The present invention relates generally to piston pumps and, more particularly, to a piston pump assembly for use in an under counter dispensing system.
Under counter dispensing systems are known in which hand cleaning fluids are dispensed from a soap spout above a countertop with the pumping mechanism to deliver the hand cleaning fluid to the soap spout from a removable and replaceable liquid containing bottle disposed under the countertop.
For example, U.S. Pat. No. 7,364,053 to Ophardt, issued Apr. 29, 2009, the disclosure of which is incorporated herein by reference, illustrates a soap dispenser for dispensing a foamed liquid soap out of a soap dispensing spout mounted adjacent a washroom sink with the liquid soap and air being delivered to the soap dispensing spout from a liquid pump and an air pump disposed below the counter. Various counter-mounted liquid dispensers and mounting systems for the same are known including, for example, systems taught by U.S. Patent Publication US 2009/0166381 to Phelps et al, issued Jul. 2, 2009 and U.S. Pat. 6,929,150 to Muderlak et al, issued Aug. 16, 2005, the disclosures of which are incorporated herein by reference.
Such known under counter dispensing systems suffer the disadvantage that replacement reservoirs need to be installed underneath the countertop for engagement with the dispensing system and that difficulties arise in respect of the coupling of the replacement reservoirs to the dispensing systems.
To at least partially overcome these and other disadvantages of previously known devices, the present invention provides a piston pump with a piston chamber-forming body and a piston-forming element relatively coaxially reciprocally movable to dispense liquid and air from a discharge outlet, which the discharge outlet is fixed relative to the piston chamber-forming body.
To overcome other disadvantages of previously known devices, the present invention provides a replaceable reservoir cartridge including a pump assembly and a delivery tube facilitating easy coupling of the cartridge to a housing arrangement disposed underneath a countertop.
As a 1st feature, the present invention provides a pump for simultaneously dispensing liquid and air comprising:
a piston chamber-forming body disposed about a central axis,
a piston-forming element received in the piston chamber-forming body coaxially slidable inwardly and outwardly therein between an outward extended position and inward retracted position,
the piston chamber-forming body having an inner tubular member extending axially between an axial inner end of the inner tubular member and an axially outer end of the inner tubular member,
the inner tubular member having a circumferential side wall defining a central passage axially through the inner tubular member open both at the axial inner end of the inner tubular member and the axial outer end of the inner tubular member,
the axially outer end of the inner tubular member open to a discharge outlet,
the piston chamber-forming body having an outer tubular member extending axially between an axial inner end of the outer tubular member and an axially outer end of the outer tubular member,
the outer tubular member disposed coaxially about the inner tubular member,
the piston chamber-forming body having an annular flange fixedly connecting the outer tubular member to the inner tubular member, the annular flange extending radially inwardly from the outer tubular member to the inner tubular member closing the inner end of the outer tubular member,
an annular air chamber defined annularly between the outer tubular member and the inner tubular member axially outwardly of the annular flange, the air chamber closed at an annular axially inner end of the air chamber by the annular flange and open axially outwardly through the axially outer end of the outer tubular member,
at least one axially and circumferentially extending guide slot extending radially through the side wall of the inner tubular member between the air chamber and the central passage,
the inner end of the inner tubular member in communication with liquid in a reservoir,
a liquid chamber defined inside the inner tubular member axially inwardly of the guide slot,
the piston-forming element having an axially extending tubular hollow inner stem extending between an axially inner stem inner end and an axially inner stem outer end,
the inner stem having axially extending passageway therethrough closed at a passageway inner end and open at a passageway outer end through the inner stem outer end,
the inner stem coaxially received within the inner tubular member for reciprocal coaxial sliding therein between the extended position and the retracted position with the inner stem inner end coaxially slidably received in the liquid chamber and the inner stem outer end coaxially slidably received in the inner tubular member axially outwardly of the guide slot,
the piston-forming element having an annular sealing member coaxially slidably received in the air chamber spanning radially between the outer tubular member and the inner tubular member,
the piston-forming element having at least one spoke member extending radially through the guide slot to fixedly couple the inner stem to the annular sealing member with the spoke member being axially slidable in the guide slot with coaxial sliding of the piston-forming element relative to the piston chamber-forming body between the extended position and the retracted position,
the inner stem inner end carrying a fluid piston portion coaxially slidably received in the liquid chamber defining with the liquid chamber, a liquid pump which, with reciprocal coaxial sliding of the piston-forming element relative the piston chamber-forming body, draws the liquid from the reservoir and discharges the liquid into the passageway, axially outwardly through the passageway and out the passageway outer end into the central passage of the inner tubular member,
the annular sealing member having a radially outer seal member engaging the outer tubular member to prevent fluid flow outwardly therebetween and a radially inner seal member engaging the inner tubular member axially outwardly of the guide slot to prevent fluid flow outwardly therebetween,
the annular sealing member coaxially slidably received in the air chamber defining with the air chamber an air pump which, with reciprocal coaxial sliding of the piston-forming element relative the piston chamber-forming body, draws air from the atmosphere into the air chamber and discharges air from the air chamber radially inwardly through the guide slot to the central passage,
wherein with reciprocal coaxial sliding of the piston-forming element relative the piston chamber-forming body, liquid discharged by the liquid pump and air discharged by the air pump are simultaneously passed through the central passage and out the discharge outlet.
As a 2nd feature, the invention provides a pump as in the 1st feature including a one-way air inlet valve to permit air from the atmosphere to be drawn into the air chamber by the air pump when the air pump creates across the one-way air inlet valve a sufficient vacuum below a pressure of the atmosphere air pressure.
As a 3rd feature, the invention provides a pump as in the 2nd feature wherein the one-way air inlet valve permits air from the atmosphere adjacent to the piston chamber-forming body to be drawn into the air chamber by the air pump when the air pump creates across the one-way air inlet valve a sufficient vacuum below a pressure of the atmosphere air pressure.
As a 4th feature, the invention provides a pump as in any one of the 1st, 2nd or 3rd features a pump including a radial transfer port radially through the inner stem into the passageway axially outwardly of the liquid pump,
wherein the air pump discharges air from the air chamber radially inwardly through the guide slot into the central passage about the inner stem open to the radial transfer port and hence through the radial transfer port into the passageway, then simultaneously with the fluid discharged by the liquid pump axially outwardly through the passageway and out the passageway outer end into the central passage of the inner tubular member axially outwardly of the inner stem outer end.
