CA1063985A - Outlet check valve for fluid dispenser - Google Patents

Abstract

ABSTRACT The present invention relates to dispensing apparatus for discharging fluid from a nozzle, the apparatus including a housing having a variable volume chamber therein and an outlet check valve for controlling fluid communication between the chamber and the nozzle. The check valve includes an elastic valve member having a rearwardly extending portion thereon which is provided with an integral sealing means. The sealing means forms a seal between the nozzle and the housing, and a solid central portion is movable responsive to pressure within the variable volume chamber. The nozzle includes means for varying the degree of contact between the solid central portion of the elastic valve member and the nozzle to thereby vary the spray discharge pattern of the dispenser.

Description

1~)6;~ r~v Back~roun(I_of the Invention ~ erosol (lispensers ~idely used in the packaging indu~try pLesent two major problems: atmospheric pollution from the propellant and d~sposal of the cannister without the risk of explosion and the accompanying hazard to personal safety. The use of hand actuated pump dispensers as a substitute for aerosol dispensers obviates these problems but is not practical in many circumstances because conventional pump dispensers are difficult to ship and expensive to construct. Accordingly, it ls a pr~mary 10 ob~ect of the present invention to provide a novel fluid dispenser which is inexpensively fabricsted and easily shipped.
Typically, fluid dispensers are attached to fluid con-tainers prior to shipping. ~n order for fluid to be withdrawn from the container, a venting passage from the atmosphere to the interior of the container must be provided. However, unless the dispenser or container is provided with means fo~ sealing the venting passage, fluid often leaks from the container during shipping. One known approach to this problem is a vent seal which may be disabled by tightening a cap over the nozzle. By way of 20 example, this approach is illustrated in the Powers U.S. Patent No. 3,780,951~ dated Decembes 25, 1973. Another known approach to the problem is the provision o~ a releasable locking pin to ~aintain the piston in a position which blocks the vent. In this approach, the pin must be manually released before the trigger can be operated. This approàch is illustrated, e.g., in the Hellenkamp U.S. Patent No. 3,840,157, dated October 8, 1974. These conventional seals and locking structures may be difficult for the consumer to operate, generally requiring the production of explanatory literature, and often entail considerable additional ~ '' dap/ ~ `-" ~

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pro~uc~ion expcnse duc to the necessity of produclng additional parts and of per~ormlng add~tional manufacturing steps in the fabrication of the structure. It is accordingly, an ob~ect of the present invention to provide a novel fluid dispenser with an easily and inexpensively ~abricated vent shipping seal which does not require explanatory literature and ~hich may be released by actuation of the dispenser trigger.
Because of the expense associated with the assembly, it is desirable that the number of separately molded parts of a fluld dispenser be minimized. It is, accordingly, an ob~ect of the present invention to provide a novel pump dispenser with an integral container conduit and vent shipping seal, an integral piston and inlet check valve seat, andlor an integral piston seal and inlet check valve member.
The operation of the trigger and its retention in the dispenser housing is often a problem and it is yet another ob~ect of the present invention to provide a novel pump dispenser in which the length of the piston stroke is utilized to retain the trigger operably connected to the housing. In the preferred embodiment, this is accomplished by directly connecting the piston with an actuating arm of the dispenser trigger to thereby limit the arc through which the trigger may pivot.
Fluid pump dispensers are generally provided with a nozzle structure including a check valve for blocking communication between the pump chamber and a nozzle aperture. A nozzle structure of this type is illustrated, e.g., in the Vanier U.S. Patent No.
3,685,739, dated August 22, 1972. It is desirable that the nozzle structure be ad~ustable to provide widely varying discharge patterns and for disabling the outlet check valve. A seal must dap~

