Patent Application
20180296044
The invention relates to suction nozzle for a portable hard surface cleaning apparatus for drawing off and suctioning off liquid from a hard surface, in particular from a window pane, comprising a suction nozzle housing having a first and a second housing half-shell which between them form a suction duct, wherein the suction duct extends from a suction opening at which a replaceable squeegee lip is held in place, to a suction duct end section to which a source of vacuum is connectable for creating a suction flow and wherein the two housing half-shells each have at least one holding element adjacent to the suction opening and a holding section of the replaceable squeegee lip is arranged between the holding elements of the two housing half-shells for holding the replaceable squeegee lip in place at the suction opening.
Furthermore, the invention relates to a portable hard surface cleaning apparatus having such a suction nozzle.
WO 2015/007328 A1 discloses a portable hard surface cleaning apparatus with the aid of which a hard surface, in particular a window pane, can be cleaned. The portable hard surface cleaning apparatus comprises a suction nozzle having a squeegee lip which can be moved along the hard surface in the manner of a manual window squeegee so that liquid can be drawn off the hard surface. The liquid collects at a suction opening of the suction nozzle and can be sucked up from the suction opening via a suction duct and transferred to a dirty-liquid tank. To this end, the portable hard surface cleaning apparatus comprises a suction unit which is in flow communication with the suction duct. By way of the suction unit, a suction flow can be created in the area of the suction opening under whose action a mixture of liquid and air is sucked in via the suction opening.
U.S. Pat. No. 5,184,372 discloses a suction nozzle comprising two housing half-shells which form between them a suction duct that extends from the suction opening to a suction duct end section which can be connected to a vacuum source. A replaceable squeegee lip is held in place at the suction opening. One of the two housing half-shells has formed thereon a holding element in the form of a groove which receives a projection of the replaceable squeegee lip, provided on one side thereof, and the other one of the housing half-shells has a plurality of supporting elements arranged in spaced-apart relationship to one another in the area of the suction duct, which supporting elements provide support to the replaceable squeegee lip.
It is an object of the present invention to improve a suction nozzle of the kind mentioned at the outset in such a manner that the replaceable squeegee lip is more reliably held in place at the suction opening.
In accordance with the invention, this object is accomplished in a suction nozzle of the generic type by the holding elements of the housing half-shells in each case forming an engagement with the holding section of the replaceable squeegee lip.
In the suction nozzle constructed in accordance with the invention, the holding section of the replaceable squeegee lip is in engagement both with the at least one holding element of the first housing half-shell and with the at least one holding element of the second housing half-shell. The replaceable squeegee lip is thereby reliably held in place at the suction opening by way of the two housing half-shells forming the suction duct. The two housing half-shells form between them the suction duct, and no additional component part is needed for holding the squeegee lip in place. During assembly of the suction nozzle, the two housing half-shells can be connected together, in particular screwed together, with the replaceable squeegee lip interposed therebetween, wherein the holding elements of both of the housing half-shells in each case form an engagement with the holding section of the replaceable squeegee lip.
It is advantageous for the holding section of the replaceable squeegee lip to be positionable between the at least one holding element of the first housing half-shell and the at least one holding element of the second housing half-shell both in a first position of use of the replaceable squeegee lip and in a second position of use of the squeegee lip turned through 180° about a center axis of the squeegee lip, wherein the center axis of the replaceable squeegee lip is oriented parallel to the longitudinal axis of the suction duct. This provides the possibility of turning the squeegee lip and thereby extending the life of the squeegee lip. The squeegee lip can initially assume a first position of use in which it is moved along the hard surface to be cleaned. In the first position of use of the squeegee lip, the holding section thereof is positioned between the holding elements of the two housing half-shells and is in engagement with the holding elements of the two housing half-shells. When in the first position of use, the replaceable squeegee lip can contact the hard surface with a first contact area thereof. Said area can be subjected to wear during cleaning the hard surface, and once a maximum amount of wear is incurred, the achievable cleaning effect is adversely affected. When this amount of wear is reached, the replaceable squeegee lip can be turned through 180° around the center axis thereof oriented parallel to the longitudinal axis of the suction duct, in order to assume a second position of use. In the second position of use, the holding section also assumes a position between the holding elements of the two housing half-shells and is in engagement with the holding elements of the two housing half-shells. When in the second position of use, the squeegee lip can also be moved along the hard surface that is to be cleaned, wherein it contacts the hard surface with a second contact area thereof which has not yet been worn. In both the first position of use and the second position of use, it is ensured by way of the holding elements arranged on the two housing half-shells that the squeegee lip is held reliably in place at the suction opening and that a very good cleaning effect can be achieved by way of the squeegee lip in both positions of use.
