DE3806991A1 - Propellent gas pressure container - Google Patents

Abstract

Propellent gas pressure container, in particular for use in a device according to the German Patent Application P 3716377.9 for delivering liquid, spray-like, foamed, pasty, slurried or emulsified substances using a pressurised gas, such as compressed air, as the delivery medium by means of an actuable pressure valve, characterised in that there are provided inside the pressure container a propellent liquid which produces internal pressure when evaporated and a compressed-gas space which is separated therefrom in a gas-tight manner, and in that the gas-tight separation within the interior of the pressure container can be shifted or moved in such a way that the volume of the space containing the propellent liquid (e.g. propellent- gas chamber) and the volume of the compressed-gas space (e.g. compressed-gas chamber) can be varied in a complementary manner depending on the degree of filling of the compressed-gas space, and in that the pressure valve communicates with the compressed-gas space. <IMAGE>

Description

The invention relates to a propellant gas pressure container, in particular for use in a device according to the German patent application P 37 16 377.9 for discharge liquid, spray-like, foamed, pasty, using slurried or emulsified substances a compressed gas such as B. compressed air as discharge medium by means of an actuatable pressure valve.

The object of the invention is to provide an improved LPG pressure tank, which also with a Device according to patent application P 37 16 377.9 is usable, d. H. with the combination of a compressed gas or compressed air charging station, by means of a propellant gas pressure vessel either via separate check valves as a compressed gas outlet-inlet valve combination or via the actual compressed gas outlet valve in a two-way combination especially steadily under gas or air pressure kept charged ready for use.

Accordingly, the invention consists in a propellant gas pressure vessel of the type mentioned, which thereby is characterized in that within the pressure vessel generating an internal pressure under evaporation LPG liquid and a gas-tight one separated from it Compressed gas space is provided and that the gas-tight Separation within the pressure vessel interior  is displaceable or movable that the volume of the LPG liquid contained space (e.g. LPG chamber) and the volume of the compressed gas chamber (e.g. compressed gas chamber) depending on the degree of filling of the compressed gas space are complementarily changeable, and that the pressure valve communicates with the compressed gas chamber.

In principle, chlorofluorocarbons could also be used as the propellant be used because of this included in the propellant gas chamber according to the invention remain or not when dispensing the spray can contents be sprayed with. But also releasing this LPG if the LPG chamber is damaged or with Disposed spray cans can be avoided by using it as a propellant for example a mixture of hydrocarbons is used with which in a butane-propane mixture a propellant pressure between 1.3 bar (pure butane) and about 8 bar (pure propane) is adjustable, whereby these values with changed ambient temperature vary.

Such a hydrocarbon mixture corresponds to that with regard to using the invention on economically optimal way intended avoidance of the Substances harmful to the ozone layer (CFCs), however easily combustible and when spraying from aerosol cans dangerous and also causes intensive inhalation health damage. In the propellant gas pressure vessel according to the invention these disadvantages are avoided.

If - as preferred - the LPG liquid in one Amount is provided, which is practical in their  complete evaporation for their gas expansion predetermined volume or this amount only exceeds little, then that is usually enough to the air pushed out of the pressure vessel (or another compressed gas) from the full air pressure charge state up to the state emptied of compressed air that of the propellant gas to maintain fully developed pressure. On the other hand, this amount of propellant gas is small enough to additional explosion protection if the level is too high Ensure temperature. This applies in particular to the transport and storage, which without compressed air charging can be done.

Air is normally used as the compressed gas, possibly also dried air used; but can also be used as compressed gas using a gas - or adding additives to the air - be what the property of the discharged substance affected during or after discharge. At the the easiest is with scented compressed air, yes is also the use of CO₂ or other gases Hardening of multi-component plastics in the Scope of the invention.

Although for the separation of pressurized gas and Propellant a piston-cylinder or z. B. a bellows construction can be used is an optimally simple one Execution of the propellant gas pressure vessel according to the invention given when the gas-tight separation is flexible Wall is what is at a high degree of filling Pressurized gas chamber (compressed gas chamber) maximum over almost the entire pressure vessel interior extends or that Volume on the LPG side almost filled.  

The preferably as a gas-tight separation between LPG and compressed gas chamber membrane used with its edge gas-tight in the lid attachment of the Compressed gas container clamped or also according to the invention attached elsewhere in the pressure vessel interior be, each covering the entire interior removable and also in a compressed position is compressible. Also an education as expandable bladder works according to the invention. The other way around, the propellant gas can be in one completed bubble included.