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-also be provi~ed to prevellt ~luLd leakage at the sliding interface of the noY~le str~1c~ure adjustment means. It is, of course, alRo desirable that the number of separately molded parts of the fluld dispenser be minimized. Accordingly, it is an ob~ect of the present invention to provide a novel fluid dispenser having an adjustable nozzle for varying the discharge pattern of the dis-penser, comprising only two separately molded parts attached to the dispenser housing.
It is desirable that a fluid dispenser have a large, protruding, and easily grasped trigger defining a long lever arm for actuating the dispenser pump. Dispensers having such easily grasped triggers are often difficult to economically and safely package for shipping. It is an ob~ect of the present invention to obviate such shipping problems by providing a novel dispenser having a large, easily operated trigger which may be conveniently and easily attached to the dispenser housing after delivery of the dispenser.
The triggers of many conventional fluid dispensers are attached to the dispenser housing with rivets or pins. This method generally requires the fabricating of additional parts and the performing of additional production steps to insert the pin or rivet. An example of this type of trigger connection is illustrated in the Hellenkamp U.S. Patent ~o. 3,840,157.
In another known method of assembly, the trigger is attached to the dispenser housing by outwardly flexing the lateral walls of the dispenser housing to permit the engagement of mating surfaces on the trigger and housing. This method of assembly has a disadvantage in that f].exure may damage the relatively fragile dispenser mechanism or the housing by exceeding the limit of dap/ ~

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~ 06~ti eLastic deformation. ~ccordingly, lt is an object of the present invention to avoid the expense of rivet attachment and ~he danger of housing dan~age b~ providing a novel, r~vetless fluid dispenser trigger which may be pivotably attached in the dispenser housing without lateral flexing of the housing.
Typically? fluid is discharged $ro~ a spray dispenser by reducing the volume of a pump chamber, thereby opening a pressure responsive outlct check valve. In conventional spray dispensers the volume of the pump chamber m~y be varied by operating a piston, as illustrated in the Hellenk~mp U,S. Patent No, 3~840~157~ or the volume of the pump ch~mber may be varied by flexlng a wall of a flexible tubular member, ha~ing an Qutlet valve integral therewith, as illustrated in the Micallef U.S, Patent No, 3~749,2~0. Both dispense~s are configured in the approximate shspe of a pistol, the nozzle being located st the end of a forwsrdly protruding i~
portion of the housing and the pump chamber being located within the portion of the housing g~asped by the hsnd. While the Mlcallef dispenser has several ,inherent advantages ? the dlspenser hss a disadvsntage in that-the protFuding nozzle cap is provided separate snd displsced from the outlet valve of the dispenser, which is formed by interengaging surfaces of the flexible tubular member, thus restricting the sccessibllity of the outlet vslve for adjust-ment to modify the discharge psttern of the dispenser, Accordingly, it is a further object of the present invention to provide a spray dispenser having a pump chamber defined by a flexible tubulsr member, and a nozzle structure displaced from the pump chamber, hsvin~ an outlet chec~ vslve which cooperates with sn adjustsble nozzle cap to vary the discharge pattern of the dispenser.

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~r~le Drawings _ I:igure 1 is a pic~orial view of a fluid dispenser embodiment of the present invention having a fluid filter?
attached to a fluid container;
Figure 2 is a sectional view in elevation taken through the ma~or ~xis of one embodiment of the dispenser o~ the present ,~
invention;
Figure 3 is a pictorial view of the piston inlet conduit of the embodiment of Figure 1 illustrating the container vent passages;
Figure 4 is a pictorial view in partial section of an embodiment of the present invention illustrating a tri8ger assembly method;
Figure 5 is a section taken along lines 4-4 of Figure 2;
Figure 6 is a section taken along lines 5-5 of Figure 5;::
Figures 7-9 are sections of the nozzle structure of the embodiment of the present invention illustrated in Figure 2 showing the ad;ustment of the structure to vary the nozzle discharge pattern;
Figure 10 is a section taken along lines 9-9 of Figure 2;
Figure 11 ls a section taken along lines lQ-iO of Figure 10;
Figure 12 is a section taken along lines 11-11 of Figure `
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Figure 13 is a sectional view of an elevation of an ~ -alter~ate fluid dispenser embodiment with a flexible pumping chamber; , ..
Figure 14 is a pictorial view of an inlet conduit filter embodiment of the present invention.

