AU3426489A

AU3426489A - Pressure supply unit

Info

Publication number: AU3426489A
Application number: AU34264/89A
Authority: AU
Inventors: Michael John Leslie
Original assignee: Dispak Pty Ltd
Current assignee: Dispak Pty Ltd
Priority date: 1988-10-07
Filing date: 1989-04-07
Publication date: 1990-05-01
Anticipated expiration: 2009-04-07
Also published as: AU621106B2

Description

PRESSURE SUPPLY UNIT

This invention relates to a pressure supply unit, more particularly for a unit to supply the pressure required for the dispensing of an aerosol or spray or stream from a closed container such as a can.

BACKGROUND OF THE INVENTION

In Australian Patent Application No. AU-A-78219/87 there is described a unit which will controllably release the gas from a pressurised bulb or the like, this release of pressure being controlled during the dispensing of the product from a can in which the unit is positioned.

Also there is known U.S. 4456155 for an aerosol spray device in which a gas bulb is positioned in the container, this being sealingly mounted within the container by being attached to an aperture in the bottom of the container, so that means can be available to hold the gas regulating position in an inoperative condition until the unit is inserted and the container sealed.

Japanese Patent No. 62066873 discloses a fire extinguisher which uses a gas bomb containing a mixture of nitrogen gas and carbon dioxide gas.

It is an object of this invention to provide a unit with the least number of parts and also it is a still further object to provide a unit which has the provision of a fail safe property, and is also self-regulating.

PRIEF STATEMENT OF THE INVENTION

Thus there is provided according to the invention a self-regulating pressure supply unit to supply a constant gas pressure to a point of use from a pressurised cylinder, said unit comprising a body attached to said pressurised cylinder and including a piston, a needle valve attached to said piston to regulate gas flow from said pressurised cylinder, said piston being attached to means for moving said piston, said means for moving said piston defining a wall of a chamber pressurised to said constant gas pressure, spring means and means to apply point of use pressure to said means for moving said piston, whereby a reduction in point of use pressure will move said means to move said piston due to differential pressure thereon.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more fully describe the invention, reference will now be made to the accompanying drawings in which :-

FIG. 1 is a cross-sectional view of one form of the invention in exploded form,

FIG. 2 is a cross-sectional view of the parts in assembled form,

FIG. 3 is a cross-sectional view of a further form of the invention in exploded form,

FIG. 4 is a view of the parts in assembled form, and

FIG. 5 is a part-sectional view in enlarged scale of the needle valve and the membrane on the gas bulb.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring firstly to FIG. 1 , there is shown a gas bulb 1 which may contain an inert gas such as carbondioxide, nitrogen or the like.

The unit 2 comprises a body 3, a piston 4 and a cap 5.

The body 3 includes a sleeve-like portion 6 which is shaped to engage the sides and neck 7 of the bulb, and is also provided with a stepped bore having a first bore 8 and a second bore 9 in which the piston operates, the piston having a first piston portion 10 operating in the bore 8, and a second piston portion 11 operating in the bore 9.

The first piston portion 10 has a skirt 12, this skirt being positioned facing toward the second piston portion 11 , and the second piston portion 11 has a skirt 13, this skirt 13 facing towards the first piston portion. Both these skirts are each similar to a cup or bucket washer.

The piston 4 has attached thereto in the first piston portion 10 a needle valve 14 which protrudes from the first piston portion to pierce the end membrane 28 of the bulb and also to seal on the so pierced membrane.

The body 3 also has in the vicinity of the end of the bulb 1 an aperture 15 opening from the interior to the outside thereof.

The end cap 5 has a recess 16 housing a spring 17 which acts on the second piston portion 11.

The unit 2 is assembled onto the bulb 1 and in doing so on insertion of the bulb 1 into the body 3 with the spring forcing the piston downwardly, the needle valve will pierce the sealing membrane of the gas bottle and due to the shape of the needle valve a small hole is formed, and in doing so the needle valve will deflect the membrane around the hole to form a flared hole in the membrane, the needle thus sealing against this flared portion.