It is advantageous for the replaceable squeegee lip to have a symmetrical configuration with respect to the center plane thereof, wherein the center plane is oriented parallel to the longitudinal axis of the suction duct.
For changing the position of use, it is advantageous for the replaceable squeegee lip to be pulled out of the suction nozzle housing in a direction transverse to the longitudinal axis of the suction duct, then turned through 180° about its center axis and then pulled back into the suction nozzle housing in a direction transverse to the longitudinal axis of the suction duct.
Preferably, the position of use of the replaceable squeegee lip can be changed without tools. With such a configuration, the user can grasp the squeegee lip with his or her hand by the squeegee lip's front portion projecting from the suction nozzle housing and pull it sideways, transversely to the longitudinal axis of the suction duct, out of the suction nozzle housing and, after flipping the squeegee lip, back into the suction nozzle housing. In doing so, the holding elements of the two housing half-shells can form a guide for the holding section of the replaceable squeegee lip.
It is preferred for the two housing half-shells to be releasably connected to one another. For example, provision may be made for the two housing half-shells to be screwable to one another or to be releasably latchable to one another.
The holding elements of the housing half-shells form an engagement, preferably a form-locking connection, with the holding section of the replaceable squeegee lip both in the first position of use and in the second position of use of the replaceable squeegee lip.
The holding section of the replaceable squeegee lip preferably has two depressions which have a symmetrical configuration with respect to the center plane of the squeegee lip, in which depressions complementarily configured projections of the holding elements of the first and second half-shells engage both in the first position of use and in the second position of use of the squeegee lip.
In an advantageous embodiment of the invention, the holding section of the replaceable squeegee lip is configured as an enlargement having a symmetrical configuration with respect to the center plane of the replaceable squeegee lip and the holding elements of the two housing half-shells have depressions in which the enlargement engages.
For example, provision may be made for the enlargement of the holding section to be configured in the form of a straight-line bead and for the holding elements of the two housing half-shells each to have a depression into which the bead extends.
By way of example, the bead can have a circular cross-sectional area and the holding sections of the two housing half-shells can accommodate, in their depressions, about one half of the cross-section of the bead in each case.
It is advantageous for at least one holding element of the first housing half-shell to be arranged in the area of the suction duct and form a flow guide element. The at least one holding element which is arranged in the area of the suction duct can provide support to and fixing in place of the replaceable squeegee lip in the area of the suction duct and at the same time act to guide the suction flow.
Preferably, the at least one holding element arranged in the area of the suction duct forms a flow guide rib. The flow guide rib can predetermine a direction of flow for the suction flow in the area of the suction opening so that a mixture of liquid and suction air can flow into the suction duct in a predetermined direction. Flow losses can thereby be kept low and this in turn has the advantage that the energy consumption of the vacuum source can be kept low.
Preferably, a plurality of flow guide ribs in spaced-apart relation to one another are arranged in the area of the suction duct.
It is particularly advantageous for the flow guide ribs to be arranged in a fan-like manner. As seen relative to the centrally located longitudinal axis of the suction duct, the flow guide ribs can have an increasing inclination to the longitudinal axis with increasing distance from the longitudinal axis.
In an advantageous embodiment of the invention, the flow guide ribs are arranged at the same height relative to the longitudinal axis of the suction duct.
In order to keep the resistance to flow of the flow guide ribs low, it is advantageous for the flow guide ribs to taper against the direction of flow of the suction flow.