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Figure 15 i8 a pictorial v~ew showing the filter embodi-ment of Figure 14 at~ached to an inlet dip tube of a dispenser;
Figure 16 is a cross-sectional view of a one-piece molded member for providing a fluid filter according to an embodiment of the present invention; and Figure 17 is a plan view of the molded member of Figure 3.
Detailed Description To facilitate an understanding of the methods and t0 structures of the present invention, reference may be had to the following:
TABLE OF CONTENTS
A. Fluid Dispenser Structure B. Method of Assembling and Venting C. Operation of the Fluid Supply and Discharge Assistant D. Operation of the Nozzle Structure E. Nozzle Structure and Flexible Pump Chamber F. One~Piece Fluid Filter A. Fluid Dispenser Structure Referring first to Figure 1, a fluid dispenser 10 is shown threadably attached to a fluid container 11. By actuating trigger 12, fluid from the reservoir 13 may be drawn through a one-piece molded filter 14 into the fluid dispenser body 15 via dip tube 16. The fluid may then be e~ected through an ad~ustable nozzle 17. The fluid dispenser body lS is described in greater detail in connection with Figure 2.
With reference to Figure 2, a fluid dispenser includes a housing 22 adapted for mounting on the threaded orifice of a dap/ ~ ~

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fluid container (not shown). A pump chamber 24 is d~sposed within the housing 22. A fluid supply and discharge assistant 26 includes a piston 27 and a conduit 28 which provides fluid to the pump chamber 24 from the container. The piston conduit 28 may be provided with an inlet conduit 30 adapted to extend into the container to draw fluid into the pump chamber 24 via the piston conduit 28 and an inlet check valve 32. The piston 27 may be actuated against the bias of a coil spring 40 by squee~ing trigger 36 thereby reducing the enclosed volume 38 of the pump chamber 24.
A flexible member 42 in contact with the piston 27 functions as the movable portion of the inlet check valve 32 and as a piston ring. Alternatively, the flexible member may be formed integral with the piston 27. The flexible member 42 may include a central portion 44 adapted to contact a valve seat 46 integral with the piston to block a piston conduit orifice 47 and thereby block communication between the container and the pump chamber in response to the pressure within the pump chamber. The central portion 44 of the flexible member 42 may be frustoconical in shape to facilitate sealing engagement with the valve seat 46. In an alternate embodiment, the piston conduit may be blocked in response to pressure within the pump chamber by a ball check valve (not shown).
The flexible member may further comprise an annular portion 48 contacting the piston and the coil spring 40. A
plurality of radially oriented, arch-shaped bands 50 of a thinner cross-section than the central portion may be used to connect the central portion to the annular portion and permit relative movement .-therebetween. A radial edge 52 of the flexible member 42 may form a fluid tight seal between the piston 27 and the inner wall of the dap/, ,' '' , -pump chamber 24.
As sllown in ~he section illustrated in Figure 5, the various portions of the flexible member described above have concentric relationships. The central portion 260 of the flexible member is attached to the piston engaging annular portion 262 of the flexible member by a plurality of the arch-shaped bands 264. Apertures 266 ln the flexi~le member lie between the bands 264 and a peripheral edge 268 of the flexible member is adapted to contact the inner wall of the pump chamber. Reference may also be had to Figure 6~ where the features of the flexible member of Figure 5 are illustrated.
Referring once more to the dispenser illustrated in Figure 1 and more particularly to the vent shipping seal, the piston conduit 28 may pass through an aperture in the container closure 70. T-he outer wall 72 of the conduit 28 and the inner wall 74 of the aperture of the container closure may define a container venting passage formed by axial indentations in either the conduit wall 72 or the wall of the closure 74. A venting passage may also be provided by a loose fit between the piston conduit and the container closure aperture. Mating surface 76 of the piston conduit and mating surface 78 of the container closure may be provided to block the venting passages when the mating surfaces are engaged.
A preferred embodiment of the vent shipping seal is illustrated with reference to Pigure 3. In Figure 3, a pisto~
conduit or inlet conduit of a spray dispenser 80 contains indentations or grooves 82 in the outer wall of the conduit 80 to define, together with the surface of the inner wall of the container closure, venting passages for the container. A raised ring 84 dap/~;~f'~J