As a 5th feature, the invention provides a pump as in any one of the 1st to 3rd features including:
an annular space extending axially within the central passage radially between the inner stem and the side wall of the inner tubular member open to the guide slot,
the annular space axially outwardly of the liquid pump and closed at an axial inner end by the fluid pump,
a transfer pathway providing communication from the annular space to outwardly of the inner stem outer end,
wherein the air pump discharges air from the air chamber radially inwardly through the guide slot into the annular space and via the transfer pathway to outwardly of the inner stem outer end.
As a 6th feature, the invention provides a pump as in the 5th feature wherein:
the transfer pathway includes a first pathway provided by the annular space extending axially within the central passage radially between the inner stem and the side wall of the inner tubular member open to outwardly of the inner stem outer end of the inner stem, and
the air pump discharges air from the air chamber radially inwardly through the guide slot into the annular space through the annular space to the central passage axially outwardly of the inner stem outer end, and then, simultaneously with the fluid discharged by the liquid pump from the passageway outer end, axially outwardly from the inner stem outer end through the central passage to the discharge outlet.
As a 7th feature, the invention provides a pump as in the 5th or 6th feature wherein:
the transfer pathway includes a second pathway provided by a radial transfer port from the annular space radially through the inner stem into the passageway axially outwardly of the liquid pump, and
the air pump discharges air from the air chamber radially inwardly through the guide slot into the annular space to the radial transfer port and hence through the radial transfer port into the passageway, and then simultaneously with the fluid discharged by the liquid pump axially outwardly through the passageway and out the passageway outer end to the central passage of the inner tubular member axially outwardly of the inner stem outer end.
As an 8th feature, the invention provides a pump as in any one of the 1st to 3rd features including:
a transfer passage provided through the central passage axially outwardly of the liquid pump, the transfer passage providing communication from the guide slot to outwardly of the inner stem outer end,
wherein the air pump discharges air from the air chamber radially inwardly through the guide slot and via the transfer passage to outwardly of the inner stem outer end.
As a 9th feature, the invention provides a pump as in any one of the 1st to 8th features wherein the liquid chamber is defined inside the inner tubular member proximate the inner end of the inner tubular member.
As a 10th feature, the invention provides a pump as in any one of the 1st to 9th features wherein:
the piston-forming element having an engagement member adapted for engagement by an actuator for axial movement of the piston-forming element relative to the piston chamber-forming body.
As an 11th feature, the invention provides a pump as in the 10th feature wherein the engagement member is carried on the annular sealing member.
As a 12th feature, the invention provides a pump as in any one of the 10th or 11th features wherein:
the engagement member comprises an engagement flange extending radially outwardly from the inner stem axially outwardly of the outer tubular member.
As a 13th feature, the invention provides a pump as in any one of the 1st to 12th features wherein:
the side wall of the inner tubular member having a radially inwardly directed inner surface and a radially outwardly directed outer surface,
the outer tubular member having a circumferential side wall coaxially circumferentially there about with a radially inwardly directed inner surface,
the radially outer seal member of the annular sealing member engaging the radially inwardly directed inner surface of the outer tubular member to prevent fluid flow inwardly and outwardly therebetween, and
the radially inner seal member of the annular sealing member engaging radially outwardly directed outer surface of the inner tubular member axially outwardly of the guide slot to prevent fluid flow outwardly therebetween.
As a 14th feature, the invention provides a pump as in any one of the 1st to 13th features wherein:
the radially inner seal member of the annular sealing member engaging the inner tubular member axially outwardly of the guide slot to prevent fluid flow both inwardly and outwardly therebetween.
As a 15th feature, the invention provides a pump as in any one of the 1st to 13th features wherein:
the radially inner seal member of the annular sealing member engaging the inner tubular member axially outwardly of the guide slot to permit air from the atmosphere to flow inwardly therebetween into the air chamber when a sufficient pressure differential exists across the annular sealing member.
As a 16th feature, the invention provides a pump as in any one of the 1st to 15th features wherein the radially inwardly directed inner surface of the outer tubular member having a diameter larger than a diameter of the radially outwardly directed outer surface of the inner tubular member.
As a 17th feature, the invention provides a pump as in any one of the 1st to 16th features wherein the fluid piston portion including:
an inner disc on the inner stem extending radially outwardly from the inner stem engaging the radially inwardly directed side wall of the inner tubular member axially inwardly from the guide slot to prevent liquid flow axially outwardly between the inner disc and the inner tubular member but to permit fluid flow axially outwardly therebetween,
an outer disc on the inner stem spaced axially outwardly from the inner disc and extending radially outwardly from the inner stem engaging the radially inwardly directed side wall of the inner tubular member to prevent liquid flow axially inwardly and outwardly therepast,
a liquid port located on the inner stem between the inner disc and the outer disc providing communication through the inner stem into the passageway, and
a one-way liquid inlet valve permitting liquid flow from the reservoir into the inner end of the inner tubular member and preventing flow from the inner end of the inner tubular member to the reservoir.
As an 18th feature, the invention provides a pump as in any one of the 1st to 17th features wherein the piston-forming element moving downwardly to slide inwardly relative the piston chamber-forming body and the piston-forming element moving upwardly to slide outwardly relative the piston chamber-forming body.
As a 19th feature, the invention provides a pump as in the 18th feature wherein the central axis is vertical.
In another aspect, the present invention provides a piston pump having:
a piston chamber-forming body having an inner tubular member and an outer tubular member fixedly mounted coaxially about the inner tubular member;
axially extending guide slots through the inner tubular member;
a piston-forming element having an inner stem axially slidably received inside the inner tubular member forming axially inwardly of the guide slots, a liquid pump for discharging fluid from an axially inner end of the inner stem through the stem to exit the stem into the inner tubular member axially outwardly of the guide slots;
the piston-forming element having an annular sealing member coaxially slidably received annularly between the inner tubular member and the outer tubular member forming axially outwardly of the guide slots, an air pump to discharge air through the guide slots into the inner tubular member, and the inner stem coupled to the annular sealing member via at least one spoke member extending radially through the guide slot.
