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1. Field of the Disclosure
The invention relates in general to a dispensing system, and more particularly, to a metered dispensing system which utilizes an integrated spout and valve coupled to a bag within a metering dispenser.
2. Background Art
The metered dispensing of different flowable materials in a repeatable and controllable manner is known in the art. For example, in the fast food industry, a preparer must often quickly and efficiently dispense a generally known quantity of a flowable material onto foodstuffs, such as, for example, sandwiches, tacos or salads, among others. While the dispensing of an improper amount may be of little consequence, even a slight over dispensing of a condiment can negatively affect the desired flavor. In addition, even a slight over dispensing over the millions and millions of cycles of the dispenser can add up to be quite costly.
In turn, various solutions have been developed to provide a metered dispensing of such flowable material in a controlled, and efficient manner. Many of such solutions require the pressing of a trigger which dispenses a predetermined quantity of the flowable material from within a holding chamber. The trigger can be repeatedly actuated to deliver the same quantity of flowable material until the dispenser has been emptied.
Problematically, such containers, while effectively delivering a desired dose of flowable material, nevertheless suffer drawbacks. For example, many of such devices include a plurality of components that are assembled to form the dispenser. Many of these components come into contact with the flowable material. This includes the housing, the seals, some of the actuator components and the valve. As such, from time to time, the dispenser is typically fully disassembled and thoroughly cleaned. Not only is such a process time consuming, but in many instances there can be problems or issues that arise from the disassembly and reassembly processes.
The disclosure is directed to, in one aspect thereof, a dispensing system comprising a dispenser housing assembly and a bag assembly. The dispenser housing assembly having a canister, a dispensing mechanism, and a lower cap. The canister has a first end and a second end. The dispensing mechanism is coupled to the canister at the first end thereof. The dispensing mechanism has a piston slidably movable along the canister between the first end and the second end thereof. The lower cap is coupled to the canister at the second end thereof. The lower cap includes a central body with a central opening extending therethrough.
The bag assembly has a flexible bag, and an integrated spout and valve member. The flexible bag is defined by a plurality of seals that form the sides and second end. The first end is defined by a fold. The flexible bag defines a fluid tight cavity with an opening at the fold for providing ingress into the fluid tight cavity. The integrated spout and valve member is molded as a single member and coupled to the flexible bag at the first end and extending over the fold. The integrated spout and valve member is placed in fluid communication with the fluid tight cavity by way of the opening. The integrated spout and valve member further includes a spout portion and a valve portion. The spout portion includes a spout body with a proximal end and a distal end. An annular base flange is coupled to the spout body at the proximal end. The valve portion is disposed within the spout body. The valve portion includes a central portion with an opening, an annular marginal portion extending therearound, an annular sidewall portion extending from the annular marginal portion toward the distal end of the spout body, and an annular outwardly extending portion extending outwardly from the annular sidewall portion and coupled to an inner surface of the spout body. The valve portion spans across the spout body, with the opening providing passage therethrough.
In a preferred embodiment, the valve portion is maintained between the proximal end and the distal end of the spout body.
In another preferred embodiment, the spout body has a first thickness between the proximal end and the annular outwardly extending portion and a second thickness between the distal end and the annular outwardly extending portion. The first thickness is greater than the second thickness.
In another preferred embodiment, the annular outwardly extending portion is substantially perpendicular to the inner surface of the spout body.
In another preferred embodiment, the flexible bag comprises a single monolithic member having a first side seal extending from the fold on one side of the spout portion and a second side seal extending from the fold on another side of the spout portion. The first side seal and the second side seal each include an outer portion extending obliquely away from the fold and a side portion substantially perpendicular to the fold and oblique to the outer portion.
In another preferred embodiment, the end seal includes a central region that is substantially parallel to the fold and spaced apart therefrom. A first side region and a second side region is either side thereof and is coupled to a respective one of the first and second side seals. The first and second side regions being oblique to each of the side portions.
In another preferred embodiment, the annular base flange has an outer surface which is sealed to an inner surface of the flexible bag such that a portion of the annular base flange is positioned within the fluid tight cavity of the flexible bag.
In another preferred embodiment, the annular base flange comprises a conical configuration extending outwardly from the proximal end of the spout body in a concave upward configuration.
In another preferred embodiment, the central body of the lower cap further includes an inner conical portion disposed about the central opening. The inner conical portion substantially corresponding to the conical configuration of the annular base flange.
In another preferred embodiment, the central opening further comprises a slot region configured to allow the distal end of the spout to pass therethrough. The slot region is in communication with the operating region.
In another preferred embodiment, the canister and the lower cap are coupled together through rotative engagement of less than a half turn of the lower cap relative to the canister. And preferably less than an quarter turn.