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axially ~isplaced from the upper end~ 86 of tlle indentations 82 may be operative to block the venting passages when engaged with the surface of a groove in the inner wall of the aperture of the container closure. The mating surface 84 depicted in Flgure 3 as a raised ring may alternatively be configured as a groove so long as the desired seal is obtained.
With continued reference to Figure,2, the trigger 36 of the dispenser has a spiral-shaped member 92 which pivots on an inwardly pro~ecting peg 94 on opposite sides of the dispenser lO housing. It may be noted that single or plural spiral-shaped members may be formed in either the housing or the trigger and single or plural pegs may be formed in the other of the housing and trigger.
The housing of the dispenser may include a separate housing head portion 96. The housing head portion 96 may be formed with a downwardly depending ear 98 for engaging the spiral-shaped member 92. A curved surface 100 of the ear 98 may slidably engage a portion 102 of the spiral-shaped member to prevent the spiral-shaped member from disengaging the pegs 94.
An arm 95 of the trigger is adapted to mate with the piston and piston conduit thereby limiting the arc through which the trigger may pivot to the length of the piston stroke. Fluid in the pump chamber 38 may be discharged from the dispenser through an outlet conduit 104 and a nozzle structure 106. The nozzlo structure 106 may include a valve seat 108 communicating with the outlet conduit 104 and a nozzle cap llO having an aperture 112 through which the fluid is discharged. An outlet check valve 114 includes flexible member 116 and the valve seat 108. A
movable ,central portion 118 of the flexible member 116 may contact dap/

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that valve seat 108 Lo block communication betwecn the aperture 112 and thc pump chamber 38 responsive to pressure within the pump chamber 38.
The central portion 118 of the flexible member may be frustoconical in shape with the central portion 118 surrounded by an annular portion 120 having apertures 121 to provide a fluid flow path when the central portion is not seated on the valve seat. An integral 0-ring 122 is provided by the peripheral portion of the flexible member 114 to orm a seal between the nozzle cap 110 and the housing 124 surrounding the outlet conduit.
The housing 124 and the nozzle cap 110 may be provided with threads 126. Rotation of the nozzle cap 110 with respect to the housing 124 may be operative to ad~ust the pressural contact between the inner central surface 128 of the nozæle cap and the central portion of the flexible member 118. Either the central portion of the flexible member 114 or the inner central portion of the nozzle cap 128 may be formed with bosses 129 for contacting the other of the cap or flexible member. The bosses may be operative to deflect the flow of fluid ad~acent the bosses. Adjustmént of the nozzle cap may vary the contact between the central portion of the flexible member and the bosses when the outlet check valve is open, thereby varying the discharge pattern of the dispenser.
As shown in Figure 10, the flexible member 116 of Figure

2 has a central, frustoconical portion 340 surrounded by an apertured annular region 342. The apertures 344 provide fluid flow passages between the outlet conduit and the aperture in the nozzle cap when the check valve is open. The 0-ring portion (not shown) of the flexible member is attached to the peripheral edge 346 of the apertured annular portion 342 of the flexible member.

