the dirt collection chamber 190 can be configured so that at least a portion of the volume is provided laterally around the cyclone chamber 188 (such as the left and right portions in the upper region 302 of
In some embodiments, the dirt collection chamber 190 may have different depths at different locations within the dirt collection chamber. Referring to
Optionally, one or both ends of the dirt collection chambers 190/190a may be openable for emptying. In the embodiment of
Pre-Motor Filter
The following is a description of pre-motor filters that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the pre-motor filters described herein may be used with any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, the pre-motor filter may be positioned so as to be visible or accessible when the air treatment member assembly is removed. Alternately or in addition, the pre-motor filter assembly may be positioned in a linear air flow path extending from the air treatment member air outlet to the suction motor air inlet.
Optionally, a pre-motor filter may be provided in the air flow path between the air treatment member assembly and the suction motor. The pre-motor filter may be housed in a pre-motor filter housing that may, optionally, be provided in the cleaning unit 130. The pre-motor filter may be any suitable filter, including a physical, porous media filter (e.g., foam, felt), electrostatic filter, HEPA filter and the like. The pre-motor filter may have any suitable physical configuration and may be positioned in any suitable location that is consistent with the cleaning unit and/or air treatment member in a given embodiment of the apparatus 100.
In the illustrated embodiments (see for example
In the embodiments of
In these embodiments, the upstream side 318 may be in communication with an upstream header area 320 (
The pre-motor filter 120 may be removed from the pre-motor filter chamber 194 when the air treatment member assembly is removed (
As exemplified in
In these embodiments, the pre-motor filter chamber 194, and pre-motor filter 120, may extend the entire lateral width 238 of the cleaning unit 130. This may help increase the upstream and downstream flow areas. Alternatively, the pre-motor filter chamber 194 and pre-motor filter 120 may extend across only a portion of the width 238 of the cleaning unit 130. Optionally, the pre-motor filter chamber 194, and pre-motor filter 120, may be configured to extend over at least 40%, and optionally at least 50%, at least 60%, at least 70%, at least 75%, at least 80% or more of the overall depth 201 of the cleaning unit 130. Increasing the depth of the pre-motor filter 120 may help increase its upstream flow area and reduce the frequency of cleaning or replacing the pre-motor filter. Referring to
Alternatively, instead of being configured as a generally planar filter, the pre-motor filter 120 may be configured as a generally cylindrical filter. In the embodiment illustrated in
As exemplified in
Referring to
In this embodiment, the pre-motor filter chamber 194 and pre-motor filter 120 underlie the cyclone chamber 188 and overlie at least a portion of the suction motor 112, but does not extend beneath the dirt collection chamber 190 or above the post-motor filter chamber 196.
Positioning of the Suction Motor
The following is a description of suction motors that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the suction motors described herein may be used with any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, the suction motor housing 118, and the suction motor positioned therein, may be sized so as not to increase the depth of the cleaning unit 130 or the upright section at the location of the cleaning unit 130. Accordingly, the diameter 335 of the suction motor housing 118 may be equal to or less than depth 201 and may be equal to or less than depth 230. Optionally, the suction motor may be sized so that the depth 230 of the air treatment member assembly 110 is the same as the diameter of the suction motor ±2 inches or ±1 inches. Optionally, as shown in
The suction motor 112 used in combination with the embodiments described herein may be any suitable type of suction motor, and may include a motor portion and a fan/impeller portion for moving the air. For example, the suction motor 112 may be an AC motor or a DC motor, or both. The suction motor 112 may be powered by plugging the apparatus 100 into a wall outlet (typically AC power), by using an on board power source 332 (schematically illustrated in
In the embodiment of
In this embodiment, the suction motor 112 is generally centered between the lateral sides of the cleaning unit 130 in the lateral direction (
The suction motor 112 and the suction motor housing 118 may have any suitable size and shape, and in the embodiment of
In the embodiment of
The embodiments of
Alternatively, instead of positioning the suction motor 112 in the lateral middle of the cleaning unit 130, it may be offset toward one of the sides of the cleaning unit 130. This may help align the suction motor 112 with other operating components (such as if the cyclone chamber 188 is offset toward one side of the air treatment member assembly 110), and/or may allow for different configurations of the air flow path, and in particular the location and configuration of the post-motor filter as described herein.
