The field of disclosure relates generally to surface cleaning apparatus, docking stations to empty a surface cleaning apparatus, such as a robotic surface cleaning apparatus, and also air treatment apparatus for a surface cleaning apparatus.
Various types of robotic surface cleaning apparatus are known. Robotic vacuum cleaner may have a docking station that charges the robotic vacuum cleaner when the robotic vacuum cleaner is connected to the docking station. Also, a docking station may have means to empty a dirt collection chamber of a robotic surface cleaning apparatus.
In addition, surface cleaning apparatus that use a cyclonic cleaning stage that comprises a plurality of cyclones in parallel are known.
In accordance with a first aspect of this disclosure, a cyclonic array for a surface cleaning apparatus or a docking station for a robotic surface cleaning apparatus comprises a plurality of cyclones is parallel. In accordance with this aspect, the cyclones (which have an axis of rotation that is at an angle to the vertical and, optionally, the axis is oriented generally horizontally) are arranged such that dirt exiting the dirt outlets of the cyclones travels directly to a dirt chamber. Accordingly, the cyclones may be of varying length or the cyclones may be staggered in the direction of the axis of rotation such that an upper cyclone positioned above a lower cyclone has an outlet that is rearward of the rear end of the lower cyclone.
For example, a plurality of cyclones, which are in parallel, may be oriented such that, in operation, some of the cyclones are positioned above other cyclones and the dirt outlets (which may be provided in the sidewall) of the upper cyclones are positioned so as to not overlie the lower cyclones. These cyclones may have the same length but may be staggered so that the dirt outlet end of the upper cyclones is rearward of the dirt outlet end of the lower cyclones. Alternately, or in addition, the lower cyclones may be shorter so that that the dirt outlet end of the upper cyclones is rearward of the dirt outlet end of the lower cyclones.
In accordance with this aspect, there is provided a cyclone array which may be used for a surface cleaning apparatus or a docking station for a robotic surface cleaning apparatus, the cyclone array having a top, a bottom and spaced apart lateral sides, the cyclone array comprising:
In any embodiment, a length of the first upper cyclone between the front end and the rear end of the first upper cyclone may be the same as a length of the first lower cyclone between the front end and the rear end of the first lower cyclone.
In any embodiment, a plane that is transverse to the cyclone axis of rotation of the first upper cyclone may be located at the front end of the first upper cyclone and the front end of the first lower cyclone may be located adjacent the plane and a length of the first upper cyclone between the front end and the rear end of the first upper cyclone may be longer than a length of the first lower cyclone between the front end and the rear end of the first lower cyclone.
In any embodiment, the dirt outlet of the first upper cyclone and the dirt outlet of the first lower cyclone may face a floor of a common dirt collection chamber. Optionally, the floor may comprise an openable door.
In any embodiment, the dirt outlet of the first upper cyclone and the dirt outlet of the first lower cyclone may be provided in a sidewall of the cyclones.
In any embodiment, the air inlet and the air outlet may be provided at the front end of the cyclones and the dirt outlet is provided at the rear end of the cyclones.
In any embodiment, when the cyclone array is oriented with the top above the bottom, the cyclone axes may extend generally horizontally.
In any embodiment, the plurality of cyclones may comprise a first plurality of upper cyclones and a second plurality of lower cyclones.
In accordance with another aspect, a docking station of a surface cleaning apparatus, such as a robotic surface cleaning apparatus is provided with a docking port that is removably connectable to the surface cleaning apparatus, an air flow path extending from the docking port to at least one air treatment member. When the surface cleaning apparatus is docked at the docking station, an air stream containing dirt collected in the surface cleaning apparatus is drawn through the docking port into the docking station where the air is treated to remove the collected dirt and a clean air stream is emitted from the docking station. The air stream may be produced by a motor and fan assembly in the surface cleaning apparatus and/or a motor and fan assembly (a suction motor) in the docking station. Accordingly, the docking station may be used to empty the surface cleaning apparatus.
The docking station may use one or more air treatment members. In one embodiment, the docking station uses a first stage momentum separator and a second stage cyclonic unit, which may comprise a plurality of cyclones in parallel. The cyclonic stage may be arranged with the cyclones disposed such that the cyclone axis of rotation is generally horizontal, generally vertical or at angle to the horizontal and/or vertical plane. In other embodiments, the docking station can use a first stage cyclonic unit rather than a first stage momentum separator. Accordingly, in these embodiments, the docking station can comprise two cyclonic stages.