If the wall of the pressure gas container at least in the area wetted by the LPG liquid consists of metal according to the invention, then a good one Heat transfer and one favored by the hand warmth Given evaporation. Conversely, in this area Pressurized gas containers also during the pressure loading and storage process e.g. B. simply be cooled by water.

The substance to be discharged can be in one in Pressurized gas container or detachably attached space be included. In the latter case, different Cloth container or can parts on one and the same Pressure vessels are placed and these can parts too be refillable. When putting on a can part this automatically via a non-return pressure valve trained compressed gas outlet valve connected so that the fabric from one on the can part Discharge valve can be removed at hand or finger pressure.  

The pressure gas chamber is filled according to the invention either by a separate (e.g. laterally arranged) pressure gas inlet valve in the wall or Lid area of the pressure vessel or - if removable Can part - directly through with the compressed gas chamber the canister part connecting compressed gas outlet valve. At Can part firmly connected to the compressed gas chamber the actuating pressure also the compressed gas outlet valve opening material discharge valve by means of a Device converted to compressed gas inlet valve will.

The invention is in exemplary embodiments below described in more detail.

It shows

Fig. 1 shows a longitudinal section through a propellant gas pressure vessel with a schematic representation of individual features,

FIG. 2 shows a modification of the propellant gas pressure container according to the invention shown analogously to FIG. 1,

Fig. 3 is an illustrated according to the previous figures further modification of the blowing gas pressure container according to the invention,

FIG. 4 shows an enlarged section of the discharge valve area of the embodiment according to FIG. 3 and

FIGS. 4a and 4b is a schematic sectional view according to line II in Fig. 4.

In accordance with Fig. 1 to 3 shown propellant gas pressure container 1 has a pot-shaped, preferably made of metal base 2, a separate so that a gas-tight cover associated 3 and surrounds with its wall 4 an inner space 7 which is gas-tight by means of a flexible membrane 8 in two mutually Chambers is divided, one of which is provided as a propellant gas chamber 5 and the other as a compressed gas chamber 6 .

The flexible membrane 8 consists of a flexible or foldable or crushable material and is fastened on its lateral edge 10 according to FIGS. 1 and 2 with the fastening 10 of the cover 3 clamped on the pot-shaped lower part 2 . According to FIG. 2, 3, the cover of the propellant gas pressure container 1 made of a likewise cup-like upper part 13 which, if necessary, both (shown schematically) by means of bent-over at the edge of the bottom part 2 and at the edge of the upper part 13 flanges 12 by means of an also optionally releasable clamping ring 11 are connected to one another in a gastight manner.

The membrane 8 according to FIG. 2 is clamped in the fastening 10 between the flanges 12 .

In Fig. 3, the membrane 8 is clamped with its edge between the flanges 12 located at the edge of the lower part 2 and at the lower edge of a can part 14 arranged above it, specifically below the cover 3 , which is also fastened between the flanges 12 and which also serves as the bottom of the Can part serves.

The flexibility or crushability or slippability of the flexible membrane 8 and / or its stretchability is designed such that it is practically completely displaceable or foldable into the lower part 2 as shown in FIGS . 1 and 3 or alternately in accordance with FIG Lower part 2 or the upper part 13 is displaceable, in accordance with the alternative positions a and b shown in FIGS. 1 to 3.

In the propellant gas chamber 5 there is a medium as the propellant gas or propellant gas liquid 9 which forms a liquid gas transition phase in the region of the common ambient temperature of the human being, in which it liquefies under the action of pressure, but maintains a certain gas pressure. The propellant gas thus acts on the compressed gas as a 2-phase compression spring.

Chlorofluorocarbons are known as such media in conventional spray cans. Preferably, however, z. B. a butane / propane mixture can be provided, the partial gas pressure in the aforementioned ambient temperature range depending on the mixing ratio between 1.3 to 1.4 bar (pure butane) and 7.8 to 8.2 (8.0) (pure propane) is adjustable. The amount of propellant gas in the propellant gas chamber is to be chosen as far as possible so that with full expansion in the interior 7 there is no or only a small liquid phase remaining.

A material which is chemically resistant to the propellant gas mixture used in each case (for example rubber, plastic, etc.) is used as the material for the flexible membrane 8 .