By reference to FIG. 5 it will be seen that the needle 14 will pierce a flared hole 22 in the membrane 21 , and in so doing will deflect the edge portions 23 of the membrane 21 to form the flared hole 22, the needle valve 14 thus sealing on the flared edge portions 23. Suφrisingly it has been found that this forms an effective seal, the gas pressure within the bulb maintaining the flared portions 23 against the needle.

Also there are provided a plurality of whisker-like protrusions 20 which compress to fit through the 25mm0 neck of any aerosol can and expand inside the can to prevent any part of the body or cylinder coming into contact with the can or the aerosol outlet valve.

The unit and bottle is then positioned in the can containing the substance to be dispensed, and in this operation and during the sealing of the cap on the can, the can is pressurised to the desired operating pressure of the can. Upon the can being pressurised, this pressurising gas can enter through apertures 18, past the skirt 13 into chamber 19 formed beneath the second piston portion 11. Also some gas could pass through the aperture 15 and up past the skirt 12 in the first piston portion so that after a short period of time the chamber 19 is pressurised to the same pressure as the can so that the can pressure is acting both on the top and bottom of the second piston portion with the spring 19 assisting in closing of the needle valve 14.

Upon dispensing of the material, there will be an immediate reduction in pressure in the can, and thus a reduction in pressure on the surface above the second piston portion 11 , but due to the positioning of the skirts 12 and 13, there will be no reduction in pressure in the chamber 19, and thus this pressure acting on the bottom of the second piston portion 11 will cause the piston 4 to rise thus moving the needle valve 14 away from its seat and allowing gas from the bulb to escape through aperture 15 into the can. Upon the cessation of dispensing of the product, this gas escapes until the original pressure is achieved, that is equal to the pressure in the chamber 19, thus the can pressure then is operating on the top of the second piston portion 11 and this in conjunction with the force exerted by the spring, closes the valve. Hence the unit is self-regulating to the desired can pressure.

Turning now to FIGS. 3 and 4 there is shown a further embodiment of the invention.

The body 24 has a central bore 25 which opens into a larger bore 26, the larger bore 26 being adapted to receive the neck 27 of the gas bottle 28, a radial passage 29 opening into the top of the larger bore 26. The top of the body 24 has a peripheral flange 30 to seal with a peripheral flange 31 on a cap 32.

The cap 32 has a diaphragm or membrane 33 extending across its open end 34, and to the membrane 23 there is attached a piston 34. The needle valve 35 is fitted centrally on the piston 34 and protrudes from the end thereof. The end of the piston 34 is provided with a flexible extending skirt 36. The cap 32 also is provided with a spring 37 which is positioned within the cap to bear on the membrane 33 on the opposite side of the membrane to the piston 34. In the cap there is also a passage 38 which connects to space 39 above the membrane 32 to the interior of the can.

The body 24 and the cap 33 are each provided with flexible arms or fingers 40 to position and hold the unit and gas bulb 41 within the can.

When the unit is assembled the piston 34 is positioned in the bore 25, the skirt 36 folding back to form a cup washer as shown in FIG. 4. Hence once inserted and the unit is subject to the can pressure, the gas pressure will pass upwardly into the space 40 beneath the membrane 33. Hence this space 40 is then pressurised to the can pressure and thus this is the self-regulating pressure.

As there is can pressure on both sides of the membrane, then the spring will cause the needle to close the aperture formed in the metallic sealing membrane of the bulb.

On reduction of can pressure, as by operation of the dispensing valve of the can, there is thus a reduction of pressure on the spring side of the membrane, and as there is the higher can pressure on the piston side of the membrane, then the membrane moves upwardly against the spring pressure to cause the needle valve to open the aperture in the bulb to thus allow escape of gas. Hence it will be seen that the unit is self-regulating and will maintain the pressure in the can at the desired set pressure.