In contrast,
Positioning the suction motor 112 toward the lower end of the cleaning unit 130 may help lower the position of the centre of gravity of the cleaning unit 130, which may help facilitate steering and maneuvering of the surface cleaning apparatus 100.
While illustrated with the motor axis 330 in the generally upright direction, the suction motor 112 may also be positioned so that the motor axis 330 is generally horizontal, in orientations analogous to the cyclone chamber configurations described herein. Orienting the suction motor 112 laterally may help reduce the overall height of the cleaning unit 130.
Post-Motor Filter
The following is a description of post-motor filters that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the post-motor filters described herein may be used with any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, the post-motor filter, if provided, is positioned so not increase the depth of the cleaning unit 130. Accordingly, the post-motor filter may be positioned so as not to be forward and/or rearward of the suction motor. For example, one or more post-motor filters may be positioned laterally from the suction motor and/or below the suction motor. Accordingly, a post-motor filter may be positioned on each lateral side of the suction motor. In such an embodiment, a clean air outlet may be provided on each lateral side of the cleaning unit.
The post-motor filter may be housed in a post-motor filter chamber positioned in the air flow path downstream from the suction motor. The post-motor filter may be housed in a suitable post-motor filter housing that can, optionally, be provided on the cleaning unit. The post-motor filter may be any suitable filter, including a physical, porous media filter (foam, felt), filter bag, electrostatic filter, HEPA filter and the like. The post-motor filter may have any suitable physical configuration and may be positioned in any suitable location that is consistent with the cleaning unit and/or air treatment member in a given embodiment of the apparatus 100.
In the embodiment of
Alternatively, instead of providing post-motor filters 122 on both lateral sides of the suction motor 112, the apparatus 100 may be configured so that a post-motor filter chamber 196, and the post-motor filter 122 provided therein, are only provided adjacent one lateral side of the suction motor 112. For example, in the embodiments of
Optionally, the post-motor filter chamber 196, and post-motor filter 122, may be positioned to overlap other components in the forward/rearward direction. Referring to
In other embodiments, such as shown in
Like the pre-motor filters, each post-motor filter 122 has an upstream side, through which air enters the post-motor filter, and an opposing downstream side, through which air exits the post-motor filter.
Cleaning Unit Airflow Ducts
The following is a description of cleaning unit air flow ducts that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the cleaning unit air flow ducts described herein may be used with any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, above floor cleaning assemblies, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect some or all of the air flow conduit of the upright section may be configured to have an aspect ratio that reduces the overall depth of the upright section that houses the cleaning unit. For example, some or all of the portions of the air flow conduit that are co-extensive with the cleaning unit 130 may be non-circular (e.g., elliptical or a parallelogram (e.g., rectangular) so that their lateral extent is greater than their depth in the direction of axis 144. Accordingly, the volume of the air flow conduits need not be reduced by changing them from circular in cross section, but may be increased by increasing the length of the conduits in a direction transverse to axis 144.
Alternately, or in addition, some or all of the portions of the air flow conduit that are co-extensive with the cleaning unit 130 may be positioned at locations of the cleaning unit that are located inwardly of the outer lateral extent of the cyclone chamber 188. In this way, the depth of the upright section that houses the cleaning unit need not be increased by the air flow passages that are co-extensive with the cleaning unit or the extent to which they increase the depth may be reduced.