In embodiments wherein the first stage comprises a momentum separator, the momentum separator may have a screen as part or all of an upper wall thereof and/or part or all of a vertical wall. In either case, a facing wall may be provided spaced from and facing the screen. Therefore, a flow channel may be provided between the screen and the facing wall. The facing wall may be spaced from the screen by 2-40, 4-25, 8-15 or 10 mm/m3 per minute of air flow. If the flow channel extends upwardly (e.g., generally vertically) then the flow channel may define a second stage momentum separator.
The screen may have a surface area (flow area) that is 2-100, 10-100, 20-50 or any in between range (e.g., 5-10 or 30) times the cross sectional flow area of the docking port in a direction of flow through the docking port.
In any embodiment, two or more of the cyclonic stage, the momentum separator and the second stage momentum separator may be emptied concurrently (e.g., they may have a common, openable bottom door).
In accordance with this embodiment, there is provided an apparatus including the cyclone array wherein the apparatus has a flow path from an air inlet to an air outlet wherein air travels along an exterior of the cyclones as the air travels from the rear end of the cyclones to the air inlets at the front end of the cyclones.
In accordance with this embodiment, there is also provided a surface cleaning apparatus including the cyclone array. The cyclone array may be a second cyclonic cleaning stage.
In accordance with this embodiment, there is also provided a docking station for a robotic surface cleaning apparatus including the cyclone array.
In accordance with this embodiment, there is also provided an air treatment apparatus, which may be used for a surface cleaning apparatus or a docking station for a robotic surface cleaning apparatus, comprising:
In any embodiment, air exiting the momentum separator air inlet may be directed generally horizontally towards the opposed portion of the sidewall.
In any embodiment, air exiting the momentum separator air inlet may be directed generally horizontally and downwardly towards the opposed portion of the sidewall.
In any embodiment, air exiting the momentum separator air inlet may be directed generally downwardly.
In any embodiment, the opposed portion of the sidewall may be generally planar.
In any embodiment, the momentum separator air inlet may have an outlet port and the outlet port may extend in a plane that is generally parallel to the opposed portion of the sidewall.
In any embodiment, the inlet portion of the sidewall may extend in a plane that is generally parallel to the opposed portion of the sidewall.
In any embodiment, the lower wall may comprise an openable door.
In any embodiment, the side screen may comprise a majority of the inlet portion of the sidewall.
In any embodiment, the side screen may comprise over 50%, over 60%, over 70%, over 80%, over 90% of the inlet portion of the sidewall.
In any embodiment, the upper wall may also comprise an upper screen. Optionally, the upper screen may comprise a majority of the upper wall. The upper screen may comprise over 50%, over 60%, over 70%, over 80%, over 90% of the upper wall.
In any embodiment, the air treatment apparatus may further comprise an end wall spaced from and facing the side screen wherein an up flow chamber is positioned between the end wall and the side screen.
In any embodiment, the momentum separator may have a bottom openable door.
In any embodiment, the up flow chamber may have a bottom openable up flow chamber door.
In any embodiment, the lower wall may comprise an openable momentum separator door and the momentum separator door and the up flow chamber door are concurrently openable.
In accordance with this embodiment, there is also provided an air treatment apparatus, which may be used for a surface cleaning apparatus or a docking station for a robotic surface cleaning apparatus, comprising:
In any embodiment, air exiting the momentum separator air inlet may be directed generally horizontally towards the sidewall.
In any embodiment, air exiting the momentum separator air inlet may be directed generally horizontally and downwardly towards the sidewall.
In any embodiment, air exiting the momentum separator air inlet may be directed generally downwardly.
In any embodiment, the air treatment apparatus may further comprise a deflector positioned on the upper wall.
The air treatment apparatus of claim 31 wherein the lower wall comprises an openable door.
In any embodiment, the upper screen may comprise a majority of the upper wall. The upper screen may comprise over 50%, over 60%, over 70%, over 80%, over 90% of the upper sidewall.
In any embodiment, the sidewall may also comprise a side screen. The sidewall may comprise first and second opposed sidewalls and the side screen comprises a majority of the first sidewall. The side screen may comprise over 50%, over 60%, over 70%, over 80%, over 90% of the first sidewall. Optionally or in addition, the air treatment apparatus may further comprise an end wall spaced from and facing the side screen wherein an up flow chamber may be positioned between the end wall and the side screen.