In another aspect, the present invention provides a pump for simultaneously dispensing liquid and air comprising:
a piston chamber-forming body disposed about a central axis,
a piston-forming element received in the piston chamber-forming body coaxially slidable inwardly and outwardly therein between an outward extended position and an inward retracted position;
the piston chamber-forming body having an inner tubular member extending axially between an axial inner end of the inner tubular member and an axially outer end of the inner tubular member;
the inner tubular member having a circumferential side wall defining a central passage axially through the inner tubular member open both at the axial inner end of the inner tubular member and the axial outer end of the inner tubular member,
the axially outer end of the inner tubular member open to a discharge outlet,
the piston chamber-forming body having an outer tubular member extending axially between an axial inner end of the outer tubular member and an axially outer end of the outer tubular member,
the outer tubular member disposed coaxially about the inner tubular member,
the piston chamber-forming body having an annular flange fixedly connecting the outer tubular member to the inner tubular member, the annular flange extending radially inwardly from the outer tubular member to the inner tubular member closing the inner end of the outer tubular member,
an annular air chamber defined annularly between the outer tubular member and the inner tubular member axially outwardly of the annular flange, the air chamber closed at an annular axially inner end of the air chamber by the annular flange and open axially outwardly through the axially outer end of the outer tubular member,
at least one axially and circumferentially extending guide slot extending radially through the side wall of the inner tubular member between the air chamber and the central passage,
the inner end of the inner tubular member in communication with liquid in a reservoir,
a liquid chamber defined inside the inner tubular member axially inwardly of the guide slot,
the piston-forming element having an axially extending tubular hollow inner stem extending between an axially inner stem inner end and an axially inner stem outer end,
the inner stem having axially extending passageway therethrough closed at a passageway inner end and open at a passageway outer end through the inner stem outer end,
the inner stem coaxially received within the inner tubular member for reciprocal coaxial sliding therein between the extended position and the retracted position with the inner stem inner end coaxially slidably received in the liquid chamber and the inner stem outer end coaxially slidably received in the inner tubular member axially outwardly of the guide slot,
the piston-forming element having an annular sealing member coaxially slidably received in the air chamber spanning radially between the outer tubular member and the inner tubular member,
the piston-forming element having at least one spoke member extending radially through the guide slot to fixedly couple the inner stem to the annular sealing member with the spoke member being axially slidable in the guide slot with coaxial sliding of the piston-forming element relative to the piston chamber-forming body between the extended position and the retracted position,
the piston-forming element having an engagement member carried on the annular sealing member axially outwardly of the outer tubular member, the engagement member adapted for engagement by an actuator for axial movement of the piston-forming element relative to the piston chamber-forming body,
the inner stem inner end carrying a fluid piston portion coaxially slidably received in the liquid chamber defining with the liquid chamber, a liquid pump which, with reciprocal coaxial sliding of the piston-forming element relative the piston chamber-forming body, draws the liquid from the reservoir and discharges the liquid into the passageway, axially outwardly through the passageway and out the passageway outer end into the central passage of the inner tubular member,
the annular sealing member having a radially outer edge seal member engaging the outer tubular member to prevent fluid flow inwardly and outwardly therebetween and a radially inner edge seal member engaging the inner tubular member axially outwardly of the guide slot to prevent fluid flow inwardly and outwardly therebetween,
the annular sealing member coaxially slidably received in the annular air chamber defining with the annular air chamber an air pump which, with reciprocal coaxial sliding of the piston-forming element relative the piston chamber-forming body, draws air from the atmosphere into the air chamber and discharges air from the annular air chamber radially inwardly through the guide slot to the central passage,
wherein with reciprocal coaxial sliding of the piston-forming element relative the piston chamber-forming body, liquid discharged by the liquid pump is simultaneously discharged with air discharged by the air pump through the central passage and out the discharge outlet.
Further aspects and advantages of the present invention will become apparent from the following description taken together with the accompany drawings in which:
Reference is made to
As seen on
As seen in
A guide tube 219 is secured within the spout 216 extending internally within the spout 216 from an enlarged funnel-like open insert end 220 of the guide tube 219 that extends downwardly as through the open lower end 221 of the inlet tube 217. The guide tube 219 extends from its insert end 220 through the spout 216 to an outlet end 222 of the guide tube 219 secured in an outlet plate 223 fixed in a spout opening 224 of the spout 216. As only schematically shown in
The spout 216 carries a sensor mechanism 226 which senses the presence of a user's hand proximate the spout 216 and suitably activates the dispensing apparatus 100 to discharge soap, liquid and air out the discharge outlet 114 of the delivery tube 112. A sensor communication wire 227 extends from the sensor mechanism 226 internally through the spout 216 and out the inlet tube 217 into the dispenser housing 104. The sensor mechanism 226 may preferably comprise an emitter to emit radiation, preferably infrared light, and a sensor to sense light reflected from a user's hands. Many touchless activation mechanisms are known and many suitably preferred mechanisms utilize infrared light or the specific nature of the sensor is not limited.
The preferred embodiment illustrated in
The guide tube 219 preferably has at its lower insert end 220 a funnel portion presenting an enlarged outer opening which facilitates the insertion of the delivery tube 112 into the guide tube 219.
As seen in
Reference is made to
Within the collar receiving slotway 134, there is provided a resilient yoke member 136 secured at its rear to the rear plate 116 and having two resilient arms 137 and 138 which extend forwardly, one adjacent each of the side plates 118 and 119 to engage the collar 18 in a snap-fit relation requiring a threshold force to be applied to move the collar 18 either into or out of the collar receiving slotway 134.
Above the top support flange 130, a horizontally extending actuator plate 140 is provided coupled at its opposite sides 141 and 142 to the side plates 118 and 119 for relative vertically sliding. In this regard, the side plates 118 and 119 preferably carry vertically extending channel members 143 and 144 to be engaged by slide members on the sides of the actuator plate 140 towards guiding the actuator plate 140 in sliding vertically relative to the dispenser housing 104. The actuator plate 140 carries a catch member 147 that defines a central cavity 146 adapted to receive the engagement flange 16 of the piston-forming element 14.
Reference is made to
Schematically shown within the compartment 238 is a control mechanism 250 and a power source 252. The sensor communication wire 227 is shown as being connected to the control mechanism 250. The control mechanism 250 controls the manner of distribution of power to the motor 240 and to the sensor mechanism 226. The control mechanism 250 may have communication capabilities as via a communication module 254 for communicating with remote devices.