It will be appreciated that, when the apparatus 100 is operated in a floor cleaning mode, the air flow conduits that are co-extensive with the cleaning unit may form part of the cleaning unit itself (see the embodiments of
Referring to
Air then travels upwardly though a the cleaning unit upflow duct 224 which may extend directly to the air treatment member assembly (
Optionally, the transition member 344 may be configured so that its inlet 346 has a different cross-sectional shape than its outlet 348 (taken in a direction orthogonal to the direction of air travel). For example, in this embodiment the inlet 346 is generally circular to match the transverse cross section of the hose 113, while the outlet 348 is generally rectangular in cross-sectional shape, with a width 350 and a length 352 (
Similarly, some or all of the conduits that are co-extensive with cleaning unit (e.g., up flow duct 224 as exemplified in
Above Floor Cleaning Assembly
The following is a description of above floor cleaning assemblies that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the above floor cleaning assemblies described herein may be used with any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, low profile floor cleaning mode, bendable handle, adjustable handles, hose wraps and other features described herein.
Optionally, an above floor cleaning assembly may be provided to allow the apparatus 100 to be used in an above floor cleaning mode. The above floor cleaning assembly may include any suitable apparatus, including a rigid or flexible wand 222, a flexible air flow conduit such as a hose 113, auxiliary cleaning tools and the like. Optionally, referring to the embodiments shown in
It will be appreciated that the wand and/or hose may or may not form part of the air flow path in the floor cleaning mode. In the embodiment of
In the embodiment shown in
When the wand 222 is secured, air can travel upwardly through the wand 222 and into the attached hose 113, which has a downstream end that is connected to the cleaning unit 130, via a suitable transition member 344. To transition to an above floor cleaning mode, the upstream end 226 of the wand 222 may be detached, such that both the wand 222 and hose 113 form an above floor cleaning assembly that is part of the air flow path in the above floor cleaning mode. Alternatively, the hand grip portion 136 may be detached from the upper end of the wand 222, while remaining attached to the hose 113, or the upstream end 360 of the hose 113 may be detached from the hand grip portion 136, to provide alternative above floor cleaning configurations, in which only the hose 113 remains part of the air flow path.
Alternatively, the apparatus may include an above floor cleaning assembly, optionally including a wand 222 and flexible hose 113, which do not form part of the air flow path when the apparatus 100 is in the floor cleaning mode. In such embodiments, portions of the air flow path may be reconfigured, and the hose 113 and wand 222 may be connected and/or disconnected to the cleaning unit 130 (or other suitable portion, such as the surface cleaning head 104) when changing operating mode. Optionally, one or more valves may be provided in the air flow path to help reconfigure the air flow path as needed. The valves may be manually actuable, or may be automatically actuated by changing the configuration of the apparatus.
The embodiment of
For example, in this embodiment (and in the other embodiments described herein) the joint 342 allows the cleaning unit 130 to pivot about pivot axis 364 (or otherwise rotate) relative surface cleaning head to an inclined, use position, and, optionally, may also function as a rotatable mount so that the upright section 102 may rotate clockwise or counter clockwise with respect to the surface cleaning head 104 about an upright section rotation axis 366 (
As exemplified in this embodiment, the up flow duct 224 may have a generally rectangular perimeter shape and cross-sectional area, and has a vertically extending portion that is laterally offset from the suction motor 112 and its housing 118 and nested behind the post-motor filter 122 (
To operate in an above floor cleaning mode, a port 370 on the side of the cleaning unit 130 is opened to provide access to the air flow path. The hose 113 may then be connected to the air flow path. Optionally, a transition member may be provided to connect the generally round outlet end of the hose to the generally rectangular air flow conduit in the cleaning unit. Optionally, the transition member may be configured so that the flow area remains generally constant along the length of the transition member, even as the perimeter shape changes. The transition member may be provided with, and be removable with, the hose 113 as illustrated, or alternatively may be formed as part of the cleaning unit 130 or provided as a separate piece.