While the propellant gas chamber 5 filled with propellant gas 9 is completely self-contained, the pressurized gas chamber 6 according to FIGS. 2 and 3 is provided with a pressurized gas inlet valve 15 which is designed as a check valve and through which not only the volume of the pressurized gas chamber 6 but also practically the entire inner space 7 shielded from the flexible membrane 8 against the propellant gas 9 is preferably filled with air under the pressure of a gas. The propellant gas 9 liquefies and the propellant gas chamber 5 practically shrinks to the volume filled by the liquid phase of the propellant gas. The filling pressure for the compressed air gas must therefore significantly exceed the safety pressure specifically set by the propellant gas mixture.

Metal can be of particular functional advantage as the material of the lower part 2 because it conducts heat well. Otherwise, pressure-resistant plastic can also be used as the material of the propellant gas pressure vessel 1 .

The substance 16 to be discharged from the air pressure is contained in the can part 14 , which according to FIGS . 1 and 2 is separated from the actual propellant gas pressure vessel 1 via e.g. B. rotary or turnbuckles 17 can be fixedly attached over the pressure vessel 1 .

The can part 14 is placed with its interior by actuating a compressed gas outlet valve 18 with its interior 20 under the pressure in the pressure vessel 1 and remains ( Fig. 1 and 2) by the open position 19 of the outlet valve 18 under this pressure. If an air tube 21 is provided, the air is passed into the space 22 via the material to be discharged. Under the constant air pressure originating from the pressure container within the can part 14 , the material 20 is discharged through the discharge spray can 25 by manual actuation of a discharge valve 24, if necessary through a riser pipe 23 , with clean air.

By continuously maintained partial pressure of the propellant gas 9 this pressure remains constant up to the emptying of the pressurized gas chamber. 9

In Fig. 3, the can part 14 is firmly connected to the propellant gas pressure vessel 1 , the lid 3 of which simultaneously forms the bottom of the can part 14 . The pressurized gas is filled via a pressurized gas filler neck 26 which projects through the interior 20 of the can part 14 to the pressurized gas inlet valve 15 .

The removal of the substance takes place via a z. B. finger pressure operated discharge valve 25 , with which the compressed gas outlet valve 18 is opened. The valve tappet 28 is formed coaxially double-walled, so that the compressed air passes through the duct 28 via the substance 16 into the interior 20 (through openings 30 ) (arrow 31 ) and the substance 16 to be discharged through a discharge duct 32 through removal openings 33 , which the Bridge the compressed air duct 29 and are arranged near the bottom 3 , press to the discharge spray nozzle 27 according to the arrows 34 .

The flexible membrane 8 can also be formed within the interior 7 as a bladder, which is attached to the wall 4 or the cover 3 with its throat around the compressed gas outlet valve 18 .

The membrane 8 can also be designed as an all-round gas-tight bubble within which the propellant gas is provided, so that the bubble z. B. can expand fully into the interior 20 in a ball shape.

The propellant gas pressure vessel can be charged preferably using a compressed air charging station, which is structurally simple and for a charging process is dimensioned for a long time, the propellant gas pressure vessel about self-employed Compressed air valves connected to the charging station for a long time and constantly charged for location-independent use is available.

The pressure vessel is charged by compressed air either by connecting the compressed air charging station to the compressed gas outlet valve 18 (FIGS . 1 and 2), by a separate compressed gas inlet valve 15 ( FIG. 2), by a compressed gas filler pipe 26 connected via a compressed gas filler neck 26 . Inlet valve 15 ( Fig. 3) or, as indicated in Fig. 4a or 4b, by dividing the air duct 32 into longitudinal passages a and b by rotation, this only schematically represented device 36, the discharge spray nozzle 25 from a removal nozzle to compressed air -Fülldüse converted, so that the removal of the compressed air and their replenishment is also possible in the embodiment of FIGS. 3 and 4 with one and the same gas pressure valve 18.

Reference symbol list

1 LPG pressure tank
2 pot-shaped lower part
3 lids
4 wall
5 LPG chamber
6 compressed gas chamber
7 interior
8 flexible membrane (alternative positions a and b)
9 LPG liquid
10 attachment
11 (clamping) ring
12 flanges
13 pot-like top
14 can part
15 compressed gas inlet valve
16 material to be discharged (liquid, foamed or pasty)
17 twist lock or turnbuckle
18 compressed gas or exhaust valve
19 open position of 18
20 interior
21 air tube
22 room over 16
23 riser
24 discharge valve
25 discharge spray nozzle
26 compressed gas filler neck
27 discharge spray nozzle
28 valve lifters
29 compressed air duct
30 openings
31 arrows
32 discharge channel
33 removal openings
34 edge of the membrane
35 Inside of the pressure tank
36 Device for repurposing

