Fill valve assembly for filler device

Information

  • Patent Grant
  • 6786248
  • Patent Number
    6,786,248
  • Date Filed
    Thursday, October 10, 2002
    22 years ago
  • Date Issued
    Tuesday, September 7, 2004
    20 years ago
Abstract
A fill valve assembly for use in association with a filler device comprising an outer housing, a product dispensing member, a displaceable piston and a seal member. The product dispensing member is associated with the outer housing. The displaceable piston is displaceably positioned within the outer housing. The seal member is fixedly associated with the displaceable piston at one end thereof, and at least one of the outer housing and the product dispensing member, at another end thereof. The seal member is capable of maintaining fixed association throughout displacement of the displaceable piston, such that isolation of outer housing and the product dispensing member can be maintained without the use of seals having slidable engagement.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates in general to a fill valve assembly, and more particularly, to a fill valve assembly for use in association with a filler device, which maintains a fill material (e.g. fluid) in desired regions, and substantially precludes undesirable contamination of the fill valve assembly by the fill material.




2. Background Art




Fill valve assemblies for use in association with filler devices have been known in the art for many years. While fill valve assemblies have become commercially available for use in association with filler devices the cleanliness of associated components remains problematic. Cleanliness of the components is especially problematic with respect to fill valve assemblies which are used in association with, for example, food products (hereinafter referred to as the fill material), where cleanliness and sanitation standards are relatively stringent.




For example, fill valve assemblies have a plurality of movable and/or displaceable components which can be, at some point during the fill process, in direct contact with the fill material. As these parts move relative to each other, the fill material can be spread to other regions of the fill valve assembly. While seals can be positioned, in an attempt to preclude and/or minimize any undesirable spread of the fill material (or, conversely, the passage of contaminants into the fill material) it is extremely difficult to maintain the desired sanitized conditions over an extended period—due to rapid movement and sliding seal interfaces. As such, it becomes necessary to disassemble or to otherwise interrupt operation to clean the fill valve assembly.




Accordingly, it is an object of the present invention to provide a fill valve assembly which precludes the undesirable spreading of fill material or contamination thereof.




It is another object of the present invention to provide a fill valve assembly which is capable of operating for many cycles and/or extended periods of time without undesirable spreading of fill material or contamination thereof.




SUMMARY OF THE INVENTION




The invention comprises a fill valve assembly for use in association with a filler device. The fill valve assembly comprises an outer housing, a product dispensing member, a displaceable piston and a seal member. The product dispensing member is associated with the outer housing. The displaceable piston is positioned within at least a portion of the outer housing and the product dispensing member. The seal member is fixedly associated with the displaceable piston at one end thereof and fixedly associated with at least one of the outer housing and the product dispensing member at another end thereof.




In one preferred embodiment, the seal member comprises a bellows having a plurality of flexing regions. In one such embodiment, the flexing regions of the bellows define a plurality of peaks and valleys. The valleys are positionable proximate the piston, and the peaks extend outwardly therefrom.




In a preferred embodiment, the seal member includes a region of increased rigidity proximate at least one of the first and second ends thereof. Preferably, the seal member includes a region of increased rigidity proximate each of the first and second ends thereof.




In one embodiment of the invention, the displaceable piston further comprises a body and a sleeve. The body includes a first end, a second end, and a lip positioned therebetween. The sleeve includes a first end and a second end. The sleeve extends over at least a portion of the body between the first end and the lip. The second end of the sleeve is positioned proximate the lip of the body.




In one such embodiment, the second end of the seal member is fixedly engaged between the second end of the sleeve and the lip of the body.




In another such embodiment, the piston further comprises a spacer positioned proximate each of the first ends of the body and the sleeve. The spacer is slidably positionable relative to the body and fixedly engageable with the first end of the sleeve. Downward movement of the spacer imparts downward movement of the second end of the sleeve toward the lip of the body.




In a preferred embodiment, the product dispensing member further comprises an upper assembly and a lower assembly.