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1 ~)6;~f Jl ~ s sllown more ~learly in Figure 11, the frusto~onical portion 350 of the flexiblc member is connected to the integral 0-ring 352 by the apertured annu~ar portion 354. The portion 354 may be thinner in cross-sectlon than the central portion lS0 to permi~ relative movement of the central portion 150 with respect to the 0-ring 152. Apertures 356 in the annular portion 354 may provide fluid flow passages through the member.
Figure 12 is a cross-sectional view taken along lines 11-11 of Figure 2. As shown in Figure 12, ~he nozzle cap 36n includes an aperture 362 formed in the central circular well 364 of the nozzle cap. Bosses 366 may be formed on the central inner surface of the nozzle cap and, the bosses may be of different heights. In one embodiment of the invention, ad~acent bosses may be of alternate heights, e.g., boss 380 of Figure 12 may be of one height while boss 382 is of a different height.
B. Dispenser Assembly and Venting~
The assembly and venting of the fluid dispenser of Figure 2 may be understood more readily by reference to Figure 4 where a fluid dispenser 200 is illustrated as including a trigger 202 pivotably engaging the housing 204. This engagement may be accomplished by interengaging the spiral member 206 on the trigger with a peg 208 on the housing so that the center of the peg is located in the interior space defined by the spiral between line 207 and the tightly curved portion of the spiral 209. Advantàge-ously, the peg may be located at the center 210 of the shortest radius of the spiral. At the same time an arm 212 of the trigger may be mated with the discharge assistànt 214 (shown in phanton).
The head portion 216 of the housing 204 may then be positioned so that the curved surfaces 218 of the downwardly depending ear 220 dap/
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of the housing hcad may sLidably cont~ct a portion o~ the spiral-shaped member 206 to prevent the spiral-shaped member from dls-engaging the peg 208.
Once the trigger 202 is pivotably mounted to the housing, the container (not shown) may be vented by squeezing the trigger toward the central portion of the housing 204 to cause upward motlon of the discharge assistant 214. This upward motion may cause the radially outward flexing of mating surface 222 from the mating surface 224 thereby causing the surfaces to disengage and move axially with respect to one another to open venting passages 226. This permits air to enter the container to displace fluid removed by the pumping action of the dispenser.
C. Fluid Supply and Dischar~e Assistant Operation The operation of the pumping mechanism of the fluid dispenser may be more easily understood with reference to Figure 2 where it can be seen that the initial squeezing of the trigger 36 toward the central portion of the dispenser operates to dis-engage the vent seal as described above~and to reduce the enclosed volume of the pump chamber 38 to discharge air via the outlet conduit 104, the valve seat 108, the flexible member apertures 121 and the nozzle cap aperture 112. When the trigger 36 is released, the coil spring 40 urges the piston 34 downwardly to increase the enclosed volume of the pump chamber and thus reduce the pressure therein. This reduction in pressure in the pump chamber may cause the central portion 118 of the flexible member 116 to seat on the valve seat 108 to close the outlet check valve. This reduction in pressure in the pump chamber may likewise cause the central portion 44 of the flexible member 32 to unseat from valve seat 46 to open the inlet check valve and cause fluid to be drawn from the dap/

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contalner into the pump ch~mber via the inlet conduit 30, the piston in].et conduit 28, the piston conduit orlfice 47 and the apertures in the flexible member 32. Air may enter the container along vent passages 72 to compensate pressuraly for the withdrawal of fluid from the container.
Further squeezing of the trig~er 36 may be operative to drive the piston upwardly once more to reduce the enclosed volume of the pump chamber 38. This reduction in volume discharges fluid from the pump chamber via the outlet conduit 104, the check valve 114, the apertures 121 and the nozzle cap aperture 112. This increased pressure in the pump chamber is also operative to open the inlet check valve 114 by unseating the central portion 118 of the flexible member 116 from valve seat 108. A series of fluid discharges from the dispenser may be obtained by the alternate squeezing and releasing of the trigger.
D. Nozzle Structure Operation The operation of the spray dispenser nozzle structure may be understood with reference to Figures 7 through 9. As shown in Figure 7, fluid may be supplied to the nozzle structure 300 via a conduit 302. An orifice 304 of the conduit 302 forms a valve seat 303 for an outlet check valve 306, and a frustoconical shaped central portion 308 o-f the flexible member 310 may be utilized to block the orifice 304 in response to pressure within the conduit 302. If the pressure in the conduit 302 is less than the ambient pressure about the nozzle structure, the central portion 308 of the flexible member may be seated on the valve seat 303 as shown in Figure 7. When the pressure in the conduit exceeds the ambient pressure the central portion 308 of the flexible member may be unseated from the valve seat 303 as shown in Figure 8 and Figure 9 dap/ ~', .