In any embodiment, the momentum separator may have a bottom openable door.
In any embodiment, the up flow chamber may have a bottom openable up flow chamber door.
In any embodiment, the lower wall may comprise an openable momentum separator door and the momentum separator door and the up flow chamber door are concurrently openable.
In accordance with this aspect, there is also provided a docking station for a robotic surface cleaning apparatus comprising:
In any embodiment, at least a portion of the dirt outlet of the first upper cyclone may be spaced rearwardly from the rear end of the first lower cyclone.
In any embodiment, a length of the first upper cyclone between the front end and the rear end of the first upper cyclone may be the same as a length of the first lower cyclone between the front end and the rear end of the first lower cyclone.
In any embodiment, a plane that is transverse to the cyclone axis of rotation of the first upper cyclone may be located at the front end of the first upper cyclone and the front end of the first lower cyclone may be located adjacent the plane and a length of the first upper cyclone between the front end and the rear end of the first upper cyclone may be longer than a length of the first lower cyclone between the front end and the rear end of the first lower cyclone.
In any embodiment, when the cyclone array is oriented with the top above the bottom, the cyclone axes may extend at an angle to the vertical, e.g., at about a 45° to the vertical.
In any embodiment, the plurality of cyclones may comprise a first plurality of upper cyclones and a second plurality of lower cyclones. Optionally, the plurality of cyclones may comprise a first plurality of upper cyclones and a second plurality of lower cyclones.
In any embodiment, the dirt outlet of the first upper cyclone and the dirt outlet of the first lower cyclone may face a floor of a common dirt collection chamber. Optionally, the floor may comprise an openable door.
In any embodiment, the at least one dirt collection chamber may comprise a single common dirt collection chamber and dirt exiting the dirt outlet of the first upper cyclone and dirt exiting the dirt outlet of the first lower cyclone may travel downwardly to a floor of the common dirt collection chamber. Optionally the floor may comprise an openable door.
In any embodiment, dirt exiting the dirt outlet of the first upper cyclone and dirt exiting the dirt outlet of the first lower cyclone may travel downwardly to an openable floor of the at least one dirt collection chamber.
In any embodiment, the dirt outlet of the first upper cyclone and the dirt outlet of the first lower cyclone may be provided in a sidewall of the cyclones.
In any embodiment, when the cyclone array is oriented with the top above the bottom, the cyclone axes may extend generally horizontally.
In any embodiment, air exiting the cyclones may travel downwardly.
In any embodiment, the first stage air treatment chamber may have a dirt collection region with an openable bottom door.
In any embodiment, the first stage air treatment chamber may have a dirt collection region with an openable bottom door.
In any embodiment, the at least one dirt collection chamber may have an openable bottom door and the bottom openable door of the at least one dirt collection chamber may be concurrently openable with the bottom openable door of the first stage air treatment chamber.
In any embodiment, when the cyclone array is oriented with the top above the bottom, the dirt outlet of the first upper cyclone may be positioned above the dirt outlet of the first lower cyclone.
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.
Some elements herein may be identified by a part number, which is composed of a base number followed by an alphabetical or subscript-numerical suffix (e.g. 112a, or 1121). Multiple elements herein may be identified by part numbers that share a base number in common and that differ by their suffixes (e.g. 1121, 1122, and 1123). All elements with a common base number may be referred to collectively or generically using the base number without a suffix (e.g. 112).
In embodiments described herein, there is provided an air treatment apparatus. The air treatment apparatus may be used in combination with a surface cleaning apparatus, such as a hard floor cleaning apparatus and/or a vacuum cleaner e.g., an upright surface cleaning apparatus, a canister surface cleaning apparatus, a robotic surface cleaning apparatus, a hand vac, a stick vac and/or an extractor). For example, in at least some embodiments, the air treatment apparatus can be used as a “docking station” to facilitate quick emptying of a surface cleaning apparatus from dust or debris that has collected therein during cleaning operation.