In another preferred embodiment, the invention further comprises a displacing member comprising an annular ring and means for displacing the annular ring. The annular ring is associated with the displaceable piston such that movement of the annular ring imparts movement upon the displaceable piston. The annular ring is positioned with an inner cavity of the outer housing so as to bisect the inner cavity into an upper inner cavity and a lower inner cavity. The annular ring displacing means displaces the annular ring within the inner cavity.




In a preferred embodiment, the displacing means further comprises an upper fluid port and a lower fluid port. The upper fluid port is in communication with the upper cavity. The lower fluid port is in communication with the lower cavity. Fluid can be selectively directed to each of the upper and lower fluid ports so as to displace the annular ring with the inner cavity.











BRIEF DESCRIPTION OF THE DRAWINGS




The invention will now be described with reference to the drawings wherein:





FIG. 1

of the drawings is a cross-sectional view of an embodiment of a fill valve assembly fabricated in accordance with the present invention.











DETAILED DESCRIPTION OF THE INVENTION




While this invention is susceptible of embodiment in many different forms, there is shown in the drawings and will be described in detail, a specific embodiment with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the invention to the embodiment illustrated.




It will be understood that like or analogous elements and/or components, referred to herein, are identified throughout the drawing by like reference characters. In addition, it will be understood that the drawing is merely a schematic representation of a first embodiment of the invention, and some of the components may have been distorted from their actual scale for purposes of pictorial clarity.




Referring now to the drawings, and to

FIG. 1

in particular, a cross-sectional view of a first embodiment of fill valve assembly


10


is provided as generally comprising outer housing


12


, product dispensing member


14


, piston


16


, displacing member


18


and seal member


20


. Fill valve assembly


10


is primarily intended for use in association with filler devices, which are generally capable of filling associated containers and/or bags with any one of a number of fill materials in solid, liquid, and/or gaseous states. Such filler devices may comprise linear filler devices, rotary filler devices and other devices which are capable of filling containers with fill material.




Outer housing


12


is shown in

FIG. 1

as including outer surface


30


, upper opening


31


, inner surface


32


, lower opening


33


, inner cavity


34


, passages


37


A,


37


B, mounting assembly


38


and attachment lip


39


. Upper opening


31


and lower opening


33


are substantially collinear and facilitate the passage of piston


16


therethrough. Mounting assembly


38


is associated with outer surface


30


and facilitates the attachment of the housing, and in turn, the fill valve to the filler device. In certain embodiments, guide


27


may be positioned proximate lower opening


33


so as to facilitate proper alignment and positioning of piston


16


within outer housing


12


.




Passages


37


A and


38


B extend from outer surface


30


to inner surface


32


and fluidly communicate with inner cavity


34


. As will be explained, the passages are associated with displacing member


18


to effectuate movement of piston


16


. Generally, outer housing


12


comprises a rigid material which is capable of withstanding repeated loads. In one embodiment, the outer housing is fabricated from stainless steel.




Product dispensing member


14


is shown in

FIG. 1

as including upper assembly


40


and lower assembly


42


. Upper assembly


40


includes inner surface


41


, cavity


43


, inlet


44


, upper opening


45


, lower opening


46


, upper mounting lip


47


and lower mounting lip


48


. Inner surface


41


defines cavity


43


. Inlet


44


is positioned so as to be in fluid communication with cavity


43


at the one end, and, in fluid communication with a product supply line at the other end. Upper opening


45


and lower opening


46


are positioned in a spaced-apart orientation and substantially collinear with the upper and lower openings of outer housing


12


, for receipt and passage of piston


16


therethrough. Upper mounting lip


47


extends around upper opening


45


. The upper mounting lip can be positioned in an abutting relationship with attachment lip


39


and secured thereto with compression clamps, such as compression clamp


83


. Lower mounting lip


48


extends around lower opening


46


, and, as will be explained, is secured to lower assembly


42


.




Lower assembly


42


is shown in

FIG. 1

as comprising inner surface


49


, cavity


50


, upper opening


51


, upper mounting lip


65


, nozzle


52


and outer configuration


53


. Inner surface


49


defines cavity


50


. In the embodiment shown in

FIG. 1

, inner surface


49


is configured so as to taper toward the nozzle (i.e., upper opening


51


has a larger diameter than nozzle


52


). Of course, in other embodiments, different configurations for the inner surface are contemplated for use.