In another preferred embodiment, the integrated spout and valve member further includes an outer flange positioned at the distal end of the spout body.
In yet another preferred embodiment, the outer flange further includes an inner surface and an outer surface. The outer flange has a diameter smaller than that of the annular base flange.
In another preferred embodiment, the outer flange is substantially perpendicular to the spout body.
Preferably, an outer lip portion is disposed on the outer surface of the outer flange, to, in turn, define a cavity together with the outer surface.
In some such embodiments, a removable cover is positioned within the cavity so as to extend across the distal end of the spout body and to cover the valve portion.
In another preferred embodiment, the flexible bag further comprises a pull tab positioned proximate the second end of the flexible bag. The pull tab is structurally configured to facilitate the grasping of the flexible bag to aid in pulling the flexible bag into and through the canister and into a desired orientation.
In another preferred embodiment, the pull tab is integrally formed with the flexible bag.
In another aspect of the disclosure, the disclosure is directed to an integrated spout and valve member molded as a single member attachable to a flexible bag. The integrated member comprises a spout portion and a valve portion. The spout portion includes a spout body with a proximal end and a distal end. An annular base flange is coupled to the spout body at the proximal end. The valve portion is disposed within the spout body. The valve portion includes a central portion with an opening, an annular marginal portion extending therearound, an annular sidewall portion extending from the annular marginal portion toward the distal end of the spout body, and an annular outwardly extending portion extending outwardly from the annular sidewall portion and coupled to an inner surface of the spout body. The valve portion spans across the spout body, with the opening providing passage therethrough.
In a preferred embodiment, the annular base flange comprises a conical configuration extending outwardly from the proximal end of the spout body in a concave upward configuration.
In another preferred embodiment, the integrated spout and valve member further has an outer flange positioned at the distal end of the spout body.
In yet another preferred embodiment, the integrated spout and valve member further has a removable cover positioned over the outer flange so as to cover the valve portion within the spout body.
The disclosure will now be described with reference to the drawings wherein:
While this invention is susceptible of embodiment in many different forms, there is shown in the drawings and described herein in detail a specific embodiment with the understanding that the present disclosure is to be considered as an exemplification and is not intended to be limited to the embodiment illustrated.
It will be understood that like or analogous elements and/or components, referred to herein, may be identified throughout the drawings by like reference characters. In addition, it will be understood that the drawings are merely schematic representations of the invention, and some of the components may have been distorted from actual scale for purposes of pictorial clarity.
Referring now to the drawings and in particular to
The dispenser housing assembly 12 includes dispensing mechanism 20, canister 22 and lower cap 24. The dispenser housing assembly 12 is generally sized so as to be handled by a user with one or both hands. The dispensing mechanism 20 comprises body 26 which is coupled to the canister through mounting mechanism 30, a piston 32, a rod 34 coupled to the body and to the piston, and a rod moving mechanism 36. The mounting mechanism comprises a pair of opposing slots that are configured to accept mating tabs and, upon receipt and rotation of the body relative to the canister, the tabs lock within the slots.
Generally, in the installed orientation, the piston 32 is slidably positioned within the canister. The rod 34 is coupled to the piston 32 and configured to slidably direct the piston within the canister. The rod moving mechanism 36 is coupled to the body and to the rod. The rod moving mechanism acts like a trigger which, upon actuation, triggers a desired incremental movement upon the rod, thereby moving the piston a predetermined distance along the canister. One such dispensing mechanism is shown in U.S. Pat. No. 8,511,520 issued to Van Wijk et al. and currently assigned to FundaMetal Design, Inc., of Burnaby, British Columbia, Canada, the entire specification of which is hereby incorporated by reference in its entirety. Another such dispensing mechanism, which is believed to be a commercial embodiment of the '520 patent, is sold under the name “Portion Pal” available from FIFO Bottle of Burnaby, British Columbia, Canada.
As shown in
At the first end 40 of the canister 22, a pair of tabs 45 are disposed thereon, which cooperate with the slots identified above with respect to the mounting mechanism 30. It will be understood that once inserted into the slots, a rotation of the two relative to each other locks the two in releasable engagement. At the second end of the canister 22, the lower attachment mechanism is positioned. The lower attachment mechanism comprises a pair of spaced apart slots 47 which are configured to receive opposing tabs, and upon receipt, are configured to releasably engage corresponding tabs in operative engagement. In the embodiment shown, a relative rotation of less than a quarter turn is required to couple the two structures together.
