Apparatus for inducing gravity feed of liquids

Abstract

Apparatus and method for transferring liquids from a sealed air-tight container to a second container by means of gravity feed, the apparatus including an air pressure input line having a one-way check valve for providing pressurized air into an air space above liquid in the air-tight container and means for escape of displaced liquid from the container in response to the induced air pressure, and an output line for feeding the displaced liquid to the second container.

Description

DRAWINGS

FIG. 1 is an exploded view illustrating apparatus in accordance with the invention;

FIG. 2 illustrates in perspective view apparatus of the invention connected for transferring liquid from a closed container to another container in accordance with the invention;

FIG. 3 is a cross-sectional view taken along lines 3-3 of FIG. 2;

FIG. 4 is a partial cross-sectional view illustrating air being applied prior to pressurizing the container sufficiently to initiate liquid transfer; and

FIG. 5 is a partial cross-sectional view illustrating liquid transfer after sufficient air pressure has been applied to pressurize the closed container in accordance with the invention.

DESCRIPTION

Referring now to the figures there is disclosed the apparatus of the invention and the manner in which it is utilized to transfer liquid from a first closed container to a second receiving container. Generally designated by the reference numeral 10, the apparatus provides a closed liquid interchange system utilizing only air pressure as the energy source for charging the system.

FIG. 1 is an exploded view of the apparatus 10 illustrating component parts of the invention. Shown is a generally flexible air inlet tube, generally designated 11, having an open end 11a for input of air under pressure, a check valve 11b for one-way passage of the pressurized air, and a connector/seal 12. As will be explained, upon operation of the system of the invention check valve 11b captures and holds applied air pressure thereby to pressurize the system to initiate gravity flow of liquid from a sealed container to another container. Inlet tube 11 transits through connector/seal 12 as indicated at 11c and enters connector 15 at opening 15a and then curved at an appropriate angle for extending downwardly of tee connector 15 through opening 15c to terminate at end 11d, end 11d curved and having an aperture for exhausting pressurized air from inlet 11a. Connector/seal 12 is configured for receiving tube 11 and mating with tee-like connector 15 at inlet 15a in a manner to provide an air tight seal. Pipe 19 has aperture 19a, rib 19b, top threaded portion 19c and bottom opening 19d. Further included are compression nut 17 and sealing member 18. Liquid outlet tube, generally designated 13, has a first end 13a attached to a connector/seal 14 for airtight mating with outlet 15b of tee-like connector 15, and a second end 13b attached to on-off valve 13c. An outlet tube 13d extends from valve 13c for insertion into a receiving container as is shown in FIG. 2. Thus, tee connector 15 has two female openings 15a and 15b for receiving compatible male portions of connector/seals 12 and 14, respectively, and a third opening 15c for receiving tube 11 and pipe 19. Input of pressurized air may be by a small bicycle pump or other suitable means. It is only necessary that sufficient air pressure is applied to initiate transfer flow of liquid up through pipe 19 and out of tee connector opening 15b and through outlet tube 13 on to the receiving container.

In assembly of apparatus 10 sealing member 18 is fitted over the threaded portion 19c of pipe 19 and firmly against pipe rib 19b. Compression nut 17 is then threaded onto threaded portion 19c of pipe 19 with threaded portion 19c then threaded into a receiving threaded portion (not shown) of opening 15c in a manner to provide an airtight seal. Pipe 19 is then inserted into the opening of container 20, as seen in FIG. 2, firmly seating sealing member 18 in the container 20 opening after which threaded compression nut 17 is tightened along threaded portion 19c and against sealing member 18 to effect an airtight seal. It is to be understood that other methods of compression sealing can be devised by those skilled in the art that would fall within the spirit and scope of the invention.

FIG. 2 is a perspective view illustrating the final assembly of apparatus 10 whereby liquid 22 is transferred from storage container 20 into receiving container 21, apparatus 10 installed onto container 20 in an airtight manner so to establish air pressure in container 20 sufficient to effect transfer of liquid in accordance with the invention. As indicated in phantom the lower portion of pipe 19 is immersed in liquid 22. End 19d is immersed to a sufficient depth for satisfactory operation of the invention.

FIG. 3 is a cross-sectional view taken along the lines 3-3 of FIG. 2 illustrating the gravity feed of liquid 22 in accordance with the invention. As indicated, air under pressure is forced into air inlet tube 11, through check valve 11b and tee connector 15 to be exhausted into the air space 23 of air-tight container 20 through outlet 16a, as indicated by the arrows, and above liquid 22. Pipe 19 is immersed in liquid 22 such that with adequate air pressure in airspace 23 liquid 22 is forced up pipe 19 and flows out of connector 15 and into outlet tube 13, also as indicated by arrows. As indicated in FIG. 3 portion 19c is can be fitted into opening 15c to provide an airtight seal. Further, connector/seals 12 and 14 may be pressure fitted or otherwise sealed into openings 15a and 15b, respectively. It is understood that other variations, modifications and embodiments can be devised by those skilled in the art that would fall within the spirit and scope of the invention.

FIG. 4 is a partial cross-sectional view of the invention illustrating pressurized air being applied into airspace 23 of container 20 prior to sufficient pressurized air being provided to initiate liquid transfer out of container 20 to container 22. The flow of pressurized air is through curved end 11a of tubing 11 which is inserted through pipe aperture 19a and into air space 23.

FIG. 5 is a partial cross-sectional view of the invention illustrating sufficient pressurized air having been applied to container 20 airspace 23 so as to initiate liquid transfer from container 20 to container 22. As indicated by the arrows the pressurized air has expanded air space 23 to force liquid 22 to flow up through pipe 19, through tee connector 15, and on through outlet tube 13 to the receiving container 21. After flow is initiated, the apparatus 10 acts as a siphon to continue transfer of liquid so long as sufficient air is allowed through one-way valve into airspace 23 and the separate container 22 is positioned with a drain located such that the gravity pressure of said liquid in said container maintains liquid transfer.