Preferably, the outlet end of the transition member may be configured to have a generally similar shape as the portion of the air flow path it is intended to be connected with, such as portions of the up flow duct and air flow conduits in the cleaning unit. This may help facilitate mechanical connection of the transition member to the air flow conduits, and may help reduce changes in the flow area along the length of the air flow path.
In the illustrated embodiment, the transition member is provided in the form of a transition member 344 that has an inlet end 346 that is generally round (i.e. the same shape as the outlet end of the hose 113) and an outlet end 348 that is rectangular (i.e. the same shape as the air flow conduit in the cleaning unit 130). In this configuration, the transition member 344 is sized so that at its outlet end 348 its height 372 (
Referring to
In this example, the air inlet of the air treatment member assembly 110, and the air inlet of the cyclone chamber 188 may each be configured to have a generally similar shape to the air flow conduit 224 and/or the outlet end 348 of the transition member. Accordingly, the air flow path through these conduits may have the same or generally the same cross-sectional area in the flow direction, thereby reducing the back pressure which could be caused by changing the cross sectional area in the flow direction.
As exemplified in
The air flow conduits 224 in the cleaning unit, and optionally the wand 222 and hose 113, may have any suitable shape, including rectangular, ovaloid, round and the like. Providing non-round conduits may help provide conduits that can be relatively narrow in the forward/rearward direction while still having a desired flow area. For example, the air flow duct 224 can have a length 380 (
Low Profile Floor Cleaning Mode
The following is a description of a low profile floor cleaning mode that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the low profile floor cleaning mode described herein may be used with vacuums having any of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, bendable handle, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, in addition to be operable in a conventional, upright floor cleaning mode, the apparatus may also be operable in at least one additional floor cleaning mode, such as a low profile cleaning mode for cleaning under furniture and other obstacles. An advantage of this mode is that, using the slab like configuration provided herein, the surface cleaning head may extend further, and possibly, all the way under furniture having a low ground clearance.
Preferably, upright section may be reconfigurable to help configure the apparatus 100 in a low profile cleaning mode. For example, the handle 124 may be reconfigurable and/or may be movably connected to the cleaning unit 130 so that the orientation of part or all of the handle 124, and the hand grip portion 136, may be changed relative to the cleaning unit 130.
Referring to
Optionally, an additional low profile support wheel 382 may be provided on the rear face of the cleaning unit 130 (see also
Bendable Handle
The following is a description of bendable handles that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the bendable handles described herein may be used with vacuums having any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, adjustable handles, hose wraps and other features described herein.
In accordance with this aspect, the push handle 124 of a surface cleaning apparatus is reconfigurable into the low profile cleaning mode whereby the cleaning unit 130 may be position such that the longitudinal axis of the cleaning unit 130 may be oriented so as to extend generally horizontally (e.g., within 25°, 20°, 15°, 10°, 5° of horizontal) or may in fact extend horizontally without the user having to fully bend over.
The apparatus may be positionable in the low profile cleaning mode using any suitable mechanism. For example, the handle 124 may be bendable and/or movably connected to the cleaning unit 130, such that the orientation of the handle, and hand grip 136, relative to the cleaning unit 130 may be changed. This can allow a common handle 124 and/or hand grip 136 to be used in both the inclined floor cleaning mode and the low profile cleaning mode. Alternatively, a separate low profile handle apparatus may be provided, such that different handles and/or hand grips are used in the different cleaning modes.
