ES1188610U - Gas cylinder (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Gas cylinder comprising a body (1), a piston (2) that moves longitudinally inside the body (1) in both directions, and a compressible gas inside the body (1), in a chamber (10) under the piston (2), the body (1) comprising at least one transverse hole that communicates the interior of said body (1) with the outside of said body (1), characterized in that the cylinder (100) comprises a solid python (3) partially housed in the transverse hole and a sealing gasket (4) between the python (3) and an internal surface (12) of the body (1), the python (3) comprising at least one fin (30)) which is arranged outside the transverse hole and inside the chamber (10) of the body (1) and the sealing gasket (4) being arranged in said chamber (10) held in position between the wing (30) and the inner surface (12) of the body (1), the fin (30) being configured to deform or break from a certain pressure of the compressible gas inside the chamber (10).

Description

DESCRIPTION

Gas cylinder

SECTOR OF THE TECHNIQUE 5

The present invention relates to gas cylinders or dampers.

PREVIOUS STATE OF THE TECHNIQUE

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A gas cylinder comprises a body, a piston movable in the body, in both directions, and a chamber inside the body and under the piston comprising a compressible gas.

The gas is progressively compressed as the piston travels in its stroke. 15 Normally these cylinders are rated at a maximum gas pressure, which is defined according to the required maximum stroke of the piston, for example. For different reasons this pressure can be exceeded, which can be dangerous if the relevant measures or securities are not taken.

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Solutions are known where to avoid this problem the chamber is provided with a safety valve that is actuated by the piston itself. The safety valve is arranged in a certain place, so that it is actuated by the piston when it passes the maximum stroke for which it is defined. This action causes gas to escape through said valve. 25

In some cases the safety valve is arranged at the bottom of the chamber, which forces the piston to travel through the entire chamber possible within the chamber to reach the safety valve, then being supported or, at best cases, close to the bottom of said chamber. With this arrangement of the valve, the piston can be struck on the bottom of the chamber, with the problems that this can cause.

In the patent document ES2219160A1 a piston with a safety valve is disclosed, which is actuated by the piston. However, in this case the safety valve

It is arranged on a wall of the body (of the chamber), instead of at the bottom.

EXHIBITION OF THE INVENTION

The object of the invention is to provide a gas cylinder, as defined in the 5 claims.

The gas cylinder comprises a body, a piston that travels longitudinally inside the body in both directions, and a compressible gas inside the body, in a chamber under the piston, and the body comprises at least one transverse hole that 10 communicates the inside of said body with the outside of said body.

The cylinder comprises a solid python housed in the transverse hole, and the python comprises at least one fin disposed in the body chamber and a sealing gasket disposed in said gap between the fin and an internal body surface and held in position by the fin. The fin is designed to deform or break from a certain pressure of the compressible gas inside the chamber.

In this way, security is provided against over pressures in the cylinder body, in a simple manner. When there is an over pressure, the gas pressure 20 itself causes the fin to break, and as a result the sealing gasket is no longer held against the cylinder body and a tight seal between the python and the transverse hole is no longer provided. . When a sealed seal is no longer provided, the gas begins to evacuate from the chamber through said transverse hole, resulting in a decrease in the pressure of said gas in said chamber, avoiding the risk of the body exploding by 25 over pressures of gas.

Additionally, this does not require a piston to act on any element to cause the gas to escape, so the proposed safety is effective for any type of overpressure, whatever the reason (and not just for over stroke as occurs in the 30 state of the technique, where the action of the piston is necessary), and, in addition, the piston is disconnected from the proposed safety and it is no longer necessary, contrary to what happens in the state of the art, to make the provision of the transverse hole exactly the position of the piston when it exceeds its maximum stroke (for example, the transverse hole could be

dispose in any position below said maximum stroke, and not in a given one). The latter also makes the implementation of the security of the invention simpler than that of the state of the art in any of the cases.

These and other advantages and features of the invention will become apparent in view of the 5 figures and the detailed description of the invention.

DESCRIPTION OF THE DRAWINGS

Figure 1 shows a sectional view of an embodiment of the gas cylinder of the invention, without overpressure.

Figure 2 shows the detail A-A of figure 1.

Figure 3 shows a sectional view of the gas cylinder of Figure 1, with overpressure. fifteen

Figure 4 shows the detail B-B of Figure 3.

DETAILED EXHIBITION OF THE INVENTION

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As shown in the figures, the gas cylinder 100 comprises a preferably metal body 1, a piston 2 that travels longitudinally inside the body 1 in both directions, and a compressible gas inside the body 1, in a chamber 10 under the piston 2. As the piston 2 advances towards the bottom 15 of the chamber 10 the gas is compressed, and decompresses when the piston 2 moves back away from said bottom.

The body 1 comprises at least one through transverse hole that communicates the inside of said body 1 with the outside of said body 1, which is made in one of the axial walls of the body 1, said transverse hole extending from an internal surface 12 30 of the body 1 to an external surface 14 of said body 1.