The lower cap 24 is shown in
The central opening 53 includes slot region 54 and operating region 55. The operating region 55 is centrally disposed on the lower cap. The central opening 53 is configured to releasably retain the spout of the integrated spout and valve member 72, in a generally snug manner. To install the spout into the proper orientation, the slot region 54 is provided adjacent to the operating region 55. The slot region comprises an enlarged arcuate region which is configured to allow the spout portion, and in particular the outer flange thereof to extend therethrough so that the spout body between the annular base flange and the outer flange can be positioned into operable engagement with the operating region 55. The overlap is such that the operating region and slot region overlap is generally less than 90° although, ranges up to 150° are contemplated. While it is possible to have the interaction even greater, or lesser, the desire is to have the overlap such that the spout remains within the operating region 55, while the slot region is of sufficient size and the overlap is of sufficient size so as to allow the proper insertion of the spout into operable position.
The outer annular flange 60 is shown in
The bag assembly 14 is shown in
The end seal 90 includes central region 100, first side region 102 and second side region 104. The end seal 90 transitions the bag between the first end 40 of the canister 22 and the piston 32. It is contemplated that each of the seals are formed through any number of different techniques, including, but not limited to, heat, RF welding, ultrasonic welding, among others. The film 74 along with the seal assembly 76 provide a fluid tight cavity defined thereby. An opening 79 is disposed across the fold 80, and is configured to be placed in fluid communication with the spout body 106, as will be described below. The configuration of the bag is such that the integrated spout and valve member can be attached to a continuous portion of the film to minimize leaking and the like, with the flexible bag configured to closely match (and to be slightly oversized) relative to the chamber of the canister within which the flexible bag will be positioned. It will be understood that variations to the seals can be made so as to more closely mimic the configuration of the canister 22. It will also be understood that additional dimensional variations may be made to more closely mimic the configuration of the canister 22. The configuration shown, however, provides an easily made pillow type configuration with an integrated and seal free surface upon which the spout is to be coupled, and a shape wherein the spout and the bag are positioned so as to minimize undesirable relative forces which may tend to weaken the connection therebetween.
Additional embodiments of the bag assembly 14 are shown in
The integrated spout and valve member 72 is shown in
The spout portion 78 includes spout body 106, annular base flange 108 and outer flange 110. As shown in
The annular base flange 108 is shown in
The outer flange 110 is positioned at the distal end 114 of the spout body 106. The outer flange 110 includes inner surface 130, outer surface 132. The inner end 134 meets the distal end 114 of the spout body. The outer end is spaced therefrom. The outer flange is generally of a diameter that is smaller than that of the annular base flange, and the slot region 54 of the lower cap is configured to permit the passage of the outer flange therethrough so as to direct the spout into the desired orientation within the operating region. The outer flange has a plurality of outer lip portions 138. As will be explained, the outer lip portions 138 cooperatively provide an annular flange which creates a cavity defined by the lip portions and the outer surface 132 of the flange. A tamper evident cover or other sterilization cover can be positioned within the cavity, with the lip portions protecting the cover from outside inadvertent contact, precluding potential inadvertent damage. The lip portions are generally separated so as to facilitate access to the cover to aid in the removal thereof. In other embodiments, the annular lip portion may comprise a single portion without any breaks therebetween, or a single break (i.e., the single lip portion extends substantially entirely about the outer end 136 of the outer flange 110).
The valve portion 79 is shown in
The annular sidewall portion 144 extends from the marginal edge toward the distal end of the spout body, and generally spaced apart from the inner surface of the spout body. It will be understood that in the embodiment shown, the annular sidewall portion is slightly frustoconical in that the diameter increases slightly toward the distal end of the spout body. The annular outwardly extending portion 146 joins the annular sidewall portion 144 to the inner surface of the spout body. The annular outwardly extending portion meets the inner surface of the spout body spaced apart from the distal end of the spout body, with the central portion 140 likewise being spaced apart from the proximal end of the spout body such that the entirety of the valve (in the resting closed orientation shown) remains within the confines of the spout body. In the embodiment shown, the spout body thickness is larger between the proximal end thereof and where the annular outwardly extending portion meets the inner surface of the spout body, than the thickness between the annular outwardly extending portion and the distal end of the spout body. Such a configuration aids in the outward movement of the annular outwardly extending portion 146 and inward return movement when the valve cycles between an closed and open position. In the embodiment shown, the annular outwardly extending portion is substantially planar and perpendicular to the inner surface of the spout body, and to the flow through the valve. Of course, in other embodiments, the annular outwardly extending portion 146 could be non-perpendicular to the inner surface of the spout body. It will be understood that the entirety of the integrated spout and valve member are formed as an integrated monolithic component that is molded as a single member, with the valve structure incorporated therein.
