Fluid supply systems in industrial, residential, and commercial environments often include one or more accumulator tanks for insuring that the flow rate and pressure of fluid supplied to various locations is substantially steady. Some accumulator tanks contain a reservoir of fluid that can be supplied to the system at peak demand times in order to maintain a substantially steady fluid flow rate and pressure. At times of lower demand, the fluid supply system can replenish such accumulator tanks with fluid.
Accumulator tanks typically include a rigid outer shell having a single aperture through which fluid can flow to and from the fluid supply system. Accumulator tanks also typically include a flexible bladder made from a porous material, such as butyl rubber, positioned within the rigid outer shell. This flexible bladder also has a single aperture aligned with the aperture in the shell and through which fluid can flow to and from the fluid supply system. Fluid enters and exits the bladder through the aligned apertures, and does not contact the rigid outer shell of the accumulator tank. In order to permit bladder expansion and contraction as fluid enters and exits the accumulator tank, respectively, conventional accumulator tanks often include one or more air holes through the rigid outer shell.
During extended periods of low demand, fluid can remain in the bladder of an accumulator tank for relatively long periods of time. Also, deposits from the fluid can collect within the bladder and can adhere to the internal walls of the bladder (e.g., retained within pores of the rubber material). The tendency of such deposits to accumulate within the bladder increases the difficulty of maintaining clean and sanitary conditions within the accumulator tank.
Some embodiments of the present invention provide an accumulator tank assembly, comprising an accumulator tank having an inlet aperture through which fluid enters the accumulator tank; an outlet aperture through which fluid exits the accumulator tank; a flange coupled to the accumulator tank and through which fluid passing through the accumulator tank assembly moves, a flexible bladder located substantially within the accumulator tank and releasably coupled to the accumulator tank by the flange, the flexible bladder comprising: an internal volume; an inlet aperture through which fluid enters the flexible bladder; and an outlet aperture through which fluid exits the flexible bladder; wherein the flange is positioned to compress the flexible bladder against the accumulator tank to create a fluid tight seal between the flexible bladder and the accumulator tank; and wherein the flexible bladder is removable from the accumulator tank and has walls movable with respect to the accumulator tank to change the internal volume of the flexible bladder.
In some embodiments, an accumulator tank assembly is provided, and comprises an accumulator tank having an inlet aperture through which fluid enters the accumulator tank; and an outlet aperture through which fluid exits the accumulator tank; a flexible bladder located substantially within the accumulator tank, the flexible bladder comprising an inlet aperture adjacent the inlet aperture of the accumulator tank; an outlet aperture adjacent the outlet aperture of the accumulator tank; an inlet flange releasably coupling the flexible bladder to a surface of the accumulator tank adjacent the inlet apertures of the accumulator tank and the flexible bladder to form a first substantially fluid-tight seal between the accumulator tank and the flexible bladder; and an outlet flange releasably coupling the flexible bladder to a surface of the accumulator tank adjacent the outlet apertures of the accumulator tank and the flexible bladder to form a second substantially fluid-tight seal between the accumulator tank and the flexible bladder; wherein the flexible bladder is deformable within the accumulator tank responsive to changing fluid pressures within the flexible bladder, and is removable from the accumulator tank through at least one of the inlet and outlet apertures of the accumulator tank.
Some embodiments of the present invention provide a method of assembling an accumulator tank assembly, wherein the method comprises: providing an accumulator tank having inlet and outlet apertures through which fluid passes through the accumulator tank assembly; providing a flexible bladder having inlet and outlet apertures through which fluid passes through the accumulator tank assembly; inserting the flexible bladder within the accumulator tank, the flexible bladder deformable within the accumulator tank responsive to changes of fluid pressure within the flexible bladder; clamping a first portion of the flexible bladder to a first surface of the accumulator tank adjacent the inlet aperture of the accumulator tank while leaving at least a portion of the inlet apertures of the accumulator tank and flexible bladder open for fluid flow therethrough; establishing a first substantially fluid tight seal between the flexible bladder and the accumulator tank by clamping the first portion of the flexible bladder; clamping a second portion of the flexible bladder to a second surface of the accumulator tank adjacent the outlet of the accumulator tank while leaving at least a portion of the outlet apertures of the accumulator tank and flexible bladder open for fluid flow therethrough; and establishing a second substantially fluid tight seal between the flexible bladder and the accumulator tank by clamping the second portion of the flexible bladder.
Further features and a better understanding of the present invention, together with the organization and manner of operation thereof, will become apparent from the following detailed description of the invention when taken in conjunction with the accompanying drawings, wherein like elements have like numerals throughout the drawings.