In the example applications described herein, the air treatment apparatus may be used as a “docking station” for a robotic surface cleaning device. In particular, an air inlet (docking port) of the air treatment apparatus may be removably coupleable to a port or outlet of the robotic cleaning device. The port or outlet may be, for example, in fluid communication with a dust collecting chamber of the robotic device. A motor and fan assembly drives the flow of air through the air inlet and into the air treatment apparatus. As air is drawn into the air inlet of the air treatment apparatus, debris located inside of the dust collecting chamber is drawn out of the dust collecting chamber and transferred with the air stream into the air treatment apparatus. The air treatment apparatus may accordingly proceed to treat the incoming stream of air to separate dust and debris therefrom. Once some or all of the dust has been transferred out of the robotic device, the air treatment apparatus may be independently cleaned-out. In this manner, the air treatment apparatus facilitates safe and fast emptying of the robotic surface cleaning device without requiring dismantlement (or opening) of the robotic device each time it is desired to empty out dust and debris.
Referring now to
The air treatment apparatus air inlet 108 is configured to accommodate an incoming stream of dirty air that includes, for example, coarse and fine dust, solid debris as well as other air-borne containments. Airflow received by the air inlet 108 travels into the air treatment apparatus 100 and passes through one or more separating stages that are configured to separate the flow of air from the air-borne containments. Relatively cleaner may then exit the air treatment apparatus 100 through the air outlet 112. In at least some embodiments, a suction device (i.e., suction motor) may connect to the air outlet 112 and may generate a suction force to drive the flow of air between the air inlet 108 and the air outlet 112 (e.g., suction motor 324 of
Referring to
The air treatment apparatus air outlet 112 may also fluidly connect to the air treatment apparatus 100 via an air outlet conduit 120. Alternately, the air outlet conduit 120 may extend from the housing body 104 to allow other devices (i.e., a suction motor) to couple to the air outlet 112 at a spaced distance (e.g., it may be connected to a conduit similar to the conduits used for a built in vacuum system such that the air outlet is exterior to the dwelling). For instance, as exemplified in
As exemplified in
As exemplified in
It will be appreciated that each of the momentum separator and/or cyclone in the first stage separator, and the cyclone array 136 in the second stage separator, as disclosed herein, may be used by itself (e.g., in a surface cleaning apparatus). It will also be appreciated that the momentum separator and/or the cyclone, and the cyclone array may be used in the same surface cleaning apparatus. In some embodiments, the air treatment apparatus can include one or more of the momentum separator, cyclone and cyclone array.
The following is a description of momentum separators that may be used in a docking station as exemplified herein (alone or in combination with one or more other air treatment members), or which may be used by themselves or in combination with one or more other air treatment members in a surface cleaning apparatus. The other air treatment member may be a cyclonic array as discussed subsequently.
Referring to
As exemplified, the momentum separator 128 may comprise a momentum separator chamber 154 which is bounded by an upper wall 156 (also referred to as top wall 156), a lower wall 160 (also referred to as a bottom wall 160), a sidewall 164 which extends between the upper wall 156 and the lower wall 160, and an end wall 172 that extends between a top portion 174 (or a top wall 174) of the housing body 104 and the lower wall 160 of the momentum separator 128. The momentum separator chamber 154 is also bounded, on either side, by lateral walls 178 that extend laterally between the sidewall 164 and the end wall 172 of the housing body 104, as well as vertically between the top housing wall 174 and the bottom wall 160 of the momentum separator. In this example, the end wall 172 faces and is distally opposed from the sidewall 164. It will be appreciated that several of the walls may form part of the housing body 104. In this example, lateral walls 178 and end wall 172 form part of housing body 104.
As exemplified, one or more walls of the momentum separator chamber 154 may comprise porous walls, e.g., part or all of one or more of the walls may be partially or fully porous. The porous wall or porous section of a wall is configured to have openings and to be generally air permeable such that air may exit the momentum separator 128 by flowing outwardly through the openings in the porous wall or porous section. The porous wall or porous section may comprise, for example, a screen, a mesh, a net, a shroud, or any other air permeable medium that is configured to pass air flow, while separating (or filtering) the air flow from dust, dirt and other solid debris. The openings in the porous wall may be selected to inhibit dirt of a predetermined size from exiting the momentum separator.
In at least some embodiments, the porous section of a wall may comprise a majority of a wall. For example, the porous portion of a wall may have a surface area that is between 40-100%, 50-100%, 60-100%, 70-100%, 80-1200% or 90-100%, or anywhere in between, of the total surface area of the porous wall.