It is advantageous for the flow guide ribs to in each case have, at their upper edge facing away from the first housing half-shell, a depression into which the holding section of the replaceable squeegee lip extends.
As seen in the direction of flow of the suction flow, the depressions are preferably arranged in a rear end region of the upper edge and, in a section upstream of the depressions, the upper edges of the flow guide ribs preferably form a planar contact face for the replaceable squeegee lip. In an advantageous embodiment, the contact face is inclined towards a bottom wall of the suction duct.
It is advantageous for the flow guide ribs to be of wedge-shaped configuration in cross-section. In a lengthwise section, they can have an increasing height relative to the bottom wall of the suction duct, as seen in the direction of flow of the suction flow.
Preferably, the replaceable squeegee lip makes contact with the flow guide ribs over at least one half of its extension, relative to the direction of flow of the suction flow.
In addition to the at least one holding element that is arranged inside of the suction duct, the first housing half-shell in a preferred embodiment has at least one further holding element that is arranged outside of the suction duct.
In particular, provision may be made for the first housing half-shell to have two further holding elements which are arranged outside of the suction duct in symmetrical relation with each other, relative to the longitudinal axis of the suction duct. The two holding elements arranged outside of the suction duct can in each case extend from one side wall of the suction duct to an edge of the housing half-shell.
In an advantageous embodiment of the invention, the second housing half-shell has a holding element which extends along the entire holding section of the replaceable squeegee lip and thus forms an engagement with the holding section along the entire holding section.
In a particularly preferred embodiment of the invention, the suction nozzle has, in addition to a replaceable squeegee lip, a non-replaceable squeegee lip which is integrally formed on the first housing half-shell. The non-replaceable squeegee lip can provide support to the replaceable squeegee lip. In cleaning a hard surface, the liquid existing on the hard surface is drawn off by way of the replaceable squeegee lip, thereby subjecting the replaceable squeegee lip to wear, in particular if the hard surface is rough. The non-replaceable squeegee lip, on the other hand, is subjected to only minor, if any, wear and this has practically no effect on the cleaning effect that can be achieved.
It is advantageous for the non-replaceable squeegee lip together with the first housing half-shell to form an injection-molded part comprising a hard component and an elastomer component. The hard component can form the wall of the first housing half-shell, and the elastomer component can form the non-replaceable squeegee lip which, because of the elastomer material used for it, is of flexible, namely flexurally flexible, configuration in a manner corresponding to that of the replaceable squeegee lip.
By way of example, a polypropylene material or an ABS (acrylonitrile-butadiene-styrene) material may be used as the hard component, particularly a talc-reinforced polypropylene material.
By way of example, a thermoplastic elastomer material may be used as the elastomer component.
The elastomer component forms the non-replaceable squeegee lip. In an advantageous embodiment of the invention, the at least one holding element which is arranged in the area of the suction duct is at least partially surrounded by the elastomer component in a circumferential direction.
Preferably, one of the two housing half-shells has a latch element in the area of the suction duct end section, which latch element forms an elastically deformable wall section of the suction duct and is overmolded by an elastomer component. When the suction duct end section is connected to the vacuum source, the latch element of the housing half-shell together with a complementarily configured latch element of the vacuum source can form a latched connection. This ensures that the suction nozzle does not unintentionally become detached from the vacuum source. The latch element of the housing half-shell is arranged in the area of the suction duct end section and forms an elastically deformable wall section of the suction duct. In order to prevent allowing suction air to escape from the suction duct in the area of the latch element, the latch element is overmolded by an elastomer component. The elastomer component thus forms a seal element and ensures that the latch element can deform elastically for forming a latched connection.
The latch element advantageously forms a latch hook which has a spring tongue and a latch projection projecting outwards from the spring tongue. The spring tongue forms an elastically deformable wall section of the suction duct and is overmolded by the elastomer component.
The spring tongue is preferably configured in the manner of a leaf spring, one end of which is connected in one piece to the wall of the housing half-shell and the other end of which carries the outwardly protruding latch projection. The spring tongue is overmolded by the elastomer component except for the end thereof that is connected to the wall of the housing half-shell in one piece therewith.