Preferably, the length 384 (
As exemplified in
In this example, the support structure 212 may be configured such that it is located to partially or fully overlie the upper end of the cleaning unit 130 (e.g., cross-member 216). An advantage of this configuration is that the pivot joint need not be located rearward of the cleaning unit 130 and therefore need not increase the height of the front of the cleaning unit 130 from the floor when the apparatus 100 is in the low profile mode. The pivot joint 386 may be connected to such forwardly extending portion of the support structure 212 (cross-member 216), such that the pivot joint 386 may overlie a portion of the air treatment member assembly 110 when the apparatus 100 is in the storage position (
Preferably, the pivot joint 386 may be locked with the extension member 126 in the upright configuration (
Optionally, the pivot joint 386 may be nested with other components on the cleaning unit 130, preferably in the forward/rearward direction, which may help reduce the overall depth 201 of the cleaning unit 130. In the embodiment shown in
In this embodiment, the pivot joint 386 may at least partially overlie the carry handle 258 on the air treatment member assembly 110 in the forward/rearward direction, when the apparatus is in the storage position (
Optionally, as illustrated in the embodiment of
Optionally, in addition to pivoting into a low profile use position, the handle 124 may be moveable into a storage position to help reduce the overall size of the apparatus 100 when it is not in use or during shipment.
Referring to
As exemplified in
When the lower pivot joint 422 is locked, as illustrated in
To unlock the lower pivot joint 422, a user may push the button 390 which may be, e.g., on the hand grip 136. Depressing the button 390 causes the linkage rod 392 to translate along the length of the elongate member 126. A lower end 436 of the rod 392 pushes on the upper slider 438, pushing it downwardly (as illustrated). An elongate portion 440 of the upper slider 438 bears against the tab 426, and downward translation of the upper slider 438 thereby leads to a corresponding downward translation of the lower slider 428. When the lower slider 428 has been moved sufficiently downwardly, the tab 426 is removed from the gap 430 and disengages the intermediary housing 434, as shown in
To unlock the upper pivot joint 424, a user may push the button 390 so that the tab portion 442 is driven out of the gap 444 and disengages the upper housing 446. In some embodiments, this may be sufficient to allow rotation about the second axis 398. Alternatively, as illustrated a second release actuator 400 may need to be released to allow rotation about the axis 398. In this embodiment, when the release actuator 400 remains engaged it is sufficient to inhibit rotation about the axis 398, even when button 390 is pressed. This may help provide independent control over the unlocking of the upper and lower pivot joint 422 and 424.
In the illustrated embodiment, the release actuator 400 includes a latch member 448 that is mounted to the upper housing 446 and that extends into a corresponding slot 450 in the intermediary housing 424. When the latch 448 is engaged with the slot 450 (
It will be appreciated that other locking mechanisms known in the handle art may be used.
Adjustable Handle Length
The following is a description of adjustable handle that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the adjustable handle described herein may be used with vacuums having any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handles, hose wraps and other features described herein.
In accordance with this aspect, instead of using a push button, linkage rod and sliders to unlock the pivot joint 386, the pivot joint 386 may be unlocked by re-configuring and/or adjusting portions of the handle 124, cleaning unit 130 or other portion of the apparatus 100. For example, reconfiguring the push handle 124 may be used to selectively lock one or both pivot joints 422, 424. For example, if the push handle 124 telescopes, e.g., it may comprise a stationary handle member and a moveable telescoping handle member, then the moveable telescoping handle member may be engageable with one or both of the pivot joints 422, 424 to lock the pivot joint in position when the handle is telescoped inwardly. For example, as discussed herein, the moveable telescoping handle member may be slidably receivable in one or both of the pivot joints 422, 424 thereby locking the pivot joints 422, 424 in position.
As exemplified in
Referring to
In this embodiment, when the extension member 126 is fully inserted within the sleeve 452 (
Referring also to
In some embodiments, the pivot joint 386 may only include a single pivot joint 386 as exemplified in
Referring to
Alternatively, referring to
Optionally, the pivot joint 386 may form part of the air flow path, much like the joint between the cleaning unit 130 and the surface cleaning head 104 can include an internal air flow conduit. For example, in embodiment of
To provide air flow communication between the wand 222 and the cleaning unit 130, the pivot joint 386 may include an internal fluid passage. Referring to
The pivot joint 386 may be unlocked using an unlocking actuator, which may use a button 390 connected to a linkage rod 392.