Such an automated mechanism for controlling the movement of the actuator plate 140 may be of the type disclosed in U.S. Pat. No. 8,201,707 to Ophardt, issued Jun. 19, 2012 and U.S. Pat. No. 8,245,877 to Ophardt, issued Aug. 21, 2012, the disclosures of which are incorporated herein by reference.
The delivery tube 112 is of a length that with the cartridge 106 engaged on the dispenser housing 104, the discharge outlet 114 of the delivery tube 112 is suitably positioned preferably extending marginally outwardly from the outlet plate 223 of the spout 216.
For coupling of the cartridge 106 to the dispenser apparatus 100, preferably, prior to the cartridge 106 being coupled to the dispenser housing 104, the flexible delivery tube 112 is manually bent and fed into and through the guide tube 219 as may be understood from broken lines on
In accordance with the first embodiment, compared to an axis passing through the actuator member 140, coupling of the cartridge 106 is accomplished by merely radial movement of the pump assembly 10. Coupling of the cartridge 106 to the dispenser housing 104 with suitable engagement of the delivery tube 112 inside the guide tube 219 is preferably accomplished in accordance with the preferred embodiment by mere forward and rearward horizontal sliding of the cartridge 106 other than suitable flexing and manipulation of the delivery tube 112. However, various other arrangements may be provided in accordance with the present invention for coupling of the cartridge 106 to the dispenser housing 104 as may involve vertical, relative movement of the cartridge 106 relative to the dispenser housing 104, alone or in combination with relative radial movement. For example, coupling may be accomplished merely by axial movement or by a combination of axial and radial movement with or without tilting of the pump assembly.
The preferred actuator member 140 is shown as being merely axially slidable relative to the dispenser housing 104. However, the actuator member 140 may be mounted for other simple relative movement of the actuator member 140 such as on a lever pivotably mounted to the dispenser housing 104. Relative movement can be as disclosed in U.S. Pat. No. 8,071,933 to Ophardt, issued Sep. 6, 2011 and U.S. Pat. No. 5,431,309 to Ophardt, issued Jul. 11, 1995, the disclosures of which are incorporated herein by reference.
Reference is made to
Reference is made to
As seen in the cross-section of
The piston chamber-forming body 12 has a radially outer tubular member 22 and a radially inner tubular member 24 joined by an annular flange 25.
The outer tubular member 22 carries an outer collar tube 26 having a threaded radially inwardly directed surface 27 carrying threads for engagement with complementary threads on the threaded neck 171 of the bottle 108.
The inner tubular member 24 extends axially between an axial inner end 28 of the inner tubular member 24 and an axially outer end 29 of the inner tubular member 22. The inner tubular member 24 has a circumferential side wall 30 which is circular in cross-section, substantially cylindrical and has a diameter. The inner tubular member 24 defines within the circumferential side wall 30 a central passage 32 axially through the inner tubular member 24 open both at the axial inner end 33 of the inner tubular member and the axial outer end 34 of the inner tubular member 24. Three axially and circumferentially extending guide slots 36 extend radially through the side wall 30 of the inner tubular member 24 into the central passage 32. Each guide slot 36 is circumferentially spaced from its adjacent guide slots 36. Each guide slot 36 is defined between opposed axially extending side walls 37 and 38 best seen on
The axially outer end 34 of the inner tubular member 24 at the axially outer end of the piston chamber-forming body 12 is open to the discharge outlet 114 via the discharge tube 112. At the axially outer end 34 of the inner tubular member 24, an annular socket 41 is provided open axially outwardly and adapted to receive in a snap-fit relation an inlet coupling 42 fixedly secured to an inlet end 43 of the delivery tube 112.
Axially inwardly from the socket 42, the inner tubular member 24 carries a foam generator 44. The foam generator 44 comprises a tubular spacer 45 and a pair of axially spaced screens 46 and 47. The particular nature of the foam generator 44 is not limited. The purpose of the foam generator 44 is to generate a mixture of a foamed air and liquid product on simultaneous passing of the air and liquid through the foam generator 44.
The outer tubular member 22 extends axially between an axial inner end 45 of the outer tubular member 22 and an axially outer end 46 of the outer tubular member 22. The outer tubular member 22 is disposed coaxially about the inner tubular member 24. The annular flange 25 fixedly connects the outer tubular member 22 and the inner tubular member 24. The annular flange 25 extends radially inwardly from the outer tubular member 22 to the inner tubular member 24 and closes the inner end 45 of the outer tubular member 22. The outer tubular member 22 has a wall 48 which is circular in cross-section, substantially cylindrical and has a diameter larger than the diameter of the side wall 30 of the inner tubular member 24.
An annular air chamber 50 is defined annularly between the outer tubular member 22 and the inner tubular member 24 axially outwardly of the annular flange 25. The air chamber 50 is closed at an annular axially inner end of the air chamber 50 by the annular flange 25. The air chamber 50 is open axially outwardly at an axial outer end 51 of the annular air chamber 50 opening axially outwardly through the axially outer end 46 of the outer tubular member 22.
The inner end 33 of the inner tubular member 24 is in communication with liquid in the bottle reservoir 108 via a dip tube 52.
A liquid chamber 54 is defined inside the inner tubular member 24 axially inwardly of the guide slots 36. The liquid chamber 54 is approximate the inner end 28 of the inner tubular member 24.
The liquid chamber 54 is defined within the inner tubular member 24 radially inwardly of the side wall 30 of the inner tubular member 24 between an axially inner end 55 and an axially outer end 56. The fluid chamber 54 is circular in cross-section, substantially cylindrical and has a diameter. The axially inner end 55 of the fluid chamber 54 is defined by a radially inwardly extending shoulder 57 with an inlet opening 58 coaxially therethrough opening axially inwardly into a socket 59 open axially inwardly. The socket 59 is adapted to frictionally receive an inner end 60 of the hollow tubular dip tube 52. The dip tube 52 extends downwardly to a lower end 61 disposed approximate the bottom wall 174 of the bottle 108. A one-way inlet valve 62 is secured in the inlet opening 58 in a snap-fit and includes a resilient disc 63 that engages the radially inwardly directed inner surface of the side wall 30 to permit fluid flow axially outwardly therepast yet to prevent fluid flow axially inwardly therepast as in a manner, for example, described in a similar one-way inlet valve in U.S. Pat. No. 5,676,277 to Ophardt issued Oct. 14, 1997, the disclosure of which is incorporated herein by reference.