For example, provision may be made for a housing half-shell of the suction nozzle to form an injection-molded part comprising a hard component and an elastomer component, wherein an elastically deformable wall section of the suction duct is formed by the hard component in the form of a spring tongue which, except for an end region thereof, is surrounded by a through-slot extending through the hard component, wherein the through-slot of the hard component is covered by the elastomer component integrally formed on the hard component. The spring tongue is connected in one piece to the hard component at one end only, but is otherwise separated from the hard component by way of the through-slot. This lends elastic deformation capability to the spring tongue. In order to prevent allowing liquid and suction air to escape from the suction duct via the through-slot, the spring tongue is overmolded by the elastomer component, which seals the through-slot. The elastomer component ensures that the spring tongue can flex relative to the hard component of the housing half-shell, whereby the elastomer component is also subjected to flexural loading but without adversely affecting the tightness of the suction duct.
As mentioned at the outset, the invention relates not only to a suction nozzle of the kind described in the foregoing but also to a hard surface cleaning apparatus for drawing off and suctioning off liquid from a hard surface having such a suction nozzle. The portable hard surface cleaning apparatus has a suction unit for creating a suction flow so that a mixture of liquid and air can be sucked off the hard surface being cleaned. Furthermore, the portable hard surface cleaning apparatus constructed in accordance with the invention has a dirty-liquid tank in which the suctioned liquid can be deposited. The portable hard surface cleaning apparatus constructed in accordance with the invention has a separating device for separating the liquid from the suctioned liquid/air mixture.
The separating device is preferably arranged in a separating chamber which is positioned in the flow path between the suction nozzle and the suction unit, and the separated liquid can be transferred from the separating chamber to the dirty-liquid tank. Thus, advantageously, the separating chamber and the dirt-liquid tank are structurally separate from each other.
Preferably, the portable hard surface cleaning apparatus has a suction duct receiving socket which is pluggably connectable to the suction duct end section of the suction nozzle and which has a latch receptacle for receiving a latch projection of the suction nozzle. As has already been mentioned, it is advantageous for the suction nozzle to have a latch element which is arranged in the area of the suction duct end section and is preferably configured as an elastically deformable wall section of the suction duct. Advantageously, the suction nozzle is pluggably connectable to a suction duct receiving socket of the hard surface cleaning apparatus and a latch receptacle is arranged inside of the suction duct receiving socket which cooperates with the latch element of the suction nozzle for effecting a latched connection.
The hard surface cleaning apparatus constructed in accordance with the invention preferably forms a portable window cleaning apparatus.
The following description of a preferred embodiment of the invention, taken in conjunction with the drawing, serves to explain the invention in greater detail.
An advantageous embodiment of a portable hard surface cleaning apparatus in accordance with the invention, denoted in its entirety by reference numeral 10, is shown schematically in the drawings. With the aid of the portable hard surface cleaning apparatus 10, liquid can be drawn off and suctioned off a hard surface, in particular a window pane. Mirror surfaces or tiled walls can also be cleaned by use of the portable hard surface cleaning apparatus 10. The hard surface cleaning apparatus 10 can be moved along the hard surface by the user in the manner of a manual window squeegee. The hard surface cleaning apparatus 10 forms a portable window cleaning apparatus.
The hard surface cleaning apparatus 10 comprises a basic part 12 in which a suction unit 14 is arranged. The suction unit 14 comprises an electric motor 16 which drives a suction turbine 18 for rotational movement. The suction turbine 18 can draw air via a turbine inlet conduit 20 which in the present exemplary embodiment is shown as being of straight-line configuration. The turbine inlet conduit 20 extends into a separating chamber 22. Arranged in the separating chamber 22, at a distance from the turbine inlet conduit 20, is a separating element in the form of an impact wall which covers an inlet opening 26 of the turbine inlet conduit 20 and is generally convexly curved in the direction facing away from the turbine inlet conduit 20.