Optionally, in addition to moving relative to the cleaning unit 130, the handle may also be configured so that the extension member 126 and/or hand grip 136 can rotate about the handle axis 134. Referring to
Instead of rotating in this manner, the handle 124 may be moved into the storage position in any suitable way, including collapsing or otherwise modifying the shape of the hand grip portion 136, rotating the hand grip 136 relative the extension member 126, detaching the extension member 126 from the pivot joint 386 and stowing it in a suitable location, and the like.
Hose Wrap
The following is a description of hose wraps that may be used by themselves in any surface cleaning apparatus or in any combination or sub-combination with any other feature or features described herein. For example, the hose wraps described herein may be used with vacuums having any one or more of the surface cleaning head, moveable wheels, upright section, air treatment member assemblies, carry handles, cyclone configurations, dirt collection chambers, pre-motor filters, suction motors, post-motor filters, cleaning unit air flow ducts, above floor cleaning assemblies, low profile floor cleaning mode, bendable handles, adjustable handles and other features described herein.
In accordance with this aspect, hose is secured in position on the upright section, preferably surrounding the lateral sides of the cleaning unit 130, such that the hose does not increase the maximum depth of the portion of the upright section that supports the cleaning unit 130.
For example, if the air flow conduits on the upper section 102 include a flexible hose, the cleaning unit 130 may include a hose wrap portion to help support and store the flexible hose when the apparatus is being used in a floor cleaning mode. Optionally, the hose wrap may be provided toward the rear side of the cleaning unit 130, which may help align the hose 113 with the other air flow conduits in the cleaning unit 130 (such as ducts 224 and wand 222).
As exemplified in
Optionally, the hose support 396 may surround an open region, and may also function as a carry handle 416 for lifting the cleaning unit. As exemplified in
The support channel 412 may be configured so that it provides a sufficient grip area such that a user can pick-up the cleaning unit 130 without contacting the underside of the hose 113. This may help improve the stability of the carry handle 416, and may help reduce the chances that the hose 113 may be squeezed or crushed during the lifting process. To that end, the support channel 412 may be sized to receive at least 40% of the hose 113, and optionally may be sized to receive at least 50% or at least 60% of the hose 113, and preferably the hose 113 can be nested at least up to its midpoint within the support channel 412.
Optionally, the cleaning unit 130 may be configured so that the hose support 396, whether configured as a carry handle or not, is the upper most portion of the cleaning unit 130 or the support structure except for the handle 124. This may help position the hose support 396 at a convenient height for users to interact with the hose wrap 369, and the hose 113 thereon. This may also help increase the path length of the hose 113, from the upper end of the wand 222 to the air inlet of the air treatment member assembly 110. Increasing the path length in this manner may allow a longer hose 113 to be provided and stored on the cleaning unit 130, which may help improve the above floor cleaning range.
In embodiments having a hose support 396 (see for example
In this embodiment, the first and second vertical portions 416, 418 and the transverse portion 420 of the hose and the rigid extension wand 222 (i.e. the above floor cleaning assembly) may all lie in a common, central transverse plane 232, which in this embodiment may extend through one or both of the suction motor 112 and cyclone chamber 188 (see for example
Similarly, in this embodiment, the transverse plane 234 that contains the forward most portions of the rigid wand 222 and hose 113 may be positioned forward of the rearmost portion of the air treatment member assembly 110, and a rearmost portion of the above floor clean assembly may lie in, or forward of, the rear plane 200 (bounding the rear side of the cleaning unit).
What has been described above has been intended to be illustrative of the invention and non-limiting and it will be understood by persons skilled in the art that other variants and modifications may be made without departing from the scope of the invention as defined in the claims appended hereto. The scope of the claims should not be limited by the preferred embodiments and examples, but should be given the broadest interpretation consistent with the description as a whole.
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