Upper opening


51


substantially corresponds to lower opening


46


of upper assembly


40


. Upper mounting lip


65


extends about upper opening


51


and is secured to lower mounting lip


48


by way of compression clamps, such as compression clamp


85


. Nozzle


52


is positioned at an end opposing upper opening


51


. The opening is dimensioned to correspond to a desired fluid opening. Such an opening can be varied to achieve different fill properties and different fill characteristics. Outer configuration


53


surrounds nozzle


52


, and is adapted for interfacing with the container to be filled by the valve. As such, outer configuration


53


may comprise a number of different configurations, depending on the configuration of the container to be filled by the valve.




Displaceable piston


16


is shown in

FIG. 1

as comprising body


54


and sleeve


56


, spacer


58


and fastener


67


. Body


54


includes first end


55


, second end


57


, lip


63


and seal


73


. Body


54


comprises a first diameter between first end


55


and lip


63


, and a second larger diameter between lip


63


and second end


57


. Seal


73


is positioned proximate second end


57


of body


54


. In certain embodiments, seal


73


may comprise a flexible sealing member, such as, for example, a flexible o-ring made from a suitable synthetic or natural member. In other embodiments, seal


73


may comprise a machined portion of body


54


which sealingly engages nozzle


52


of lower assembly


42


.




Sleeve


56


is shown in

FIG. 1

as comprising first end


59


and second end


61


. First end


59


substantially corresponds to first end


55


of body


54


. Second end


61


substantially corresponds to lip


63


of body


54


. In the embodiment shown, sleeve


56


is substantially collinear with body


54


and extends around a portion of same. Spacer


58


is positioned such that body


54


extends therethrough and spacer


56


terminates therein. In turn, spacer


58


is slidably positionable relative to body


54


and fixedly engaged with sleeve


56


at least in one direction. Fastener


67


is associated with body


54


and spacer


58


. The fastener serves to force the spacer and the sleeve toward the second end of body


54


, such that second end


61


of sleeve


56


is directed toward lip


63


of body


54


. Piston


16


is preferably fabricated from a metal material of substantial rigidity and strength. For example, stainless steel is one such material which additionally provides a strong resistance to corrosion.




As shown in

FIG. 1

, displacing member


18


includes annular ring


60


, upper stop


62


, lower stop


64


, upper fluid port


66


, and lower fluid port


68


. Upper stop


62


and lower stop


64


are spaced apart within inner cavity


34


so as to define the upper and lower end of inner cavity


34


. Annular ring


60


is rigidly fixed to sleeve


56


of piston


16


and sized so as to interface with inner surface


32


to bisect inner cavity


34


into an upper cavity portion


34


A and lower cavity portion


34


B. Annular ring


60


includes seal member


67


which substantially sealingly isolates upper and lower cavity portions


34


A and


34


B, respectively, from each other.




Upper fluid port


66


extends through passage


37


A and is in fluid communication with upper cavity portion


34


A. Lower fluid port


68


extends through passage


37


B and is in fluid communication with lower cavity portion


34


B. The upper and lower fluid ports provide a means for displacing annular rim


60


within inner cavity


34


. It is contemplated that the annular rim displacing means may comprise a single fluid port in cooperation with a biasing means, such as a spring and the like, wherein fluid is used to overcome the biasing means and to move the annular rim in a first direction, and the biasing means is used to return the annular ring after the supply from the fluid port is ceased. Additional o-rings and seals are included along inner surface


32


so as to isolate the upper and lower cavity portions


34


A,


34


B from upper opening


31


and lower opening


33


of outer housing


12


.




In another embodiment of the invention, it is contemplated that the displacing member


18


may comprise an electrically or electronically controlled stepper or servo motor instead of the pneumatic control system shown in FIG.


1


. In such an embodiment, a stepper or servo motor or other device is controlled electrically or electronically to precisely control the movement of the displaceable piston relative to the dispensing member. In addition, other displacing members are likewise contemplated for use.