The fluid chamber 54 is open at its axially outer end 56 via the guide slots 36 into the air chamber 50.
The piston-forming element 14 is generally coaxially about the axis 20.
The piston-forming element 14 has an axially extending tubular hollow inner stem 64 extending between an axially inner stem inner end 65 and an axially inner stem outer end 66. The inner stem 64 has an axially extending passageway 67 therethrough closed at a passageway inner end 68 proximate the inner stem inner end 65 and open at a passageway outer end 69 through the inner stem outer end 66.
The inner stem 64 is coaxially received within the inner tubular member 24 for reciprocal coaxial sliding therein between the extended position and the retracted position with the inner stem inner end 65 coaxially slidably received in the liquid chamber 54 and the inner stem outer end 66 coaxially slidably received in the inner tubular member 24 axially outwardly of the guide slots 36.
The piston-forming element 14 has an annular sealing member 70 coaxially slidably received in the air chamber 50 spanning radially between the outer tubular member 22 and the inner tubular member 24.
The piston-forming element 14 has a bridging member 71 with three spoke members 72, each extending radially through a respective one of the three guide slots 36 to fixedly couple the inner stem 64 to the annular sealing member 70 with each spoke member 72 being axially slidable in a respective guide slot 36 with coaxial sliding of the piston-forming element 14 relative to the piston chamber-forming body 12 between the extended position and the retracted position.
The piston-forming element 14 has an engagement flange 16 carried on the annular sealing member 70 axially outwardly of the outer tubular member 22. The engagement flange 16 is adapted for engagement by an actuator, namely, the actuator plate 140 for axial movement of the piston-forming element 14 relative to the piston chamber-forming body 12. The engagement flange 16 is to be coupled and uncoupled with the actuator plate 140 on the dispenser housing 104 and is provided at an axial location on the piston chamber-forming body 12 axially outwardly of the piston chamber-forming body 12, such that the engagement member 16 can be engaged with and disengaged from the actuator plate 140 by relative radial movement. To accommodate such engagement, the engagement flange 16 extends radially outwardly in the form of a circular disc 73 carrying a plurality of circumferentially spaced resilient finger members 74, each connected to the disc 73 at a first end 75 and extending radially outwardly and axially inwardly to a distal end 76. Adjacent finger members 74 are circumferentially spaced by radially and axially extending slots through the disc 73.
The inner stem inner end 65 is coaxially slidably received in the liquid chamber 54 defining with the liquid chamber 54 the liquid pump 78 which, with reciprocal coaxial sliding of the piston-forming element 14 relative the piston chamber-forming body 12, draws the liquid from the reservoir bottle 108 and discharges the liquid into the passageway 67 and axially outwardly through the passageway 67 out the passageway outer end 69 into the central passage 32 of the inner tubular member 24.
The inner stem 64 carries an axially innermost fluid piston portion 79 coaxially received within the fluid chamber 54 to form the liquid pump 78. The fluid piston portion 79 includes a resilient inner disc 80 that engages the side wall 30 of the inner tubular member 24 in the fluid chamber 54 to permit fluid flow axially outwardly therepast but to prevent fluid flow axially inwardly therepast. The fluid piston portion 79 includes an outer disc 81 that engages the side wall 30 of the inner tubular member 24 in the fluid chamber 54 to prevent fluid flow axially therepast. Liquid ports 82 located on the inner stem 64 between the outer disc 81 and the inner disc 80 extend coaxially through the inner stem 64 into the passageway 67. With reciprocal coaxial movement of the fluid piston portion 79 relative to the fluid chamber 54, fluid is drawn upwardly from the bottle 108 though the dip tube 52 past the one-way inlet valve 62 into the fluid chamber 54 in a retraction stroke and, in an opposite extension stroke, the fluid is discharged axially outwardly past the inner disc 80 into an annular space 83 radially outward of the inner stem 64 and radially inward of the side wall 30 and between the inner disc 80 and the outer disc 81 and hence via the liquid ports 82 radially through the inner stem 64 into the passageway 67 leading to the axially outer end 69. The operation of the liquid pump 78 is substantially the same as described in U.S. Pat. No. 5,676,277 to Ophardt referenced above. However, many other configurations of a piston pump may be adopted for the liquid pump 78 without departing from the present invention.
Axially outwardly on the inner stem 64 from the fluid piston portion 79, notably axially outward of the outer disc 81 of the fluid piston portion 79, transfer ports 84 are provided radially through the inner stem 64 into the passageway 67.
In the liquid pump 78, there is defined between the outer disc 81 and the one-way inlet valve 62, as best seen in
With the piston-forming element 14 engaged on the piston chamber-forming body 12, as seen in
The annular sealing member 70 has a radially outer seal member 89 engaging the outer tubular member 22 to prevent fluid flow inwardly and outwardly therebetween and a radially inner seal member 90 engaging the inner tubular member 24 axially outwardly of the guide slots 36 to prevent fluid flow inwardly and outwardly therebetween. The outer seal member 89 has an annular inner air disc 91 that, at its radially outer end, carries a pair of resilient disc arms 92 and 93. The inner seal member 90 has an annular outer air disc 94 and carries a resilient disc arm 95.
With the piston-forming element 14 engaged on the piston chamber-forming body 12 as seen in
(a) the inner air disc 91 extends radially outwardly with its disc arms 92 and 93 engaging the radially inwardly directed inner surface of the wall 48 of the outer tubular member 22 inside the air chamber 50 to provide a seal preventing flow axially inwardly and outwardly therepast; and
(b) the outer air disc 90 extends radially inwardly with its disc arm 95 engaging a radially outwardly directed surface of the side wall 30 of the inner tubular member 24 axially outwardly of the guide slots 36 to provide a seal preventing flow axially outwardly therepast and to restrict flow axially inwardly therepast.
The annular sealing member 70 is coaxially slidably received in the annular air chamber 50 defining with the annular air chamber 50 an air pump 96 which, with reciprocal coaxial sliding of the piston-forming element 14 relative the piston chamber-forming body 12, draws air from the atmosphere into the air chamber 50 and discharges air from the air chamber 50 radially inwardly through the guide slots 36 into the central passage 32, wherein with reciprocal coaxial sliding of the piston-forming element 14 relative the piston chamber-forming body 12, liquid discharged by the liquid pump 78 is simultaneously discharged with air discharged by the air pump 96 through the central passage 32 and out the discharge tube 112 to the discharge outlet 114.