On the side of the separating chamber 22 facing away from the turbine inlet conduit 20, the basic part 12 forms a suction duct receiving socket 28 which receives a suction duct end section 30 of an advantageous embodiment of a suction nozzle 32 in accordance with the invention. The suction nozzle 32 is shown schematically in the drawings and will be described in greater detail below.
The suction turbine 18 is separated from the separating chamber 22 by way of a first partition wall 34, wherein the turbine inlet conduit 20 passes through the first partition wall 34. In the area of the first partition wall 34, the turbine inlet conduit 20 is surrounded by a seal ring 36 with which it is ensured that liquid cannot inadvertently pass from the separating chamber 22 along the outer side of the turbine inlet conduit 20 to the suction turbine 18.
The basic part 12 has a second partition wall 38 at a distance from the first partition wall 34 and oriented in parallel relation thereto. The suction turbine 18 is arranged between the first partition wall 34 and the second partition wall 38, and the electric motor 16 is arranged on the side of the second partition wall 38 facing away from the suction turbine 18, in a drive chamber 40 of the basic part 12. A motor shaft 42 of the electric motor 16 passes through the second partition wall 38 and is connected to the suction turbine 18 in rotationally fixed relation thereto. The suction turbine 18 can be given rotation by way of the motor shaft 42.
In addition to the electric motor 16, the drive chamber 40 has positioned therein a rechargeable battery 44 and control, switching and charging electronics 46. The control, switching and charging electronics 46 cooperates with an actuating element 48 which in the illustrated exemplary embodiment is configured as a press switch for switching on and off the electric motor 16. Furthermore, the control, switching and charging electronics 46 controls the rotational speed of the electric motor 16 and the charging process for the battery 44. The control, switching and charging electronics 46 and the rechargeable battery 44 are arranged on a common circuit board 49.
The drive chamber 40 is arranged in a hand grip 50 of the basic part 12. The hand grip 50 can be grasped by the user with one hand.
The hand grip 50 extends to a bottom wall 52 of the basic part 12 which permits resting the portable hard surface cleaning apparatus 10 on a supporting surface.
In addition to the basic part 12 and the suction nozzle 32, the portable hard surface cleaning apparatus 10 has a dirty-liquid tank 54 which is toollessly, releasably held on the basic part 12 and has extending thereinto a filling device 56. Via the filling device 56, liquid can pass from the separating chamber 22 into the dirty-liquid tank 54. The filling device 56 has a filler tube 58 and a vent tube 60 which are connected to one another in one piece and extend into the dirty-liquid tank 54.
The dirty-liquid tank 54 has an upper tank section 62 which faces towards the separating chamber 22 and can be inserted in an upper recess 64 of the basic part 12 via an upper opening 63, and a rear tank section 66 which can be inserted in a lower recess 68 of the basic part 12 via a lower opening 67. The upper recess 64 is arranged laterally next to the suction turbine 18 and is in flow communication with the suction turbine 18 so that suction air from the suction turbine 18 can be exhausted to atmosphere via the upper recess 64 and the upper opening 63.
Opening into the upper recess 64 is a fill funnel 70 which is connected in one piece to the first partition wall 34. Via the fill funnel 70, liquid can pass from the separating chamber 22 into a trough-like depression 72 of the filling device 56 which is adjoined by the filler tube 58. The vent tube 60 extends parallel to the filler tube 58, wherein it protrudes, at its upper end facing away from the dirty-liquid tank 54, above the filler tube 58 and extends into the fill funnel 70.
The lower recess 68 is arranged immediately above the bottom wall 52, wherein the bottom wall 52 has, in the area of the lower recess 68, resiliently deformable bottom wall sections and thereby exerts on the dirty-liquid tank 54 a resilient holding force in a direction towards a contact wall 74 arranged at a distance from the bottom wall 52, against which contact wall 74 the rear tank section 66 is in contact at an upper side thereof. The rear tank section 66 can be latched to the lower recess 68 by way of latch elements that are configured complementarily thereto.