The surface area of the porous portion(s) that define the air exit of the momentum separator may also be expressed relative to the opening area of a momentum separator air inlet 182. For example, in some cases the one or more porous wall sections may have a surface area (screen area) that is 2-100, 10-100, 20-50 or any in between range (e.g., 5-10 or 30) times the opening area of the momentum separator air inlet 182 (i.e., the cross-section area of the inlet 182 in a direction transverse to the direction of air flow through the inlet 182). An advantage of using a larger porous portion(s) area is that the greater surface area for air to exit the momentum separator 128 produces a reduced flow rate of air through the porous portion(s), thereby reducing the likelihood that dirt may get pushed through the porous portion(s), which would reduce the separation efficiency of the momentum separator. Accordingly, this can facilitate the filtering of dust, dirt and other air-borne containments from the exiting air stream.
Another advantage of using a large air exit is to avoid generating a wind tunnel like effect as air exits the momentum separator 128. In particular, where a large volume of air exits the momentum separator 128 through a small porous portion, the air flow may experience a sudden increase in flow velocity, which results in air-borne containments being less likely to become separated from the exiting stream of air and to therefore clog the openings.
The momentum separator 128 may include any number of porous walls, or walls which include porous sections. For instance,
Optionally, in addition or in alternative to the side screen 176, the upper wall 156 of the momentum separator 128 may also comprise a porous wall and may include a top screen 180 which is generally air permeable. Accordingly, air can exit the momentum separator 128 by flowing upwardly and outwardly through the top screen 180.
An advantage of using the combination of a top screen 180 and a side screen 176 is that an even larger surface area is provided for air to exit the momentum separator 128. Accordingly, this generates a further reduction in the velocity of the outgoing air stream, which in turn, facilitates the separation of dust and debris from the stream of air. In at least some embodiments, including both the top screen 180 and the side screen 176 can reduce outgoing airflow velocity by as much as 50% as compared to using only the side screen 176.
It will be appreciated that the configurations illustrated in
Referring now back to
As exemplified in
In embodiments wherein the upper wall 156 of the momentum separator 128 includes a top screen 180, air exiting through the top screen 180 may also flow into a side-flow chamber 208. As exemplified in
In various cases, as best exemplified by
Referring to
Momentum Separator with a Generally Horizontal Air Inlet
Optionally, as exemplified in
The momentum separator may be used in a surface cleaning apparatus, such as a robotic surface cleaning apparatus or a hand vac. The momentum separator may use any of the features and/or dimensions of momentum separator 128 and is also exemplified herein as part of a docking station.
As the air stream enters momentum separator chamber 154, the velocity of the air stream may decrease and entrained dirt will fall towards the bottom of the momentum separator chamber 154.
Optionally, the wall opposed to the wall having the momentum separator air inlet 182 (e.g., end wall 172) may be solid. Therefore, air entering the momentum separator chamber 154 cannot continue in a generally linear direction but must change direction and exit the momentum separator chamber 154 on the same side as it entered the momentum separator chamber 154. Accordingly, the air stream will undergo a 180° change in direction that will further enhance the extent to which entrained dirt will become dis-entrained.
As exemplified in
The momentum separator air inlet 182 is optionally situated at an elevated section of the inlet portion 168 along the sidewall 164 (e.g., above the midpoint, in the upper third, or in the upper quarter of the sidewall 164). Accordingly, air enters into the momentum separator 128 from a raised position above any dirt that may have collected in the momentum separator chamber 154 (provided the momentum separator chamber 154 has been emptied when a fill line has been reached) and will therefore tend to not re-entrain dirt that has already been collected. Upon entry to the momentum separator chamber 154, the air stream will experience a reduction in velocity, which facilitates the separation of air borne dust and dirt from the airflow. In various embodiments, air entering the momentum separator 128 may experience a reduction of velocity by as much as 25 to 100 times the original velocity of the air as it exits the outlet port 152 and/or the momentum separator air inlet 182. Dust and dirt, which becomes dis-entrained from the airflow inside of the momentum separator 128, i.e., as a result of the velocity reduction, may collect on top of the lower wall 160 of the momentum separator 128.
In the example embodiment shown in
In other embodiment not shown, the downstream end 148 may be configured to re-direct air entering the momentum separator 128 in any one of a number of other suitable directions (for example, generally horizontally and upwardly, etc.)
Momentum Separator with a Vertical Air Inlet
Optionally, as exemplified in
The momentum separator may be used in a surface cleaning apparatus, such as a robotic surface cleaning apparatus or a hand vac. The momentum separator may use any of the features and/or dimensions of momentum separator 128 and is also exemplified herein as part of a docking station.