In a retraction stroke, the air pump 96 forces air from the air chamber 50 radially inwardly through the guide slots 36 simultaneously with the discharge of the liquid from the pump liquid 78 into the passageway 67 for simultaneous discharge of air and liquid into the central passage 32 and then through the foam generator 44 to produce foamed air and liquid that flows through the delivery tube 112 and out the discharge outlet 114. In a withdrawal stroke, the air pump 96 draws into the air chamber 50 foam, air or liquid within the central passage 32 and the delivery tube 112 as well as air from the atmosphere via the discharge outlet 114.
The air pump 96 includes a variable volume air compartment 97 defined between the annular sealing member 70 and the inner stem 64. As seen in
The air compartment 97 has a volume that varies with the axial position of the piston-forming element 14 within the piston chamber-forming body 12 whereby the air pump 96 is formed. In a retraction stroke, the volume of the air compartment 97 decreases forcing air (a) through the transfer ports 84 into the passageway 67 and (b) through the annular space 88 annularly about the axially outer end 66 of the inner stem 64 between inner stem 64 the inner tubular member 24, simultaneously with the discharge of the liquid from the pump liquid 78 into the central passage 32 providing for simultaneous discharge of air and liquid through the foam generator 44 to produce a foamed air and liquid mixture that flows through the delivery tube 112 and out the discharge outlet 114. In a withdrawal stroke, the volume of the air compartment 97 increases drawing foam, air or liquid within the central passage 32 and the delivery tube 112 as well as air from the atmosphere into the air compartment 97 via the discharge outlet 114. If a sufficiently high vacuum is created in the air compartment 97 in a withdrawal stroke, then air will be drawn from the atmosphere axially inwardly past resilient disc arm 95. The extent to which the resilient disc arm 95 is biased radially inwardly into engagement with the inner tubular member 24 will determine a minimum pressure differential between the pressure of atmospheric air on the axially outer side of the disc arm 95 and the pressure within the air compartment 97 at which the disc arm 95 will be deflected to permit atmospheric air to flow therepast into the air compartment 97 and function as a one-way air inlet valve, permitting atmospheric air adjacent to the piston chamber-forming body 12 to be drawn into the air chamber 50. In the first embodiment of the pump assembly of
In the first embodiment of
As seen in
In the first embodiment, the reservoir bottle 104 is preferably a collapsible bottle which collapses as liquid is drawn from the bottle. If the bottle is a non-collapsible bottle, then the bottle is open to the atmosphere at its upper end, for example, directly or via a vacuum relief valve (not shown) permitting atmospheric air to enter the bottle when a vacuum condition is created in the bottle.
Reference is made to
As seen in the cross-section of
The piston chamber-forming body 12, as seen in
The chamber member 323 has a side wall disposed coaxially about the axis 20 with a generally stepped configuration defining a tubular outer portion 327 and a tubular inner portion 328 connected by a radially extending shoulder 329. A slotted central support member 330 extends radially inwardly from the shoulder 329 with the support member 330 coupled to the shoulder 329 at an axial inner end 331 and extending axially outwardly to an outer distal end 332. The support member 330 is in the form of a cylindrical tube from which axially extending guide slots 36 have been cut. Each guide slot 36 is open axially outward at outer open end 334 at the distal end 332 of the support member 330 and extends axially inwardly to a blind end wall 339 axially inwardly toward the shoulder 329, defining between adjacent guide slots 36 circumferentially spaced axially extending guide finger members 336. Each finger member 336 carries at the distal end 332 a radially outwardly extending snap flange 337.
The central take off or exit tube member 324 has an outer tube member 338 joined by a radially inwardly extending inner shoulder 339 to an inner tube member 340. At an axially inner end 341 of the outer tube member 338, a radially outwardly extending outer shoulder 342 supports a socket tube member 343 forming an annular socket 344 open axially inwardly and adapted to receive the distal end 332 of the support member 330 with the finger members 336 and their snap flanges 337 engaged in a snap-fit relation in the annular socket 344 so as to fixedly couple the exit tube member 324 to the support member 330 of the chamber member 323 coaxially about the axis 20.
At an axially outer end 345 of the outer tube member 338, an annular socket 41 is provided open axially outwardly and adapted to receive in a snap-fit relation an inlet coupling 42 fixedly secured to an inlet end 43 of the delivery tube 114.
The foam generator 44 comprises a tubular spacer 45 and a pair of spaced screens 46 and 47 which are provided in the outer tube member 338 sandwiched axially between the inner shoulder 339 and the inlet coupling 42. The particular nature of the foam generator 44 is not limited. The purpose of the foam generator 44 is to generate a consistent mixture of a foamed air and liquid product on simultaneous passing of the air and liquid through the foam generator 44.
A fluid chamber 54 is defined within the tubular inner portion 328 radially inwardly of the wall of the chamber member 323 between an axially inner end 55 and an axially outer end. The fluid chamber 54 is circular in cross-section, substantially cylindrical and has a diameter. The axially inner end 55 of the fluid chamber 54 is defined by a radially inwardly extending shoulder 57 with an inlet opening 58 coaxially therethrough opening axially inwardly into a socket 59 open axially inwardly. The socket 59 is adapted to frictionally receive an inner end 60 of a hollow tubular dip tube 52. The dip tube 52 extends downwardly to a lower end 61 disposed approximate the bottom wall 174 of the bottle 108. A one-way inlet valve 62 is secured in the inlet opening 58 in a snap-fit and includes a resilient disc 63 that engages the radially inwardly directed inner surface of the wall to permit fluid flow axially outwardly therepast yet to prevent fluid flow axially inwardly therepast as in a manner, for example, described in a similar one-way inlet valve in U.S. Pat. No. 5,676,277 to Ophardt issued Oct. 14, 1997, the disclosure of which is incorporated herein by reference. The fluid chamber 54 is open at its axially outer end 56 into an inner end 371 of an air chamber 50.