The dirty-liquid tank 54 together with the hand grip 50 delimit a through-hole 75, for finger insertion therethrough, of the hard surface cleaning apparatus 10 which permits the user's fingers to be inserted therethrough when he or she holds the portable hard surface cleaning apparatus 10.
The suction nozzle 32 is shown separately in
The two housing half-shells 76, 78 define between them a suction duct 80. At its rear end region facing towards the separating chamber 22, the suction duct 80 forms the suction duct end section 30, already mentioned, which can be inserted in the suction duct receiving socket 28. The suction duct 80 extends between the two housing half-shells 76, 78 from a suction opening 82 to the suction duct end section 30.
The first housing half-shell 76 forms a bottom wall 84 of the suction duct 80 and first arcuately curved side walls 86, 88 of the suction duct 80. In a corresponding manner, the second housing half-shell 78 forms a top wall 90 of the suction duct 80 and second arcuately curved side walls of the suction duct 80 which can be placed onto the first side walls 86, 88 in a flow-tight manner.
For drawing off liquid from a hard surface that is to be cleaned, the suction nozzle 32 has, in the area of the suction opening 82 thereof, a replaceable squeegee lip 92 and a non-replaceable squeegee lip 94. The non-replaceable squeegee lip 94 is integrally formed on the first housing half-shell 76 and forms together with the first housing half-shell 76 an injection molded part having two components, namely a hard component forming the first housing half-shell 76 and an elastomer component forming the non-replaceable squeegee lip 94.
The suction duct 80 has a centrally arranged longitudinal axis 102, and the replaceable squeegee lip 92 is configured symmetrically with respect to its center plane 96 oriented parallel to the longitudinal axis 102 and has a holding section 98 which is formed by a bead 100 having a generally circular shape in cross-section. The bead 100 extends in a direction transverse with respect to the longitudinal axis 102 of the suction duct 80 along the entire length of the replaceable squeegee lip 92 and forms the rear end portion thereof. The front end portion of the replaceable squeegee lip 92 is formed by a first squeegeeing edge 104 and a second squeegeeing edge 106 which extend along an end face 108, facing away from the bead 100, of the replaceable squeegee lip 92.
The first housing half-shell 76 has a plurality of holding elements for fixing in place of the replaceable squeegee lip 92, wherein multiple first holding elements are arranged in the area of the suction duct and each of these forms a flow guide rib 114. The flow guide ribs 114 are arranged in a fan-like manner so that with increasing distance from the longitudinal axis 102 of the suction duct 80, the flow guide ribs 114 are at an increasing inclination to the longitudinal axis 102. All of the flow guide ribs 114 are arranged at the same level, relative to the longitudinal axis 102. They protrude vertically upwards from the bottom wall 84 and have in each case a depression 118 at the upper edge 116 thereof into which the bead 100 extends in a form-locking manner. Upstream of the depressions, the flow guide ribs 114 in each case have, at the upper edges thereof, a planar contact face 119 oriented at an incline with respect to the bottom wall 84, for contacting the replaceable squeegee lip 92. The flow guide ribs 114 provide support to the replaceable squeegee lip 92 in the area of the suction duct 80. The flow guide ribs 114 are optimized in the shape in terms of fluid flow, wherein they are tapered at the front end portions thereof facing towards the non-replaceable squeegee lip 94. In addition to their function of providing support, the flow guide ribs 114 enable a suction flow to be guided with very small losses of flow so that a mixture of liquid and suction air can pass through between the flow guide ribs 114 with only small losses of flow.
In addition to the flow guide rib 114, the first housing half-shell 76 has two further holding elements for fixing the replaceable squeegee lip 92. Said further holding elements are configured in the form of a holding channel 120 and a holding channel 122 which are located outside of the suction duct and which in each case extend away from a first side wall 86 and 88 respectively of the suction duct 80 to an external wall 124, 126 of the first housing half-shell 76.