The operation of the valve is such that when the pressure increases on the inside of the valve, eventually, the annular outwardly extending portion rotates outwardly, with the annular sidewall portion rolling upon itself. Eventually, the annular marginal portion and the central portion undergo deformation such that the openings 150 are urged into the open position, allowing the passage of flowable material therefrom. The flow continues, until the pressure within the flexible bag is such that there is no longer enough force to cause the valve to deform, to, in turn, open the openings 150 of the central portion. In such a configuration, the resilience of the valve returns the valve to the original configuration (much like the configuration shown in the drawings), thereby closing the valve and precluding passage of additional flowable material. The particular pressure at which the valve opens and closes is determined through the material, as well as the dimensions of the different components. Another example of the operation of such a deformable a valve and its openings is shown in U.S. Pat. Nos. 5,439,143; 5,339,995; 5,213,236 all issued to Brown et al. All of the foregoing patents are incorporated in their entirety herein by reference.
As shown in
To assemble a dispensing system, the user is first provided with a bag assembly 14. Typically, the bag assembly 14 is prefilled with a desired flowable material (such as a sauce, a dressing, a marinate, a vinegar, an oil, among others). Generally the bag is filled with a predetermined quantity of the flowable material, with, preferably some head space within the bag assembly (as the bag assembly is preferably dimensionally larger than the canister).
Once provided, the bag is coupled to the lower cap 24. To achieve the same, the user directs the integrated spout and valve 72 into operative position within the central opening. In more detail, the outer flange of the spout is pushed through the slot region 54 of the lower cap so that the spout body can be captured within the operating region 55 of the central opening. Once in the proper position, the annular base flange 108 is in abutting engagement with the conical portion of the central body. It may be necessary to elastically deform the outer flange to achieve insertion through the slot region of the central opening.
Once the bag assembly is coupled to the lower cap, the bag assembly is inserted into the canister 22 and the lower cap 24 is coupled to the canister. In particular, the user slides the bag assembly through the second end 41 of the canister. Due to the amount of filling, the user should be able to slidably insert the flexible bag without substantial difficulty. As the bag assembly reaches full insertion, or at least insertion sufficient to engage the lower cap and the canister without pinching a portion of the bag therebetween, the tabs 35 of the outer annular flange 50 are directed into contact with and engagement with the lower attachment mechanism 47 and the slots thereof. Once engaged, the two are turned relative to each other to lockingly engage the two components. Advantageously, while it is contemplated that a threaded engagement requiring more than a quarter of a turn is contemplated, the tab and slot engagement allows for a minimal relative rotation of the canister and the lower cap relative to each other (and in turn, a minimum of rotation of the bag assembly within the canister). It has been found that limiting the relative rotation limits the possibility of damage to the underlying bag assembly.
The user then couples the dispensing mechanism 20 to the canister 22. It will be understood that the dispensing mechanism can be coupled to the canister prior to insertion of the bag assembly into the canister and attachment of the lower cap. To achieve the attachment, the user positions the piston 32 within the canister through the first end thereof. The rod is coupled thereto and to the rod moving assembly 36. Next, the body 26 of the dispensing mechanism can be coupled to the first end of the canister by interfacing the mounting mechanism 30 with the upper attachment mechanism 45. Once fully inserted, the piston 32 is positioned proximate to the second end of the flexible bag (i.e., opposite the integrated spout and valve member). The system is now ready to dispense flowable material from within the bag assembly.
To dispense flowable material, the user actuates the rod moving mechanism to direct the piston 32 toward the second end of the canister and the lower cap. For example, the rod moving mechanism can advance the piston a predetermined distance along the canister each time the mechanism is actuated. In other embodiments, the system may be indexed, or may depend on the amount of force exerted on the rod moving mechanism.
Regardless of the manner in which the piston movement is achieved, as the piston is directed toward the second end of the canister, the piston imparts force against the flexible bag and eventually applies pressure against the flowable material within the flexible bag. As the pressure within the bag increases, eventually, a predetermined pressure/force is observed at the valve that is required to open the valve. When such pressure is reached, the valve opens and directs flowable material through the opening of the valve. The flow continues until the force required to maintain the valve in the open position is no longer present. At such time, the resilience of the valve returns the valve to a closed orientation. This cycle can be repeated as desired until the piston has reached the end of its travel, and/or the flexible bag no longer contains flowable material which the piston can apply enough pressure to open the valve.
Once the user has completed dispensing, the user can uncouple the lower cap from the canister. Next, the bag assembly can be decoupled from the lower cap and the bag assembly can be discarded. A new bag assembly can be provided and coupled to the dispenser as set forth above. That is, there is no need to clean the inside of the canister, as the inside of the canister is isolated from the flowable material and is not contaminated by the flowable material. Advantageously, contamination is minimized as well as spoilage and other negative results of the inadvertent failure to properly clean the components where there is direct contact with flowable material.
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.