The present invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced in various ways. Also, the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. The terms “connected,” “coupled,” and “mounted” are used broadly and encompass both direct and indirect connections, couplings, and mountings. In addition, the terms “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
The accumulator tank assembly 20 can be installed in any fluid supply system (not shown), such as in a water supply system for equipment drawing water in a restaurant, factory, office, residential building, and the like. In other embodiments, the accumulator tank assembly 20 can be installed in systems supplying any other type of fluid.
The accumulator tank assembly 20 can be oriented in any manner desired, such as in a substantially vertical orientation as shown in
The accumulator tank assembly 20 can be mounted to any structure using one or more support brackets 28. In the illustrated embodiment, two support brackets 28 are used to mount the accumulator tank 32 to the vertical structure 24, although any other number of support brackets 28 can instead be used. The support brackets 28 can be secured to the accumulator tank 32 or other portion of the accumulator tank assembly 20 and to the vertical structure 24 in any manner, such as by welding, brazing, adhesive and/or cohesive bonding material, bolts, screws, rivets, pins, clips, clamps, and other conventional fasteners, inter-engaging elements, snap-fits, and the like. In the illustrated embodiment for example, the support brackets 28 are coupled to the outer shell 32 by welds and are coupled to the vertical structure 24 by bolts 31.
In other embodiments, the accumulator tank assembly 20 can be secured to an adjacent structure in other manners, such as by one or more bosses or flanges on the accumulator tank 32 and/or adjacent structure, by one or more straps, bands, or belts coupled to the adjacent structure and extending at least partially around the accumulator tank 32, and the like.
In some embodiments of the present invention, the accumulator tank assembly 20 can include one or more brackets for mounting one or more devices to the accumulator tank assembly 20. Such brackets can have any shape and size, and can be coupled to the device(s) and the accumulator tank 32 or other portion of the accumulator tank assembly 20 in any of the manners described above with regard to the connections between the support brackets 28 and the accumulator tank 32 and structure 24. In the illustrated embodiment of
With continued reference to
The accumulator tank 32 can comprise any rigid material. In the illustrated embodiment, the accumulator tank 32 is stainless steel. In other embodiments, the accumulator tank 32 can comprise brass, aluminum, or other metals, plastic, fiberglass, glass, ceramic, composite materials, and any combination thereof.
The accumulator tank 32 can be constructed of any number of elements each having any size. By way of example only, the accumulator tank 32 illustrated in
The inlet and outlet apertures 40, 44 of the accumulator tank 32 illustrated in
With continued reference to
The flexible bladder 56 can have a body 68 with an internal bladder cavity 72. The body 68 can have any shape desired, including any of the shapes described above with reference to the accumulator tank 32. In some embodiments, the body 68 has a shape complimentary to the shape of the accumulator tank 32. Also, when the flexible bladder 56 is positioned within the internal cavity 36 of the accumulator tank 32, a gap 92 can be defined between an outer surface 96 of the flexible bladder 56 and an inner surface 100 of the accumulator tank 32. In some embodiments, the flexible bladder 56 is sized and shaped to engage the inner surface 100 of the accumulator tank 32 with the outer surface 96 of the flexible bladder 56 so that no gap 92 (or substantially no gap 92) exists between one or more portions, a majority, or substantially all of the flexible bladder 56 and the accumulator tank 32.
In some embodiments, the flexible bladder 56 can also have an inlet aperture 80 and an outlet aperture 88 through which fluid can enter and exit the flexible bladder 56, respectively. The inlet and outlet apertures 80, 88 in the illustrated embodiment are substantially round, although the inlet and outlet apertures 80, 88 can instead be rectangular, oval, irregular, or can have any other shape desired. In addition, the inlet and outlet apertures 80, 88 need not necessarily have the same shape and size.
The inlet and outlet apertures 80, 88 of the flexible bladder 56 illustrated in
With continued reference to the embodiment of
In the embodiment of
The inlet and outlet flanges 60, 64 can be coupled to the accumulator tank 32 by fasteners 120 threaded into threaded apertures in the accumulator tank 32 (and/or into nuts located within the accumulator tank 32). The fasteners 120 can be a plurality of bolts as shown in
The inlet and outlet flanges 60, 64 can be positioned to clamp a portion of the flexible bladder 56 against the accumulator tank 32, or to otherwise clamp the flexible bladder 56 with respect to the accumulator tank 32 (such as in cases where another element is located between the flexible bladder 56 and the accumulator tank 32). For example, the inlet and outlet flanges 60, 64 can clamp the flexible bladder 56 against exterior surfaces of the accumulator tank 32 adjacent the inlet and outlet apertures 40, 44 of the accumulator tank 32. In some embodiments, the inlet and outlet flanges 60, 64 clamp the inlet and outlet bladder flanges 76, 84 with respect to the accumulator tank 32, although other portions of the flexible bladder 56 can instead be clamped. For example, in some alternative embodiments, either or both end walls of the flexible bladder 56 can be clamped against internal surfaces of the accumulator tank 32 (described in greater detail below).