Thus, in accordance with the invention, pressurized air is forced through air inlet tube 11 into air space 23 of sealed container 20 to gradually increase the air space 23 until liquid 22 flows out of container 20 and into outlet tube 13 after which with valve 13c turned to the on position liquid flows into container 21 until either the valve 13c is turned off or the liquid 22 level gets below the inlet 19d of pipe 19.

There has been shown and described new and unique apparatus for gravity feed liquid transfer from a storage container to a receiving container. Although the invention has been described with reference to certain embodiments, other variations, modifications and embodiments can be devised by those skilled in the art that would fall within the spirit and scope of the invention.

Claims

1. A fluid handling system for movement of fluid from one container to a separate container, comprising: a container sealed and closed to the outside atmosphere for exchange of a liquid contained therein;input means to said container having one-way valve means for providing pressurized air to an air space above said liquid while maintaining closure of said system from the outside atmosphere;connecting means between said liquid and a separate container operable for removing said liquid from said sealed container to said separate container, said connecting means having a liquid input below the level of said liquid in said container; andsaid liquid is transferred from said container into +said separate container by air pressure provided through said input means into said air space in said container.

2. The system of claim 1 wherein said one-way valve means provides sufficient additional air to said air space in response to a liquid transfer created vacuum in said air space of said container to maintain liquid exchange between said container and said separate container.

3. The system of claim 2 wherein said connecting means further includes valve means selectively operable for exchanging said liquid between said container and said separate container.

4. The system of claim 3 wherein said separate container and said connecting means comprises a gravity drain positioned between said container and said separate container, said gravity drain characterized by positioning said separate container with a drain located such that the gravity pressure of said liquid in said container maintains liquid transfer from said container into said separate container.

5. A gravity feed liquid transfer system comprising: at least one sealed liquid sending container and at least one liquid receiving container;means for liquid exchange between said at least one sending container and said at least one receiving container;said means for liquid exchange including air pressure induced gravity feed exchange between said at least one sending container and said at least one receiving container; andwherein said at least one sending container contains both liquid and an air space above said liquid and means for increasing the volume of said air space thereby to induce simultaneous gravity feed liquid exchange between said at least one sending container and said at least one receiving container.

6. The system of claim 5 wherein each of said sending container and corresponding receiving container includes: intermediate connector means;an air inlet tube having an open end for input of air under pressure, a check valve for one-way passage of the pressurized air, and sealable means having an aperture for receiving said inlet tube therethrough and for airtight connection to a first opening of said intermediate connector means, said inlet tube transiting said sealable means and said intermediate connector to extend a selected distance from a second opening of said intermediate connector means to terminate in an air exhaust outlet;tubing means having a first end for sealable connection to a second opening of said intermediate connector means and for receiving said air inlet tube a selected distance therein, said tubing means including an aperture for receiving said air inlet exhaust outlet therethrough;a liquid outlet tube having a first end for airtight mating to a third opening of said intermediate connector means, an on-off valve, and an open terminating end; andsaid tubing means configured for liquid communication with said third opening and said liquid outlet tube.

7. The system of claim 6 further comprising: said at least one sending container includes liquid therein and an airspace above said liquid;means for sealable insertion of said tubing means wherein the other end of said tubing means and said exhaust outlet is below the surface of said liquid;means for providing air under pressure to said air space thereby inducing gravity flow of said liquid through said tubing means and into said outlet tube;said at least one receiving container for receiving liquid from said at least one sending container through said terminating end of said outlet tube; andwherein said check valve is a self-tending one-way valve for automatically providing additional air in response to any liquid transfer created vacuum in said air space of said at least one sending container.

8. A fluid transfer method of exchanging liquid in a closed system without exposing the liquid to the atmosphere, said method comprising the steps of: containing an air space above a liquid in a sealed sending container;providing a receiving container;interconnecting said sending container and said receiving container by a liquid conduit; andtransferring liquid from said sending container into said receiving container through said conduit in response to gravity flow induced by controllable increase of the volume of said air space in said sealed container.

9. The fluid transfer method of claim 8 wherein said liquid conduit comprises: intermediate connector means;an air inlet tube having an open end for input of air under pressure, a check valve for one-way passage of the pressurized air, and sealable means having an aperture for receiving said inlet tube therethrough and for airtight connection to a first opening of said intermediate connector means, said inlet tube transiting said sealable means and said intermediate connector to extend a selected distance from a second opening of said intermediate connector means to terminate in an air exhaust outlet;tubing means having a first end for sealable connection to a second opening of said intermediate connector means and for receiving said air inlet tube a selected distance therein, said tubing means including an aperture for receiving said air inlet exhaust outlet therethrough;a liquid outlet tube having a first end for airtight mating to a third opening of said intermediate connector means, an on-off valve, and an open terminating end; andsaid tubing means configured for liquid communication with said third opening and said liquid outlet tube.

10. The fluid transfer method of claim 8 further comprising: means for sealable insertion of said tubing means into said sending container wherein the other end of said tubing means and said exhaust outlet is below the surface of said liquid;means for providing air under pressure to said air space thereby inducing gravity flow of said liquid through said tubing means and into said outlet tube;at least one receiving container for receiving liquid from at least one sending container through said terminating end of said outlet tube; andwherein said check valve is a self-tending one-way valve for automatically providing additional air in response to any liquid transfer created vacuum in said air space of said at least one sending container.