Seal member


20


includes flexible seal member


70


having first end


72


and second end


74


. First end


72


interfaces with outer housing


12


and product dispensing member


14


such that sealing engagement is maintained therebetween. In the embodiment shown, clamp


83


serves to compress first end


72


between lower opening


33


of outer housing


12


(and guide


27


) and upper opening


45


of upper assembly


40


. Second end


74


is compressed by fastener


67


between second end


61


of sleeve


56


of piston


16


and lip


63


of body


54


of piston


16


. As such, sleeve


56


and outer housing


12


are fluidly isolated from cavity


43


and cavity


50


of product dispensing member


14


, and conversely, the cavities


43


,


50


are fluidly isolated from sleeve


56


and housing


12


.




In one embodiment flexible seal member


70


may comprise a bellows which includes a plurality of predetermined flexing regions, such as flexing region


76


. Of course, the number of flexing regions may comprise as little as a single flexing region to a multitude of different flexing regions. The flexing regions facilitate the controlled deformation of the seal member as the piston moves relative to product dispensing member


14


. Indeed, through flexing regions


76


the movement and flexing of seal member


20


can be controlled and managed throughout the travel of piston


16


. In the particular embodiment, the flexing regions define a plurality of peaks and valleys, wherein the valleys are naturally positioned proximate the sleeve and the peaks extend outwardly therefrom. By maintaining the valleys proximate the sleeve, the obstruction of cavity


43


by seal member


20


can be minimized.




In the embodiment shown, regions


91


,


93


of increased rigidity may be positioned proximate first end


72


and second end


74


. Such a configuration precludes distortion of a portion of seal


20


into outer housing


12


proximate lower opening


33


thereof. Similarly, such a configuration precludes inadvertent distortion of portions of the seal into cavity


50


of lower assembly


42


. Furthermore, the structures can be configured.




In another embodiment, the seal member may include a highly flexible member such that there are no predetermined flexing regions, rather, the structure is capable of flexing at differing locations along the surface thereof depending on the conditions present within the cavity of the upper assembly of the dispensing member.




In the various embodiments, the seal member generally comprises a natural and/or synthetic polymer or flexibly resilient material capable of repetitive extension and/or contraction over a number of cycles—so as to properly function under conditions of its intended use. One such material may include PTFE, or the like.




In operation, fill valve assembly


10


is associated with a filler device. In particular, mounting assembly


38


of outer housing


12


is attached to a corresponding structure on the filler device, by way of, for example, fasteners and the like. Next, a material supply line is placed in fluid communication with inlet


44


of product dispensing member


14


. Likewise, each of one upper fluid port


66


and lower fluid port


68


is associated with fluid supplies and associated controllers which can control the fluid delivery through the ports. In the presently contemplated embodiment, the fluid utilized with upper and lower fluid ports comprises air, however, other fluids are likewise contemplated for use.




Once the fill valve assembly is fully integrated into the filler device, a container is associated with nozzle


52


. In particular, the container is directed such that the opening of the container cooperates with outer configuration


53


of the lower assembly of the dispensing member. Subsequently, fluid is directed through lower fluid port


68


into lower cavity portion


34


B. The passage of fluid into the lower cavity portion forces annular ring


60


in an upward direction toward and into contact with upper stop


62


. As annular ring


60


is fixedly associated with sleeve


56


of piston


16


, upward movement of annular ring


60


likewise imparts upward movement of piston


16


.




At such time, seal member


20


contracts as piston


16


moves relative to outer housing


12


and product dispensing member


14


. As the embodiment shown includes predetermined flexing regions


76


, seal member


20


uniformly folds during the contraction in a controlled manner, maintaining isolation of inner surface


32


and sleeve


56


of piston


16


from cavities


43


,


50


of dispensing member


14


, and, conversely, the isolation of cavities


43


,


50


from inner surface


32


and sleeve


56


.