Claims (16)

1. propellant gas pressure vessel, in particular for use in a device according to the German patent application P 37 16 377.9 for discharging liquid, spray-like, foamed, pasty, slurried or emulsified substances using a compressed gas such as. B. compressed air as a discharge medium by means of an actuatable pressure valve, characterized in that a propellant gas liquid ( 9 ) generating an internal pressure under evaporation and a gas-tightly separated compressed gas space ( 6 ) is provided within the pressure vessel ( 1 ) and that the gas-tight separation within the pressure vessel Interior ( 7 ) is displaceable or movable in such a way that the volume of the space containing the propellant gas liquid (e.g. propellant gas chamber 5 ) and the volume of the pressurized gas space (e.g. pressurized gas chamber 6 ) are complementarily changeable depending on the degree of filling of the pressurized gas space, and that the pressure valve (18/24) communicates with the compressed gas chamber in connection. 2. LPG pressure vessel according to claim 1, characterized in that a hydrocarbon or a mixture of at least two hydrocarbons, for example of butane and propane, is used as the propellant gas liquid ( 9 ). 3. propellant gas pressure vessel according to claim 1 or 2, characterized in that the propellant gas liquid ( 9 ) is provided in an amount which, when practically completely evaporated, corresponds to the volume predetermined for its gas expansion, preferably only slightly exceeding this amount. 4. propellant gas pressure vessel according to one of claims 1 to 3, characterized in that air, also dried air, is used as the compressed gas in the compressed gas chamber ( 6 ). 5. propellant gas pressure vessel according to one of claims 1 to three, characterized in that a gas is used as the pressurized gas in the pressurized gas chamber ( 6 ), which cooperates with the discharged substance and affects its property in the discharged state. 6. LPG pressure vessel according to one of claims 1 to 5, characterized in that the gas-tight separation is a flexible wall (z. B. membrane 8 ), which is at a high degree of filling of the pressure gas chamber (pressure gas chamber 6 ) maximum over almost the entire pressure vessel - Interior ( 7 ) extends or almost completely fills the propellant gas chamber ( 5 ). 7. LPG pressure vessel according to one of the preceding claims, characterized in that the flexible wall (membrane 8 ) with its edge ( 34 ) along the inside ( 35 ) of the pressure vessel interior ( 7 ) is gas-tight. 8. propellant gas pressure vessel according to one of the preceding claims, characterized in that the flexible wall (membrane 8 ) in the other area of the pressure vessel interior ( 7 ) can be put out. 9. LPG pressure vessel according to one of the preceding claims 1 to 3, characterized in that the flexible wall (membrane 8 ) is designed as an expandable or compressible bladder, the access opening of which is arranged around the pressure valve ( 18 ). 10. LPG pressure vessel according to one of the preceding claims 1 to 5, characterized in that the propellant gas liquid ( 9 ) is provided within an expandable or compressible bladder arranged in the interior of the pressure vessel ( 7 ). 11. Propellant gas pressure vessel according to one of the preceding claims, characterized by a device ( 36 ) for converting the pressure valve ( 18 ) from a pressure gas outlet valve which can be triggered at the push of a button to a pressure gas inlet valve. 12. LPG pressure vessel according to one of the preceding claims, characterized in that within the propellant gas pressure vessel ( 1 ) a space ( 20 ) is provided which has the substance to be discharged ( 16 ) and which with the compressed gas valve ( 18 ) in the discharge position in Connection is established. 13. LPG pressure vessel according to claim 1 to 12, characterized in that the substance to be discharged ( 16 ) in the space ( 20 ) can be refilled. 14. LPG pressure container according to claim 1 to 10, characterized in that the space ( 20 ) of the propellant gas chamber ( 5 ) and of the compressed gas chamber ( 6 ) is arranged separately. 15. propellant gas pressure vessel according to claim 1 to 12, characterized in that the space ( 20 ) for the substance to be discharged ( 16 ) is arranged outside the pressure vessel ( 1 ). 16. LPG pressure vessel according to claim 15, characterized in that the space ( 20 ) for the substance to be discharged ( 16 ) on the pressure vessel ( 1 ) is releasably attached, the pressure valve ( 24 ) with the propellant gas pressure vessel via a non-return pressure valve ( 18 ) is connectable.