As exemplified in
As further exemplified, optionally, if the air exits outlet port 182 vertically or generally vertically, then a deflecting member (or deflector) 388 may be provided, e.g., on the upper wall 156. The deflecting member 388 is preferably positioned such that an incoming stream of dirty air, exiting the outlet port 182, impacts the deflector 388. The air stream is accordingly forced to change direction quickly, and in turn, experience a sudden reduction in velocity. This may help to facilitate separation of solids and other air-borne debris from the incoming stream of air. In addition, if the upper wall 156 comprises or consists of a screen, then the deflector may prevent the incoming air stream being directed directly at the screen.
The deflector 388 may have any suitable shape. In the illustrated embodiment, the deflector 388 has a generally concave shape (see
The following is a description of a single cyclone that may be used by itself or in combination with other air treatment members in a docking station as exemplified herein, or which may be used by itself or in combination with other air treatment members in a surface cleaning apparatus. Accordingly, as exemplified in
As exemplified, cyclone 502 may include a cyclone bin assembly 504 comprising a cyclone chamber 506 and a separate dirt collection chamber 508. Dirt collection chamber 508 is external to the cyclone chamber 506 and is in communication with the cyclone chamber 506, via a dirt outlet 510, to receive dirt and debris exiting the cyclone chamber 506. Cyclone chamber 506 includes an air inlet 182 for receiving a flow of dirty air, and an air outlet 518 through which clean air may exit the chamber 506.
As exemplified, cyclone chamber 506 may also include a cyclone chamber side wall 580 which extends between the first and second cyclone ends. In some cases, lateral walls 178 and end wall 172 may define the cyclone chamber sidewall 580 (e.g.,
Cyclone chamber 506 extends along cyclone axis of rotation 550 between a first cyclone end 506a and a second cyclone end 506b and may be of various designs and orientations. In the embodiment exemplified in
The dirt outlet 510 may have any suitable shape or configuration. For instance, in the embodiment exemplified in
In the embodiment of
In various cases, the cyclone chamber 506 can also be configured as an inverted cyclone. In other words, dirty air may enter from the bottom of the cyclone chamber 506 and exit from the lower end of cyclone chamber 506.
Cyclone air inlet 182 and air outlet 518 may have any suitable configuration. For instance, in the exemplified embodiments, air inlet 182 comprises a tangential opening on the cyclone sidewall 580, while cyclone air outlet 518 may be defined by an opening on the top wall 156 and may comprise an outlet passage 524.
Optionally, a screen 512 may be positioned over the cyclone air outlet 518. Screen 512 may help to prevent dirt and debris (e.g., hair, larger particles of dirt) from exiting cyclone chamber 506 via the air outlet 518. As exemplified, screen 512 can include one or more air permeable regions 514, which permit the flow of air through the screen 512 to the air outlet 518. The permeable regions 514 can comprise, for example, a mesh material. In some cases, the mesh material may be self-supporting (e.g., metal mesh). In other cases, non-permeable frame members 516 can be used as support frame for the mesh material. The non-permeable frame members 516 may surround the permeable regions 514.
In the exemplified embodiment of
In operation, dirty air may flow into the cyclone chamber 506 via the air inlet 182 and cyclonically flow inside cyclone chamber 506 about cyclone axis 550. Air may then exit the cyclone chamber 506 from the air outlet 518. In the exemplified embodiments, air exiting the cyclone chamber 518 may enter the side flow chamber 208 and continue toward the second (downstream) stage separator 132 (e.g., cyclone array 136).
As cyclonic flow is induced inside of cyclone chamber 506, dirt may be ejected from the cyclone chamber 506 into the dirt collection chamber 508, via the dirt outlet 510.
The following is a description of a cyclone array that may be used by itself or in combination with one or more additional air treatment members that may be located upstream and/or downstream from the cyclone array. The cyclone array may be used in a surface cleaning apparatus, such as a robotic surface cleaning apparatus or a hand vac or a docking station. The cyclone array is exemplified herein as part of a docking station.
In accordance with this aspect some, and preferably all, of the cyclones in a cyclone array have a dirt outlet that is positioned such that dirt exiting the dirt outlet is not directed towards another cyclone in the array. Accordingly, dirt exiting the cyclone array may travel unimpeded to a dirt collection chamber. Optionally, this design is utilized when the cyclones have a cyclone axis of rotation that is at an angle (non-zero angle) to the vertical, such as about 75°, 60°, 45° (e.g., as exemplified in
Alternately, or in addition, in accordance with this aspect the cyclone array may be configured to enable air to flow between or along the cyclones. For example, a plurality of housings 216 may be provided wherein each housing has, e.g., 2 or more cyclones, and the housings 216 are spaced apart from each other to enable air to flow therebetween. Alternately, the cyclone may themselves be spaced apart to enable air to flow therebetween.