The air chamber 50 is defined between its axially inner end 371 and its axially outer end 372 by the tubular outer portion 327 of the wall which is circular in cross-section, substantially cylindrical and has a diameter larger than the diameter of the tubular inner portion 328 forming the fluid chamber 54. The air chamber 50 is open axially outwardly at its axially outer end 372. The air chamber 50 includes an annular portion 374 annularly between the tubular outer portion 327 of the wall and the outer tube member 338 of the exit tube member 324 which annular portion 374 is open radially inwardly through the guide slots 36 in the support member 330 into the axially inner end of the central exit tube member 324 and notably the open axially inner end 375 of the inner tube member 340.
The collar member 322 has a side wall 376 disposed coaxially about the axis 20 with a tubular outer portion 377 carrying at its axially outer end 378 a radially outwardly extending outer shoulder flange 379 merging into an outer collar tube 26 having a threaded radially inwardly directed surface 27 carrying threads for engagement with complementary threads on the threaded neck 171 of the bottle 108. As can be seen in
The tubular outer portion 377 of the side wall 376 of the collar member 322 carries at its axially inner end 382 a radially inwardly extending inner shoulder flange 383 merging into an open inner tube 384. The collar member 322 has on its shoulder flange 383 an axially outwardly extending coupling tube 385 that extends axially outwardly to a distal end 386.
An axially inwardly opening annular socket 387 is defined in the shoulder 329 of the chamber member 323 adapted to receive the axially outwardly extending coupling tube 385 on the chamber member 323 so as to fixedly secure together in a snap-fit the collar member 322 and the chamber member 323 coaxial about the axis 20.
A one-way air inlet valve 388 is provided on the inner shoulder flange 383 of the collar member 322 including an axially inwardly extending air inlet tube 389 open at one end 390 axially inwardly and open at an axially outer end 391 into an air inlet port 392 through the shoulder 329 of the chamber member 323. A resilient disc member 394 is secured within the air inlet tube 389 engaged therein to permit flow axially inwardly therethrough but to prevent flow axially outwardly therethrough.
As in the first embodiment, in the second embodiment, as seen on
The outer tubular member 22 is formed by the outer tubular portion 327 of the chamber member 323 and the tubular outer portion 377 of the collar member 322. The inner tubular member 24 is formed by the tubular inner portion 328 and the slotted support member 330 of the chamber member 323 and the exit tube member 324. The annular flange 25 is formed by the shoulder 329 of the chamber member 323 and the shoulder flange 379 of the collar member 322.
Guide slots 36 are provided through the inner tubular member 24 as the guide slots 36 of the slotted support member 330.
Atmospheric air is permitted to flow into the bottle 108 via the one-way air inlet valve 388 when a vacuum created in the bottle 108 overcomes the bias of the disc member 392. The air inlet port 382 is in communication with atmospheric air via vent channels 393 axially between the collar member 322 and the chamber member 323 that permits atmospheric air to flow to inside the bottle 108 to relieve vacuum created by discharged liquid.
Reference is made to
The piston-forming element 14 is generally coaxially about the axis 20.
The central piston portion 401 of the piston-forming element 14 includes a central axially extending inner stem 64 with a passageway 67 therethrough closed at an axially inner end 68 and open at an axially outer end 69. The central piston portion 401 carries a reduced diameter axially innermost fluid piston portion 79 which is adapted to be coaxially received within the fluid chamber 54 to form a liquid pump 78. The fluid piston portion 79 includes a resilient axially inner disc 80 that engages the tubular inner portion 328 of the wall 30 in the fluid chamber 54 to permit fluid flow axially outwardly therepast but to prevent fluid flow axially inwardly therepast. The fluid piston portion 79 includes an axially outer disc 81 that engages the wall 30 in the fluid chamber 54 to prevent fluid flow axially therepast. Liquid ports 82 located on the inner stem 64 between the outer disc 81 and the inner disc 80 extend coaxially through the stem 64 into the passageway 67. With reciprocal coaxial movement of the central piston portion 401 relative to the chamber member 323, the fluid is drawn upwardly from the bottle 108 though the dip tube 52 past the one-way inlet valve 62 into the fluid chamber 54 in a retraction stroke and in an opposite extension stroke, the fluid is discharged axially outwardly past the inner disc 80 into an annular space 83 radially outward of the inner stem 64 and radially inward of the wall 30 and between the inner disc 80 and the outer disc 81 and hence via the liquid ports 82 radially through the inner stem 64 into the passageway 67 leading to its axially outer end 69. The operation of the liquid pump 78 is substantially the same as described in U.S. Pat. No. 5,676,277 to Ophardt referenced above. However, many other configurations of a piston pump may be adopted for the liquid pump 78 without departing from the present invention.
In the liquid pump 78, there is defined between the outer disc 81 and the one-way inlet valve 62, a liquid compartment 85 with a volume that varies with the axial position of the central piston portion 401 within the fluid chamber 54.
Axially outwardly on the inner stem 64 from the outer disc 81, transfer ports 84 are provided radially through the inner stem 64 into the passageway 67. Axially outwardly from the transfer ports 84, a radially extending bridge flange member 71 extends radially outwardly. As best seen on
With the piston-forming element 14 engaged on the piston chamber-forming body 12, as seen in
As best seen on
An annular axially inner air disc 91 extends radially outwardly from the outer stem 430. The inner air disc 91 at its radially outer end carries a pair of resilient disc arms 92 and 93.
The axially outer end 433 of the outer portion 436 of the outer stem 430 is open axially outwardly as a central socket 444 with a snap groove 445.
The annular end member 403 has an annular tubular wall 446 defining a central passageway 447 axially therethrough from an axially inner end 448 to an axially outer end 449. At the outer end 449, an engagement flange 16 extends radially outwardly from the tubular wall 446 in the form of a circular disc 73 carrying a plurality of circumferentially spaced resilient finger members 74, each connected to the disc 73 at a first end 75 and extending radially outwardly and axially inwardly to a distal end 76. Adjacent finger members 74 are circumferentially spaced by radially and axially extending slots 77 through the disc 73.
The tubular wall 446 is engaged within the central socket 444 against removal with a radial stop flange 454 on a radially outwardly directed surface of the tubular wall 446 engaged in the slide groove 445 in the outer portion 436 to fixedly couple the annular end member 403 to the outer piston portion 402 yet permit limited relative coaxial sliding to create a drawback effect.
An annular axially outer air disc 94 is provided on the annular end member 403 extending radially inwardly into the central passageway 447 from a radially inwardly directed surface 457 of the annular tubular wall 446. The outer air disc 94 carries a resilient disc arm 95.