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where like features of F-i~ure 7 arc identified with like numbers.
With rcerence to Figures 7, 8 and 9, a nozzle cap 312 may be provided ~or threa~ed engagement with the portion 314 of the dispenser defining conduit 302 and may be formed with an aperture 316 through which fluid is discharged from the dispenser.
The nozzle cap engages an 0-ring portion 318 of the flexible member to retain the periphery of the flexible member in a fixed position with respect to the valve seat 303 and to provide a fluid tight seal between the nozzle cap and the conduit defining portion 314 of the dispenser. Rotation of the nozzle cap 312 along the path defined by the threads 320 may vary the distance and/or pressural contact between the central portion of the flexible member and the inner central surface 322 of the nozzle cap. Bosses 324 may be formed in either the inner central surface 322 of the nozzle cap or the central portion 308 of the flexible member to deflect fluid flow. Alternatively, fluid directing recesses may be formed in either the inner central surface 322 of the nozzle cap or the central portion 308 of the flexible member to direct fluid flow.
As shown in Figure 8 and Figure 9, fluid pressure in the conduit 302 may unseat the central portion 308 of the flexible member from the valve seat 303 and be discharged from the aperture 316 via the orifice 304 and the apertures 326 in the flexible member. When the cap is positioned with respect to the flexible member as shown in Figure 8, the discharged fluid must pass between bosses 324 before it is discharged through aperture 316, and, therefore, is swirled. The resultant discharge pattern may be a spray dispensed over a relatively wide area. When the nozzle cap is positioned with respect to the flexible member as shown in dap/ "

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Figure 9, the flllid may pass from apertures 326 in the flexible member through aperture 316 in the nozzle cap without passing between the bosses 324, and is not swirled by the bosses. The resultant discharge pattern may, therefore, be in the form of a stream.
Where bosses of varying heights are provided the dlscharge pattern of the sprayer may be varied by selectively ad~usting the nozzle cap to selectively cause contact between the flexible member and some or all of the bosses when the outlet check valve opens.
E. Nozzle Structure and Flexible Pump Chamber Alternatively, the nozzle structure described in connec-tion with Figures 7-12 may be employed in a fluid dispenser having a flexible pump chamber, as shown in Figure 13.
With reference to Figure 13, a fluid dispenser may include a housing 384 adapted for mounting on the threaded orifice of a fluid container (not shown). A variable volume pump chamber 385 may be located within the housing 384. The pump chamber may be partially defined by a flexible tubular member 386 having an open axial end 387 in communication with nozzle structure 388 of the type described in connnection with Figures 7-12. Fluid may be supplied to the variable volume pump chamber 385 via an inlet conduit 389 and an inlet check valve 390. The dispenser may be actuated by pivoting a trigger 391 to press an arm 392 of the trigger against a portion of the wall of the flexible tubulari member 386, thereby reducing the enclosed volume of the pump chamber 385. When the trigger is released the elastic bias o~ the tubular member may tend to return the member 386 to its distended position (shown in phantom).

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Tlle llpper axiaL cnd 387 of the flexible tubular member 386 may communicate witll the outlet check valve of the nozzle structure 388 via outlet conduit 393. A cylindrical chamber 394 in the housing 384 may cooperate with the flexible member to define the pump chamber and conduit fluid discharged from the hollow of tlle flexible tubular member to the outlet conduit 393. The flexible tubular member may be sealably positioned with respect to the cylindrical chamber by means of a flange formed in an upper portion of the wall of the tubular member which engages a corresponding indentation in the housing 384.
The trigger 391 may be mounted to the hQusing 384 for pivoting about axis perpendicular to the plane of the Figure. The arm 392 of the trigger 391 may be pivotably mounted to the trigger and pass substantially horizontally through an aperture in the housing. The arm 218 may be molded integrally with the trigger 391 and have a narrowed portion joining the arm thereto, to permit pivoting of the arm with respect to the trigger.
In operation, the spray dispenser of Figure 13 may be disposed on a fluid container and the trigger 391 squeezed and released to prime the dispenser. The release of the trigger permits the flexible tubular member to return to its distended position, thereby reducing the pressure in the pump chamber?
closing the outlet check valve in the nozzle structure 388, and drawing fluid into the pump chamber 385 via the inlet conduit 389 and the inlet check valve 390, If the trigger is again squeezed, the volume of the pump chamber 395 is reduced, thereby pressuring the pump chamber, closing the inlet check v~lve 390 and opening the outlet check valve in the nozzle structure 388. Fluid in the pump chamber may be discharged through the aperture of the nozzle structure via the chamber 385, outlet conduit 393? and the outlet dap/ ;/~