The cylinder 100 further comprises a solid python 3 shown in more detail in Figures 2 and 4, which is housed in the transverse hole, and a seal 4 between

the python 3 and an internal surface 12 of the body 1. The python 3 preferably comprises, at one end, at least one fin 30 which is arranged outside the transverse hole and inside the chamber 10 of the body 1, and the seal 4 it is arranged in said chamber 10, held in position between the flap 30 and the internal surface 12 of the body 1. The sealing gasket 4 provides a tight seal between the python 3 and the body 1, preventing the gas from the chamber 10 evacuate or escape through the transverse hole.

The flap 30 is designed to deform or break from a certain pressure of the compressible gas inside the chamber 10 (situation shown in Figure 4). If, for whatever reason, the pressure of the gas inside the chamber 10 reaches said determined pressure 10, the fin 30 deforms or breaks and stops holding the seal 4 against the internal surface 12 of the body 1 of the cylinder 100. When the fastener is lost, the seal 4 also loses its position, and the passage of gas is allowed through the transverse hole 4, which is no longer closed tightly. Thus, in spite of the presence of the python 3, part of the gas present in the chamber 10 begins to escape from said chamber 10 through 15 through the outlet opening, reducing the pressure of the gas present in the chamber 10, thus providing security against over pressures to cylinder 100 in a simple way. The gas leak is represented by arrows G in Figure 4.

The width and / or height of the transverse hole is greater than the width and / or height of the part 20 of the python 3 that crosses said transverse hole, such that the passage of gas through the transverse hole is allowed, between said hole transverse and the python 3. Preferably, the python 3 comprises a cylindrical body from which the flap 30 protrudes, said cylindrical body passing through the transverse hole and said cylindrical body comprising a diameter smaller than the diameter of the transverse hole. 25

The python 3 crosses the entire transverse hole and protrudes from the outside of an external surface 14 of the axially extending body 1. Thus, the python 3 is accessible from the outside of the cylinder 100. This allows to measure the pressure of the gas inside the chamber 10 from the outside in a simple manner, acting on the part of the python 3 that protrudes 30 by, for example, , a pressure gauge.

The cylinder 100 further comprises a safety element 5 that surrounds part of the area of the python 3 that protrudes outside the body 1, said element protruding from

security 5 of said python 3 and said security element 5 being attached to said python 3. Python 3 may comprise a slot for partially accommodating security element 5, or said security element 5 can be arranged on said python 3. The safety element 5 allows to measure the pressure inside the chamber 10 in a safe way, since it prevents said python 3 from entering the chamber 10 due to an action on it 5 during said measurement (pressure gauge action, for example).

Preferably, the body 1 comprises a recess 13 on its axial outer surface 14, the transverse hole being communicated with said recess 13 and the python 3 protruding from the outside of said outer surface 14 in said recess 13, up to a maximum height 10 of the rest of the outer surface 14. In this way the python 3 does not protrude from the body 1 and is more protected.

Preferably the python 3 is metallic, but it could also be plastic, for example.

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Claims (10)

1. Gas cylinder comprising a body (1), a piston (2) that travels longitudinally inside the body (1) in both directions, and a compressible gas inside the body (1), in a chamber (10) under the piston (2), 5 the body (1) comprising at least one transverse hole that communicates the inside of said body (1) with the outside of said body (1), characterized in that the cylinder (100) comprises a solid python (3) partially housed in the transverse hole and a seal (4) between the python (3) and an internal surface (12) of the body (1), the python (3) comprising at least one fin ( 30) which is arranged outside the transverse hole 10 and inside the chamber (10) of the body (1) and the sealing gasket (4) being arranged in said chamber (10) held in position between the fin (30) and the internal surface (12) of the body (1), the fin (30) being configured to deform or break from a certain pressure compressed gas inside the chamber (10).  fifteen 2. A gas cylinder according to claim 1, wherein at least the part of the python (3) housed in the transverse hole is cylindrical and comprises a diameter smaller than the diameter of the transverse hole. 3. Gas cylinder according to claim 1 or 2, wherein the python (3) crosses the entire transverse hole and protrudes from the outside of an external surface (14) of the body (1) extending axially, said python being left (3) accessible from the outside of the cylinder (100). 4. A gas cylinder according to claim 3, wherein the body (1) comprises a recess 25 (13) on its outer surface (14) towards the chamber (10), the transverse hole being communicated with said recess (13) and the python (3) protruding from the outside of said body (1) in said recess (13) up to a maximum of the height of the rest of the external surface (14).  30 5. A gas cylinder according to claim 3 or 4, comprising a safety element (5) that is attached to the area of the python (3) that protrudes outside the body (1), and which protrudes from a surface of said Python area (3) such that it hits the outer surface (14) of the body (1) if the python (3) tends to move towards the camera (10), preventing said security element (5) said displacement. 6. A gas cylinder according to claim 5, wherein the safety element (5) is a circlip that is wound on the python (3).  5 7. A gas cylinder according to claim 6, wherein the python (3) comprises a groove in the perimeter zone in the area that protrudes outside the body (1), the circlip being housed in said groove. 8. A gas cylinder according to any one of claims 1 to 7, wherein the python is cylindrical, the fin (30) being at one end of said python (3). 9. Gas cylinder according to any one of claims 1 to 8, wherein the python (3) is metallic.  fifteen 10. Gas cylinder according to any one of claims 1 to 8, wherein the python (3) is made of plastic.