With reference to
By clamping the portions of the flexible bladder 56 as described above, a fluid-tight seal can be formed between the flexible bladder 56 and the accumulator tank 32 at or adjacent the inlet and outlet apertures 40, 44 of the accumulator tank 32. Although the inlet and outlet flanges 60, 64 in the illustrated embodiment have an annular shape for this purpose, the inlet and outlet flanges 60, 64 can have any other shape capable of performing this function, including without limitation square and other polygonal shapes, irregular shapes, and the like.
In some embodiments of the present invention, the inlet flange 60 includes an inlet pipe 104 through which fluid passes to enter the accumulator tank 32 and/or the outlet flange 64 includes an outlet pipe 108 through which fluid passes to exit the accumulator tank 32. The inlet and outlet pipes 104, 108 can be integral with the inlet and outlet flanges 60, 64 as best shown in
The inlet and outlet pipes 104, 108 can comprise any material desired, and can comprise the same or different material than the other portions of the inlet and outlet flanges 60, 64 (including any of the accumulator tank materials described above). Also, the inlet and outlet pipes 104, 108 can be substantially centrally located with respect to the corresponding inlet and outlet apertures 40, 44 of the accumulator tank 32 and/or the corresponding inlet and outlet apertures 80, 88 of the flexible bladder 56 as best shown in
As mentioned above, the inlet and outlet flanges 60, 64 of the illustrated embodiment can be clamped against the flexible bladder 56 by tightening the fasteners 120 of the inlet and outlet flanges 60, 64. In other embodiments, the clamping force of the inlet and outlet flanges 60, 64 can be generated in a number of other manners, all of which fall within the spirit and scope of the present invention. For example, the peripheral edge or other portion of the inlet and outlet flanges 60, 64 can be internally or externally threaded, and can be threaded into and tightened upon an annular groove, wall, step, or other feature of the accumulator tank 32. As another example, the inlet and outlet flanges 60, 64 can be provided with one or more protrusions or apertures mating in snap fit or press fit engagement with one or more apertures or protrusions on the accumulator tank 32. Although the inlet and outlet flanges 60, 64 in the illustrated embodiment are the same and perform the bladder clamping function in the same manner, the inlet and outlet flanges 60, 64 in other embodiments can be different in size, shape, manner of connection, and/or manner of clamping.
In some embodiments, the flexible bladder 56 can be secured to the accumulator tank 32 in a variety of other manners still falling within the spirit and scope of the present invention. For example, the accumulator tank 32 can include an inlet flange and an outlet flange positioned within the internal cavity 36 of the accumulator tank 32. In such embodiments, the flexible bladder 56 can be positioned between internal surfaces of the accumulator tank 32 and the inlet and outlet flanges 60, 64. Also in such embodiments, the inlet and outlet flanges 60, 64 can be tightened by fasteners passed through apertures in the accumulator tank 32 and inlet and outlet flanges 60, 64, by mating threads on the inlet and outlet flanges 60, 64 and on the accumulator tank 32 (e.g., female threads in the inlet and outlet apertures 40, 44 of the accumulator tank 32 mating with male threads on the inlet and outlet flanges 60, 64, and the like), by press or snap fits between elements or features on internal surfaces 100 of the accumulator tank 32 and the inlet and outlet flanges 60, 64, and the like. In such cases, the ends of the flexible bladder 56 need not extend radially inwardly as far as shown in
In still other embodiments, as illustrated in
In some embodiments, the accumulator tank 32 includes a valve 124 in fluid communication with the internal cavity 36 of the accumulator tank 32 and, particularly, in fluid communication with the gap 92 of the internal cavity 36 surrounding the flexible bladder 56 when the flexible bladder 56 is positioned with the internal cavity 36. The valve 124 can facilitate the passage of air or other fluid to and from the gap 92 surrounding the flexible bladder 56. In some embodiments, a source of air or other fluid (not shown) can be coupled to the valve 124 to introduce air or other fluid into the gap 92 in order to increase pressure around the flexible bladder 56. Increasing pressure between the accumulator tank 32 and the flexible bladder 56 can increase the pressure within the flexible bladder 56 and, therefore, can increase fluid pressure in the fluid supply system coupled to the accumulator tank assembly 20. The valve 124 can be actuated to release fluid from the gap 92 in order to reduce pressure around the flexible bladder 56. Decreasing pressure between the accumulator tank 32 and the flexible bladder 56 decreases pressure within the flexible bladder 56 and, therefore, can decrease fluid pressure in the fluid supply system coupled to the accumulator tank assembly 20.