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check valve ~nd apertures of the no~7.1e structure 388.
F. One-Piece Fluid Filtcr Referring now to Figure 14, a dlp tube filter embodiment of the present invention is shown. The filter may include two generally circular plates 412 and 414. The plate 412 may also be annular in shape, and have radially extending ribs 416 formed in a surface thereof. A tubular hub portion 418 may extend coaxially from the annular plate 412. The hollow of the tubular portion 418 (not shown) may communicate with the central opening (not shown) of the annular plate 412. The plates 412 and 414 may be connected along portions of their circumferences by an integral hinge 420. The plates 412 and 414 may be pivoted ~ith respect to one another about an axis 422, defined by the hinge, to expose the ribs 416 for cleaning.
Figure 15 is a pictorial view of a fil~ered fluid supply embodiment 430 of the present invention attached to a conventional fluid dispenser 432. The filtered fluid supply apparatus may include a fluid container 434 with a bottom wall 436 a~d a mouth 438 for threaded attachment to the fluid dispenser 432. An inlet dip tube 440, providing fluid communication between the dispenser 432 and the container 434, may extend from the mouth 438 of the container toward the bottom wall 436 of the container. A fluid filter 442 may be attached to an end portion of the dip tube 440.
The filter 442 may include a collar portion 444 having a tubular portion 446 for engaging the dip tube 440 and a first generally circular plate 448. A second generally circular plate, selectively positionable ad~acent to the first circular plate may be hingedly connected by means of hinge portion 452 to the first circular plate. At least one of the first and second plates may be formed ~ 18 -dap/

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- ' ': ' '' . ' . ,' ' ., , ~.()6;~ 3 wlth radially ext~nding ribs 454 for providing a plurality of ~luid passages be~ween the plates in commun~cation with said tubular portion 446 and the dip tube 440. T~e second plate may be located ad~acent and parallel to the bottom wall 436 of the fluid container.
In operation, a molded member having the above described portions 446, 448, 450 and 452 is provided. The tubular portion 446 may be grippingly engaged to the dip tube 440; the inner surface of the tubular portion 446 frictionally contacting the outer wall of the dip tube 440. The second circular plate 450 may be pivoted with respect to the first circular plate 448 about the hinge portion 452 to locate the second circular plate coaxially ad~acent to the first circular plate. When so positioned the rib~
on the one of the circular plates cooperate to define fluid passages between the circular plates. The dispenser dip tube and filter may then be threadably engaged to the container 430 and the filter emersed in a fluid 456 within the container. The dispenser 432 may be actuated to draw fluid through the filter and into the dispenser via the tubular portion 446 and the dip tube 440. Fluid drawn into the dip tube 440 must first pass between the ribs 454 of the filter. It will be understood that solid material suspended in the fluid 456 will be prevented from entering the dip tube by the ribs 454.
The ribs 454 may extend radially inwardly from the circumference of the circular plates 448 and 450 and, thus the area for filtering may be maximized. The second circular plate 450 may be located adjacent and parallel to the bottom wall 436 of the container 434. In this configuration, virtually all of the fluid 456 may be withdrawn from the container 434 through the filter, before the fluid level falls below the level of the passages - ' -- 19 -- , dap~

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between the ribs.
Figure 16 is a cross-sectional view of a one piece molded mem~er 460 for providing a fluid filter according to an embodiment of the present lnvention. The member may include an annular plate portion 462 having a central openlng 464. A tubular portion 466 may extend axially from the annular plate portion, a hollow 468 of the tubular portion communicating with the central opening 464 ln the annular pate portion. A generally circular plate portion 470 may be hingedly connected to the annular plate portion 462 by a hinge portion 472 of`relatively thinner cross-section than either of the plate portions. Members 474, axially extending from the circular plate portion may be adapted to pressurely engage the tubular portion 466 ~o maintain surfaces 476 and 478 of the plate portions coaxially ajdacent one another. At least one of the surfaces 476 and 478 may be formed with radially extending ribs, such as ribs 480. I~hen the surfaces 476 and 478 are located coaxailly adjacent to one another, the ribs provide a plurality of fluid passages between the plates which communicate with the hollow 468 of the tubular portion 460.
The tubular portion 466 may be formed with a first hollow portion 482 for receiving the members 474. Radial ends of the members 474 may pressurely engage the inner wall 484 of the tubular member. The tubular portion 466 may be formed with first and second inwardly extending flanges 486 and 488. When the dip tube is inserted into the hollow 4'68 of the tubular portion 466, the flange 486 limits the extent to which the dip tube may be inserted, The gripping flange 488 is adapted to frictionally engage the dip tube and inhibit separation of the filter from the dip tube.
Figure 17 is a plan view of the molded member 460 dap/~ t/~