The second housing half-shell 78 has a holding element in the form of a holding channel 110 for fixing of the replaceable squeegee lip 92 in place at the suction opening 82. The holding channel 110 receives an upper edge portion 112 of the bead 100. In a corresponding manner, the two holding channels 120, 122, which are arranged outside of the suction duct 80, and the flow guide ribs 114, which are arranged within the suction duct 80, receive in each case a lower edge portion 128 of the bead 100 so that the replaceable squeegee lip 92 is fixed in place between the two housing half-shells 76, 78.
For cleaning a hard surface, the portable hard surface cleaning apparatus 10 can be moved with the replaceable squeegee lip 92 along a hard surface that is to be cleaned. The replaceable squeegee lip 92 can initially assume a first position of use in which the first squeegeeing edge 104 faces towards the non-replaceable squeegee lip 94, as illustrated for example in
As has already been mentioned, the suction duct end section 30 can be inserted in the suction duct receiving socket 28 of the basic part 12. This is shown in
The elastomer component extends from the non-replaceable squeegee lip 94 along the first side walls 86, 88 of the suction duct 80 to the latch hook 136. This is shown in
Once the suction nozzle 32 is connected to the basic part 12 by inserting the suction duct end section 30 in the suction duct receiving socket 28, the portable hard surface cleaning apparatus 10 can, in the manner of a manual window squeegee for cleaning a hard surface, in particular a window pane or a glass door, be moved along said hard surface, wherein liquid present on the hard surface can be fed to the suction opening 82 by way of the replaceable squeegee lip 92 and the non-replaceable squeegee lip 94 supporting same. The liquid, together with air, can be aspirated into the suction opening 82 via the suction duct 80 and fed into the separating chamber 22. To this end, the turbine inlet conduit 20 can have a negative pressure applied thereto by the suction unit 14 via the turbine inlet conduit 20. The mixture of liquid and air passes through the suction duct 80 and, inside the separating chamber 22, first strikes an impact plate 144 held to the suction duct end section 30, on which impact plate 144 a portion of the entrained liquid separates out. The liquid/air mixture then impinges against the impact wall 24 on which the remaining entrained liquid separates out, whereas the suctioned air flows around the impact plate 144 and the impact wall 24 and reaches the suction turbine 18 via the turbine inlet conduit 20. From the suction turbine 18, the suctioned air is discharged to the exterior via an annular air outlet chamber 146 which surrounds the upper tank section 62 within the upper recess 64 in a circumferential direction.
The impact plate 144 forms a first separating element for separating liquid, and the impact wall 24 forms a second separating element for separating liquid from the drawn liquid/air mixture. The liquid separated in the separating chamber 22 can reach the dirty-liquid tank 54 via the fill funnel 70 and the filler tube 58. The dirty-liquid tank 54 can be emptied as required. To this end, the user can remove the dirty-liquid tank 54 together with the filling device 56 held thereto from the basic part 12 by pulling the rear tank section 66 out of the lower recess 68 and then removing the upper tank section 62 from the upper recess 64. Subsequently, the user can release the filling device 56 from the dirty-liquid tank 54 and empty the dirty-liquid tank 54. The user can then re-insert the filling device 56 in the dirty-liquid tank 54 and insert same at the upper tank section 62 thereof in the upper recess 64 and at the rear tank section 66 thereof in the lower recess and latch the dirty-liquid tank 54 to the basic part 12.
Should, after prolonged use of the portable hard surface cleaning apparatus 10, the first or second squeegeeing edge 104, 106 that slides along the hard surface to be cleaned become worn, it is possible for the user, as has been described above in detail, to turn over the replaceable squeegee lip 92 through 180° relative to the center axis 130 thereof so that the user can now use the unused squeegeeing edge 104 or 106.
The portable hard surface cleaning apparatus 10 constructed in accordance with the invention is distinguished by long life and can be moved along the hard surface by the user in the usual manner of a manual window squeegee. The portable hard surface cleaning apparatus 10 is distinguished by having low cost of manufacture.
This application is a continuation of International Application Number PCT/EP2015/080887 filed on Dec. 21, 2015, which is incorporated herein by reference in its entirety and for all purposes.
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/EP2015/080887 | Dec 2015 | US |
| Child | 16013448 | US |