As piston


16


continues in an upward direction, seal


73


is eventually displaced from nozzle


52


and fill material is permitted to flow through nozzle


52


into the container. Once the container has been filled as desired, the supply of fluid through the lower fluid port


68


into lower cavity portion


34


B is halted. Instead, fluid is directed through upper fluid port


66


into upper cavity portion


34


A. In turn, annular ring


60


and piston


16


are directed in a downward direction until ring


60


interferes with lower stop


64


and/or seal


73


again interfaces with nozzle


52


. Once seal


73


and nozzle


52


interface, the flow of fill material through nozzle


52


ceases.




Contemporaneously, seal member


20


extends to a substantially extended position while retaining the fixed relationship with outer housing


12


and product dispensing member


14


, to maintain isolation of the outer housing and the sleeve from the cavities of the product dispensing member, and, conversely, between the cavities and the outer housing and the sleeve. This cycle is repeated for each subsequent filling of containers.




Advantageously, as annular ring


60


moves from upper stop


62


to lower stop


64


and back to upper stop


62


, seal member


20


repeatedly extends and contracts to maintain an effective fluid tight seal. Significantly, seal member


20


is adapted for use in place of sliding (o-ring) type seals between piston


16


and outer housing


12


. In turn, the possible contamination that can result from the passage of undesirable material beyond a sliding type seal (in either direction) is eliminated as seal member


20


is fixed at either end and can contain the fill material to the product dispensing member. Moreover, the need to clean the inside surfaces of the outer housing and the cavities of the dispensing member are greatly reduced.




The foregoing description merely explains and illustrates the invention and the invention is not limited thereto except insofar as the appended claims are so limited, as those skilled in the art who have the disclosure before them will be able to make modifications without departing from the scope of the invention.



Claims
  • 1. A fill valve assembly for use in association with a filler device, comprising:an outer housing; a product dispensing member associated with the outer housing; a displaceable piston positioned within at least a portion of the outer housing and the product dispensing member, the displaceable piston further comprises: a body having a first end, a second end, and a lip positioned therebetween; a sleeve having a first end and a second end, the sleeve extending over at least a portion of the body between the first end and the lip, wherein the second end of the sleeve is positioned proximate the lip of the body; and a spacer positioned proximate each of the first ends of the body and the sleeve, wherein the spacer is slidably positionable relative to the body and fixedly engageable with the first end of the sleeve, whereupon downward movement of the spacer moves the second end of the sleeve toward the lip of the body; and a seal member, the seal member fixedly associated with the displaceable piston at a list end thereof, and fixedly associated with at least one of the outer housing and the product dispensing member at a second end thereof, the seal member comprises a bellows having a plurality of flexing regions, wherein the first end of the seal member is fixedly engaged between the second end of the sleeve and the lip of the body.
  • 2. The fill valve assembly of claim 1 wherein flexing regions of the bellows define a plurality of peaks and valleys, the valleys being positionable proximate the piston, and the peaks extending outwardly therefrom.
  • 3. The fill valve assembly of claim 1 wherein the seal member includes a region of increased rigidity proximate at least one of the first and second ends thereof.
  • 4. The fill valve assembly of claim 1 wherein the seal member includes a region of increased rigidity proximate each of the first and second ends thereof.
  • 5. The fill valve assembly of claim 1 wherein the product dispensing member further comprises an upper assembly and a lower assembly.
  • 6. The fill valve assembly of claim 1 further comprising a displacing member comprising:an annular ring associated with the displaceable piston such that movement of the annular ring imparts movement upon the displaceable piston; the annular ring positioned with an inner cavity of the outer housing so as to bisect the inner cavity into an upper inner cavity and a lower inner cavity; and means for displacing the annular ring within the inner cavity.
  • 7. The fill valve assembly of claim 1 wherein the displacing means further comprises:an upper fluid port in communication with the upper cavity; and a lower fluid port in communication with the lower cavity, wherein fluid can be selectively directed to each of the upper and lower fluid ports so as to displace the annular ring with the inner cavity.
CROSS-REFERENCE TO RELATED APPLICATION

This application claims the priority of co-pending Provisional Patent Application Serial No. 60/328,475 filed Oct. 11, 2001, entitled “Fill Valve Assembly for Filler Device.”

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Provisional Applications (1)
Number Date Country
60/328475 Oct 2001 US