Thus, it will be seen that there is a self-regulating feature of the piston and valve, for example if the escape of gas from the bulb is greater than the rate to which the material is being dispensed, there will be a self- regulating feature of the valve. Also, due to the fact that the spring always tends to close the valve, there is a fail safe aspect of this construction.

Thus, it will be seen that with this construction that without any alterations at all, the unit is adapted to be suitable for the use and dispensing at various pressures, whether these be at 40 pounds per square inch, 60 pounds per square inch or 80 pounds per square inch, due to the fact that on assembly and with the pressurising of the can to the desired pressure, this desired pressure will cause the gas to pass the seals and thus pressurise the area of chamber 19 to the can pressure and then the unit always operates at this pressure.

It will be seen in this embodiment that care should be taken in the selection of the diameters of the two piston portions, the second piston portion or the top diameter being loaded to the power function, and the first piston portion or the bottom as shown in the drawings is related to the loss factor in the expanded mode and these diameters are so chosen so that the effective operation is achieved.

Thus, it will be seen that according to the invention there is provided a unit which is of minimum parts in its construction, and which thus allows the use of an aerosol dispenser with an inert gas, such as nitrogen, and which thus can be used with a variety of products to be dispensed.

Although this form of the invention has been described in some detail, it is to be realised that the invention is not to be limited thereto but can be varied within the spirit and scope of the invention.

Claims

1. A self-regulating pressure supply unit to supply a constant gas pressure to a point of use from a pressurised cylinder, said unit

5 comprising a body attached to said pressurised cylinder and including a piston, a needle valve attached to said piston to regulate gas flow from said pressurised cylinder, said piston being attached to means for moving said piston, said means for moving said piston dividing a wall of a chamber pressurised to said constant gas pressure, spring means 10 and means to apply point of use pressure to said means for moving said piston whereby a reduction in point of use pressure will move said means to move said piston due to differential pressure thereon.

2. A pressure supply unit as defined in claim 1 wherein said 15 point of use is the internal pressure of a can to dispense a product, and said pressure supply unit is inserted into said can whereby a reduction of the pressure in said can will cause said needle valve to open to release gas pressure into said can.

20 3. A pressure supply unit as defined in claim 2 wherein said unit comprises a body, a stepped bore having a large bore and a smaller bore in said body, said piston operating in said smaller bore, a passage through said body at said smaller bore to allow gas to pass from said pressurised cylinder to said can interior while acting on said piston end.

25

4. A pressure supply unit as defined in claim 3 wherein said piston has a one way sealing means to permit pressure in said can to pass into said chamber to pressurise and maintain the pressure in said chamber.

30

5. A pressure supply unit as defined in claim 2 wherein said piston is connected to a further piston acting in said larger bore, said larger piston having sealing means to seal against the larger bore.

/) 35 6. A pressure supply unit as defined in claim 5 wherein said sealing means is a one way sealing means to allow passage of gas into said chamber, said larger piston forming the means for moving said piston.

7. A pressure supply unit as defined in claim 3 wherein said unit includes a cap to attach on said body, spring means acting between said cap and said means to move said piston, and a passage connecting said cap interior to the pressure within said can.

8. A pressure supply unit as defined in claim 3 wherein said piston has a one way sealing means to permit pressure in said can to pass into said chamber to pressure and maintain pressure in said chamber, said piston being connected to a diaphragm in a cap attached to said body to form said chamber.

9. A pressure supply unit as defined in claim 8 wherein said cap has an aperture opening to the can interior and to the diaphragm opposite to said chamber.

10. A pressure supply unit as defined in claim 8 wherein a spring is positioned in said cap to act on said diaphragm on the side opposite said chamber.

11. A pressure supply unit as defined in claim 1 wherein said needle valve pierces a metallic ceiling membrane on said pressurised cylinder to form a flared aperture, said needle valve sealing on said flared aperture.

12. A pressure supply unit substantially as hereinbefore described within reference to and as illustrated in the accompanying drawings.