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,' ' - ' described in connection wiLh Figure 16, ILke structures being identifled by the sa~e numerals employed in Figure 16. The molded member 460 include~ the annular sllaped plate 462 connected by the llinge portion 472 to tlle circular plnte portion 470. In the embodiment of Figures 16 and 17 the surface 478 of the plate 470 is a relatively smooth and the surface 476 of the plate 462 is formed with the ribs 480. The ribs 480 may extend radially lnwardly from a circumference 490 of the surface 476 to a radlus 492 inter-mediate the circumference and the central opening 464 in the asnular plate 461. In this way maximum filtering area is obtained along the circumference 490 of the plates~ while restriction of fluid flow is minimized.
` The members 474 for pressurely engaging the tubular portion may extend radially outwardly as shown in Figure 17.
Radial ends 494 of the members 474 are adapted to engage the inner wall of the tubular portion 466 (shown in Figure 16).
In operation the circular plates may be pivoted with respect to one another to coaxially align the plates and locate the surfaces 476 and 478 ad~acent one another, the members 474 engaging the tubular portion 466 to mainta~n the surfaces adjacent i one another. Solid material prevented from entering the dip tube by the ribs 480 may accumulate in the vicinity of the ribs. When this occurs the plates may be pivoted with respect to one another about the hinge portion 472 to expose the ribs to permit the solid material to be cleaned away.
The principals, preferred embodiments and modes of operation of the present invention have been described in the fore-going specification. The invention which is intended to be protected is not, however, to be construed as limited to the , - 21 - .
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particular forms disclosed, since these are to be regarded as illustratlve rather than restrlctlve. Variatlons and changes may be made by those skilled in the art without departing from the spirit and scope of the present invention.

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Claims (5)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. In a dispensing apparatus for discharging fluid from a nozzle including a housing having a variable volume chamber therein and an outlet check valve for controlling fluid communication between said variable volume chamber and the nozzle, the improvement wherein said outlet check valve includes an elastic valve member having a rearwardly extending portion thereon which is provided with an integral sealing means, said sealing means forming a seal between said nozzle and said housing, and a solid central portion movable responsive to pressure within the variable volume chamber and wherein the nozzle includes means for varying the degree of contact between the solid central portion of the elastic valve member and the nozzle to thereby vary the spray discharge pattern of the dispenser.

2. In a dispensing apparatus having a variable volume pump chamber for discharging fluid through an outlet conduit, an outlet check valve and an apertured nozzle cap, the improvement wherein the terminal end of the outlet conduit forms the valve seat for the outlet check valve, wherein the valve member of the outlet check valve includes:
a relatively rigid central portion for sealably engaging and disengaging the valve seat responsive to pressure in said outlet conduit;
a relatively flexible intermediate portion having at least one aperture therein; and an O-ring peripheral portion sealably engaging the radially inner surface of a nozzle cap in a sliding relationship thereto; and wherein said nozzle cap is selectively positionable to variably limit the excursion of said valve member from the valve seat.

3. The apparatus of Claim 2 wherein said nozzle cap may be selectively positioned to contact the central portion of said valve member to maintain said central portion in contact with said valve seat thereby disabling the outlet check valve.

4. The apparatus of Claim 1 wherein the nozzle includes a cap having a threaded portion engaging a threaded portion on said housing and a front cylindrical portion with an opening therein and wherein fluid-directing recesses are formed in one of the central portion of the elastic valve member and the inner surface of the front cylindrical portion of the cap.

5. The apparatus of Claim 2 wherein fluid-directing recesses are formed in one of the front face provided on said valve member and the rear face provided on the cylindrical front portion provided on the nozzle cap.