With reference to
In operation, fluid moves through the accumulator tank 32 as fluid is required downstream of the accumulator tank 32. In periods of low fluid demand, the amount of fluid in the flexible bladder 56 can be relatively high, and fluid can move through the flexible bladder 56 at a relatively slow rate. During higher or peak fluid demand periods, fluid can move through the flexible bladder 56 at a relatively fast rate to compensate for the larger volume of fluid consumed downstream. In such periods, the flexible bladder 56 can contract, thereby supplying downstream apparatuses with an additional volume of fluid from the flexible bladder 56. As the demand for fluid decreases downstream, the flexible bladder 56 can expand to receive additional fluid for use in the next high or peak demand period. The amount of fluid in the flexible bladder 56 can be variable to compensate for the varying fluid demands of the fluid supply system and to maintain a steady or steadier fluid pressure at downstream locations.
With reference to
After the flexible bladder 56 is removed from the shell cavity 36, another flexible bladder 56 can be inserted into the shell cavity 36 through the inlet aperture 40 and/or the outlet aperture 44. In some embodiments, the inlet bladder flange 76 and the outlet bladder flange 84 can be appropriately positioned to extend out of the inlet aperture 40 and the outlet aperture 44, respectively, of the accumulator tank 32. The fasteners 120 can then be tightened to move the inlet flange 60 and the outlet flange 64 toward surfaces of the accumulator tank 32 and to compress the inlet bladder flange 76 and the outlet bladder flange 84 between the recessed annular portions 112 of the inlet and outlet flanges 60, 64 and the exterior surfaces of the accumulator tank 32. Once the inlet and outlet bladder flanges 76, 84 are sufficiently compressed, the replacement flexible bladder 56 is secured to the accumulator tank 32, and the accumulator tank assembly 20 is ready for operation within the water supply system. In some embodiments, air pressure surrounding the flexible bladder 56 can be increased by coupling an air source to the air valve 124 and introducing pressurized air into the gap 92 surrounding the flexible bladder 56.
The embodiments described above and illustrated in the figures are presented by way of example only and are not intended as a limitation upon the concepts and principles of the present invention. As such, it will be appreciated by one having ordinary skill in the art that various changes in the elements and their configuration and arrangement are possible without departing from the spirit and scope of the present invention as set forth in the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
357128 | Loretz | Feb 1887 | A |
407830 | Loretz | Jul 1889 | A |
578505 | Worthen et al. | Mar 1897 | A |
852150 | Whitney | Apr 1907 | A |
2261948 | Beach | Nov 1941 | A |
2652172 | Negola | Sep 1953 | A |
2685887 | Ame | Aug 1954 | A |
2735642 | Norman | Feb 1956 | A |
2760518 | Peet | Aug 1956 | A |
2838073 | Bruce et al. | Jun 1958 | A |
2896862 | Bede | Jul 1959 | A |
3057509 | Bernd | Oct 1962 | A |
3331399 | Von Forell | Jul 1967 | A |
3536102 | Zahid et al. | Oct 1970 | A |
3623629 | Hendershot | Nov 1971 | A |
4186775 | Muroi | Feb 1980 | A |
4313400 | Walker et al. | Feb 1982 | A |
4314621 | Hansen | Feb 1982 | A |
4514295 | Mathieu et al. | Apr 1985 | A |
4779757 | Fuckert et al. | Oct 1988 | A |
4796676 | Hendershot et al. | Jan 1989 | A |
4817830 | Yavorsky | Apr 1989 | A |
5064096 | Illing et al. | Nov 1991 | A |
5217138 | Nichols | Jun 1993 | A |
5253778 | Sirosh | Oct 1993 | A |
5397020 | Witt | Mar 1995 | A |
5522523 | Nogles | Jun 1996 | A |
5901744 | Richards | May 1999 | A |
5954222 | White et al. | Sep 1999 | A |
6029708 | Spell et al. | Feb 2000 | A |
6418969 | Bertagna | Jul 2002 | B1 |