The cyclones may be provided in a single housing such that a single manifold or header distributes air to each of the cyclones. Alternately, a plurality of such headers may be provided. In the embodiment of
Referring to
Each cyclone 221 may include a cyclone chamber 260 that extends, along a cyclone axis of rotation 244, between a first cyclone end 248 and an axially opposed second cyclone end 252. The axial extension between the first cyclone end 248 and the second cyclone end 252 defines the axial length 280 of the cyclone. A cyclone sidewall 270 may extend between the first and second cyclone ends.
As discussed previously, the cyclone axis of rotation 224 may be oriented in various directions. For instance,
While the exemplified embodiments illustrate each cyclone 221, in the cyclone array 136, as being oriented in the same direction, and in a generally parallel configuration, in other cases, different cyclones 221 in cyclone array 136 may have cyclone axis oriented in different directions.
Each cyclone unit 221 may have one or more air inlets 256 for receiving a flow of air, and a cyclone outlet 264 for an outflow of air.
The cyclone air inlets 256 and air outlet 264 may be located at any suitable position along the axial length of each cyclone 221. In the exemplified embodiments, the air inlet 256 and air outlet 264 are positioned at the first cyclone end 248 (
The cyclone air inlet 256 and outlet 264 may also have any suitable shape or configuration. For instance, as exemplified, each cyclone air inlet 256 may comprise a tangential inlet, and the cyclone 221 may include one or more air inlets 256 positioned circumferentially around the outer perimeter of the cyclone unit 221. The cyclone air outlet 264 may comprise a central opening located in the first cyclone end 248, and may be surrounded by the one or more air inlets 256.
In operation, as exemplified in
Dirt and debris, which becomes separated from the airflow inside of the cyclone chamber 260, exits the cyclone through one or more dirt outlets 268. In the exemplified embodiments, the dirt outlets 268 are provided at the second cyclone end 252, and are configured as apertures (e.g., slot or gap) on the cyclone sidewall 270. As exemplified in
In various embodiments, the cyclones 221 inside of the cyclone array 136 may be arranged into one or more “sets”. For instance, as exemplified in
In the embodiment of
In other cases, cyclone array 136 may include more than two cyclone sets. For example,
In the exemplified embodiments, each cyclone set 236 and 240 can include one or more cyclones 221. For instance,
The cyclone sets may be spaced apart (e.g., vertically or horizontally, as the case may be), by any desired distance. For instance, in
As exemplified, in
It will be understood that gaps 602 may be provided in embodiments wherein the cyclone array 136 is oriented generally horizontally with the cyclones 221 in the upper cyclone row 236 and lower cyclone row 240 positioned one on top of the other such that the upper cyclones 236 fully overly the lower cyclones 240 (e.g., the upper and lower cyclones may have the same diameter and the cyclone axes of rotation may be located in a vertical plane extending through the upper and lower cyclones). Alternatively, as exemplified in
In the embodiment exemplified in
An advantage of using discrete housings is that an airflow path may be provided between adjacent housings. As exemplified, the discrete housings 216 may be spaced apart by gaps 232 formed between opposing lateral sides 228 of each housing 216. Each gap may form part of an airflow path.
Each cyclone housing 216 may comprise one or more cyclones. In the illustrated embodiment, each cyclone housing comprises one upper cyclone 236 positioned above, and in parallel to, one lower cyclone 240.
Air-flowing from the up flow chamber 188 and/or the side-flow chamber 208 (see
In other embodiments, any other airflow path may be used to provide air to header. For example, the air may travel above the cyclone housings and/or between the cyclone housings and/or laterally beside the outer cyclone housing and/or below the cyclone housings.
It will be appreciated that, in one aspect, the cyclones may be of various configurations provided the cyclones have a dirt outlet that permits dirt to exit in a direction such that dirt exiting the dirt outlet is not impeded from collecting on a lower end of the dirt collection chamber by another cyclone in the array. Accordingly, the cyclone air inlet or outlets may be provided at various locations and the dirt outlet may also be provided at various locations. For example, the cyclones may be in a staggered configuration and/or the cyclone axis of rotation may be at an angle to the horizontal.