With the piston-forming element 14 engaged on the piston chamber-forming body 12 as seen in
(a) the inner air disc 91 extends radially outwardly with its disc arms 92 and 93 engaging the inner surface of the tubular outer portion 327 of the side wall of the chamber member 323 inside the air chamber 50 to provide a seal preventing flow axially inwardly and outwardly therepast; and
(b) the outer air disc 94 extends radially inwardly with its disc arm 95 engaging a radially outwardly directed surface of the outer tube member 338 of the exit tube member 324 to provide a seal preventing flow axially outwardly therepast and resisting flow axially inwardly.
The engagement flange 16 is to be coupled and uncoupled with the actuator plate 140 on the dispenser housing 104 and is provided at an axial location on the piston chamber-forming body 12 axially outwardly of the piston chamber-forming body 12, such that the engagement member 16 can be engaged with and disengaged from the actuator plate 140 by relative radial movement.
As in the first embodiment, in the second embodiment, as seen in
An air compartment 97 is defined between the inner stem 64, the outer stem 330 and the side wall of the chamber member 323 between the outer air disc 94, inner air disc 91 and the outer disc 81. The air compartment 97 includes an outer annular portion 98 and an inner annular portion 99 in communication with each other via the guide slots 36. The outer annular portion 98 is defined within the air chamber 50 axially inwardly and radially inwardly of the annular sealing member 70. The inner annular portion 99 is defined within the central passage 32 of the inner tubular member 24 radially outwardly of the inner stem 64 and axially outwardly of the fluid piston portion 79, that is, axially outwardly of the outer disc 81. The air compartment 97 has a volume that varies with the axial position of the piston-forming element 14 within the piston chamber-forming body 12 whereby an air pump 96 is formed. In a retraction stroke, the volume of the air compartment 97 decreases forcing air (a) through the transfer ports 84 into the passageway 67 and/or (b) through the annular opening 88 annularly about the axially outer end 66 of the inner stem 64 and the inner tube member 340 of the exit tube member 424 simultaneously with the discharge of the liquid from the pump liquid 78 into the passageway 67 for simultaneous discharge of air and liquid through the foam generator 44 to produce a foamed air and liquid that flows through the delivery tube 112 and out the discharge outlet 114. In a withdrawal stroke, the volume of the air compartment 97 increases drawing into the air compartment 97 foam, air or liquid within the passageway 67 and the delivery tube 112 as well as atmospheric air through the discharge outlet 114.
As can best be seen in
The pump assembly 10 illustrated in the preferred embodiments provide for the simultaneous dispensing of air and liquid through a foam generator 44 to produce a foam product. The configurations of the pump assembly 10 is, however, also suitable for simultaneous dispensing of air and liquid as a spray or mist in which case the foam generator 44 would not be provided and a suitable nozzle for producing a desired spray of the air and the liquid would be provided preferably proximate the discharge outlet 114.
In each of the liquid pump 78 and air pump 96 shown, discharge is provided in a retraction stroke. The particular nature of the piston pumps illustrated by the liquid pumps 78 and the air pumps 96 may, however, be substituted by other constructions for liquid pumps and air piston pumps which may, for example, discharge fluid in a withdrawal stroke. However, it is to be appreciated that provision of the inner tubular member 24 and the exit tube member 324 as a fixed component of the piston chamber-forming body 12 can be adopted for various arrangements in which the piston-forming element 14 is to relatively slide axially relative to the piston chamber-forming body 12.
The preferred embodiments of the liquid pump 78 provide a separate one-way inlet valve 62. By the use, for example, of configurations of stepped chambers, a liquid piston pump can be provided without the need for a separate one-way valve.
In accordance with the present invention, the pump assembly 10 provides for simultaneous discharge of air and liquid in which the liquid pump 78 and the air pump 96 operate in sequence, that is, dispensing simultaneously in a retraction stroke. It is to be appreciated that various liquid pumps and air pumps may be utilized in which the liquid pump is out of phase with the air pump in the sense of the liquid pump discharges liquid into the air compartment during one stroke and the air pump discharges air and the liquid received from the liquid pump in an opposite stroke.
The preferred embodiments illustrates a pump assembly 10 in which each of the components forming the pump assembly are preferably formed as by injection molding from plastic materials and to provide for ease of manufacture from a minimal number of components. In
In accordance with the preferred embodiments, the pump assembly 10 is adapted for use in a dispenser assembly in which the liquid is dispensed upwardly from the bottle. This is not necessary and, in accordance with the present invention, pump assemblies could be developed which utilize similar arrangements for providing the inner tubular member 24 or the exit tube member 324 as a fixed component of the piston chamber-forming body 12 yet permit dispensing of the fluid downwardly or in other orientations such as horizontally.
While the invention has been described with reference to preferred embodiments, many modifications and variations will now occur to persons skilled in the art. For definition of the invention, reference is made to the follow claims.
Number | Date | Country | Kind |
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2942640 | Sep 2016 | CA | national |
This application is a continuation of co-pending U.S. patent application Ser. No. 15/709,731 filed Sep. 20, 2017 and claims the benefit of 35 U.S.C. 120.
Number | Name | Date | Kind |
---|---|---|---|
5445288 | Banks | Jan 1995 | A |
5431309 | Ophardt | Jul 1995 | A |
5676277 | Ophardt | Oct 1997 | A |
5918771 | van der Heijden | Jul 1999 | A |
6142342 | Lewis | Nov 2000 | A |
6929150 | Muderlak et al. | Aug 2005 | B2 |
7364053 | Ophardt | Apr 2008 | B2 |
8071933 | Ophardt et al. | Dec 2011 | B2 |
8113388 | Ophardt et al. | Feb 2012 | B2 |
8201707 | Ophardt | Jun 2012 | B2 |
8245877 | Ophardt | Aug 2012 | B2 |
10144020 | Ophardt | Dec 2018 | B2 |
20080304978 | Ophardt et al. | Dec 2008 | A1 |
20090166381 | Phelps et al. | Jul 2009 | A1 |
20100140300 | Lewis | Jun 2010 | A1 |
20150320266 | Creaghan | Nov 2015 | A1 |
Number | Date | Country | |
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20190054485 A1 | Feb 2019 | US |
Number | Date | Country | |
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Parent | 15709731 | Sep 2017 | US |
Child | 16167688 | US |