The dirt outlet 268 of the upper cyclones 236 may be staggered rearwardly of the second cyclone end 252, of the lower cyclone 240, by any suitable staggering distance 288. For example, the staggering distance 288 may be 4 mm, 6 mm, 8 mm, 10 mm or more. A greater staggering distance 288 can reduce the possibility that lower cyclones 240 obstructing dirt exiting the dirt outlet 268 of the upper cyclones 236. Conversely, a smaller staggering distance 288 can allow for a more compact cyclone array configuration.
For example, cyclones 221c and 221d may have a length 280 of 50 mm, cyclones 221a and 221f may have a length 208 of 38 mm, and cyclones 221b and 221e may have a length 280 of 44 mm. In some cases, the cyclone units may also each have a diameter of 5 mm.
In other embodiments, a staggered configuration can be achieved using cyclones of equal length 280. For instance, as exemplified in
As exemplified in
In the embodiment exemplified in
The dirt may travel downwardly to the floor of the dirt collection chamber 276 in a portion of the dirt collection chamber 276 that is a single contiguous space or channel, or in separate channels. As exemplified in
Alternately, as exemplified in
As exemplified, linking or connecting walls 284 may extend between the lower ends of adjacent lateral walls 228 to define part of a top of the dirt collection chamber. Accordingly, lateral walls 228 and rear wall 192 of cyclone housings 216 and front wall 292 may be considered to define a plurality of vertical passages that extend from the dirt outlets of the cyclones of each cyclone unit to a common volume of the dirt collection chamber 276 that is positioned below linking walls 284.
Front wall 292 may be an exterior wall of the apparatus. Alternately, a front wall 298 may be provided forward of front wall 292. As shown in
The following is a description of emptying the air treatment member 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.
As exemplified in
Optionally, as exemplified, lower wall 160 may form a common wall between the first stage separator 124 and the cyclone dirt chamber 276. Accordingly, door 184 can allow concurrent emptying of dirt that has accumulated in both the first stage separator 124 and the dirt collection chamber 276. Alternatively, or in addition, the dirt collection chamber 276 may have a separate openable door 272 from the first stage separator. In particular, this may allow for separate and independent emptying of the dirt collection chamber 276.
In the embodiment of
As exemplified in the embodiment of
The door 184 may be openable in any manner known in the art. For example,
The openable door 184 can also be held in the closed position in any suitable manner. As exemplified in
In some embodiments, the top wall 174 of the apparatus 100 can also form a removable (or openable) top lid 408, which can be detached from the body housing 104 (e.g.,
Any one or more of the removable components may have any or more of the features of the first stage momentum separator, second stage momentum separator and the cyclone array discussed herein.
Alternately, or in addition, as exemplified in
In at least some embodiments, one or more components comprising the air treatment apparatus 100 may be configured for separate or joint removal from the air treatment apparatus 100 (i.e., for maintenance or cleaning). By way of non-limiting examples, the following components may be separately or jointly removed: (a) the momentum separator 128; (b) the cyclone array 136; (c) the combination of the momentum separator 128 and the cyclone array 136; (d) the combination of the momentum separator 128, the cyclone array 136, and the dust collecting chamber 276; (e) the momentum separator 128 and the dust collecting chamber 276 (without the cyclone array 136); (f) the combination of any one of (a) to (e), and one or both of the side screen 176 and the top screen 180.
While the above description provides examples of the embodiments, it will be appreciated that some features and/or functions of the described embodiments are susceptible to modification without departing from the spirit and principles of operation of the described embodiments. Accordingly, 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.
This application is a continuation of U.S. patent application Ser. No. 17/719,265, filed on Apr. 12, 2022, which itself is a continuation of U.S. patent application Ser. No. 16/594,396, filed Oct. 7, 2019 and issued as U.S. Pat. No. 11,318,482 on May 3, 2022, which itself claims priority from co-pending U.S. Provisional Patent Application No. 62/748,840, filed on Oct. 22, 2018, each of which is herein incorporated by reference in its entirety.
Number | Date | Country | |
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62748840 | Oct 2018 | US |
Number | Date | Country | |
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Parent | 17719265 | Apr 2022 | US |
Child | 18302404 | US | |
Parent | 16594396 | Oct 2019 | US |
Child | 17719265 | US |