SAFETY DEVICE AGAINST EXCESS TEMPERATURE

Abstract

The invention relates to a safety device for containers loaded by gas pressure. Said safety device (1) for containers pressurized with gas, in particular for safeguarding the gas side of the working chamber of hydropneumatic apparatuses, such as hydraulic accumulators, comprising a relief apparatus (2) for reducing an elevated gas pressure in the particular container (3), caused by the influence of heat. is characterized in that the relief apparatus (2) is a component (4) that is loaded under the influence of a shear force or compressive force, the shape change of said component under the influence of heat on the safety device (1) in a space (5) closed to the outside occurring in such a way that a fluid-conducting connection (6) from the inside of the container (3) to the outside in the direction of the surroundings is enabled.

Description

The invention relates to a safety device for gas-pressurized containers, in particular for safeguarding the gas side of the working space of hydropneumatic devices, such as, for example, a hydraulic accumulator.

In order to ensure the safe operation of devices with containers containing a pressurized gas, such as hydraulic accumulators, among other things, all risks which can arise at the installation site of these devices must also be considered, with possible hazardous external effects being important, especially temperature spikes that occur in a fire in the immediate vicinity of these gas-pressurized containers and that can lead to the failure of the container.

DE 32 19 526 A1 discloses a safety device for these pressure vessels, in particular for lightweight, metal pressure vessels for liquefied gas, with the safety device being formed essentially by a fusible screw which has been screwed in a flange of the pressure vessel. The fusible screw contains a metal alloy with a low melting point, with the metal alloy being disposed in an exit channel for pressurized liquefied gas. The fusible alloy is covered by a metal foil which ensures tightness during alternating loads in operation of the pressure vessel.

In normal operation, the safety device is disposed in a region that is surrounded by fluid so that its temperature is defined. In the event of a fire, it can be assumed that the liquefied gas will undergo transition into the gaseous phase and the fusible alloy will thus be heated, as a result of which pressure equalization to the outside is enabled. An explosion of the pressure vessel is avoided in this way; however, the vicinity of the pressure vessel can be adversely affected or endangered by the rapidly emerging hot and liquid fusible alloy.

U.S. Pat. No. 6,367,499 B2 discloses a safety device for pressure vessels which is disposed in a relief opening of a gas pressure vessel, where there is a piston-like closure element which is disposed axially in an outflow opening from the gas pressure vessel to the outside with an energy storage mechanism for purposes of opening of the outflow opening. The closure element is pressed against a stop of fusible material. The stop thus constitutes a heat-sensitive relief device. Under the action of heat, the molten material of the stop can escape radially from the safety device so that the closure element clears the outflow opening. A radial escape of the fusible material constitutes a safety increase in the known safety device.

On the basis of this prior art, the object of the invention is to devise a safety device for gas-pressurized containers which, when activated, does not constitute a hazard for the vicinity and which has a simple structure.

This object is achieved according to the invention by a safety device having the features specified in claim 1 in its entirety.

An important particularity of the invention resides in the fact that the relief device which is formed from a heat-sensitive material is disposed in a closed space of the safety device, through which space, exhibiting an opening, none of the material of the relief device can flow.

This design measure prevents a risk to the vicinity of the safety device due to the molten material of the relief device. Moreover, the relief device is pretensioned with shear, preferably for buckling or bulging, so that in principle melting of the relief device is not necessary to clear an outflow opening which is closed by the safety device. Softening is thus sufficient. The dimensioning of the space which surrounds the relief device first enables a buckling or bulging of the relief device. The safety device according to the invention, however, also works when the relief device were to melt at elevated ambient temperature. In this case, due to the indicated pretensioning and the associated shear forces, the relief device in turn clears the outflow opening which is closed in the normal operating state of the vessel. This melting away can be expected especially when the relief device consists of a plastic material with a low melting point. If a ceramic material or a metal material, even in the form of a bimetal, is used for the relief device, it can rather be expected that buckling or bulging of the relief device will occur with subsequent clearance of the outflow opening as a result of the pretensioning.

The relief device is exposed to shear in the sense of pretensioning by a component which preferably directly closes a fluid-conducting connection (outflow opening). No additional energy storage mechanism which pretensions the relief device is necessary since the gas within the container alone pressurizes the relief device. The component which closes the drain opening is held in position on the drain opening, secured with a sealing means, so that even in the unmounted state, not pressurized by gas, the safety device can be handled and in particular can be mounted without limitation. Under the action of heat, the relief device deforms preferably along one axis of symmetry, and the component which closes the outflow opening can be moved axially within the safety device and can clear the drain opening. The space, which has several times the volume of the relief device, allows this reforming of the relief device in the sense of softening or melting.

The relief device is preferably formed from a plastic body which can deform or melt away under the action of heat, as described. Depending on the pressure to be maintained in the pertinent container, it can be feasible to choose a fluoroplastic, in particular a polyvinylidene plastic such as polyvinylidene fluoride, with a continuous working temperature range of from −30° C. to +140° C. or polyvinyl fluoride with a continuous working temperature range of from −70° C. to +110° C.

The relief device can be a rod-shaped plastic part which is stressed for buckling or bulging, or a cylindrical one, in the sense of a plastic part which is designed as a hollow cylinder.

In order to ensure reliable response of the relief device to heat, it is feasible to choose the space around the relief device to be about four times as large as the volume occupied by the relief device itself.

The invention is detailed below using one exemplary embodiment which is shown in the drawings.

FIG. 1 shows a schematically simplified longitudinal section of a hydropneumatic piston accumulator provided with a safety device according to the exemplary embodiment shown in FIG. 2;

FIG. 2 shows a longitudinal section through a safety device according to the application as shown in FIG. 1.

FIG. 1 shows, in a schematic longitudinal section, not to scale, a container 3 which constitutes a hydraulic accumulator in the form of a piston accumulator in a conventional design. The hydraulic accumulator is provided with a hollow cylindrical accumulator housing 10 which is closed pressure tight on the end sides by one cover 11 and one cover 12. A cup-like piston 13 which can move axially in the accumulator housing 10 separates a fluid side, in particular oil side 14, from a gas side 15. The oil side 14 can be connected in the conventional manner to a hydraulic system, not shown., via an oil port 17 which is coaxial to the longitudinal axis 16 of the container 3. On its opposite side, in the cover 12, there is likewise, viewed coaxially to the longitudinal axis 16, a gas loading port 18 via which the gas side 15 can be supplied in the conventional manner with a working gas, such as, for example, nitrogen, with a predetermined loading pressure.

In FIG. 1, the piston accumulator is provided with an exemplary embodiment of the safety device according to the invention as shown in FIG. 2. The safety device 1 is screwed directly into the gas loading port 18 of the cover 12, so that the safety device 1 directly borders the gas side 15 of the piston accumulator.

FIG. 2 shows in a schematic longitudinal section, not to scale, the safety device 1 for the container 3 which as a whole forms a kind of screw-in body for screwing into the indicated gas loading port 18. For this purpose, the safety device 1 has an external thread 19, which can be screwed into a corresponding internal thread of the cover 12 in the region of the gas loading port 18. The external thread 19 is disposed on a cup-shaped housing 21 of the safety device 1, which housing is provided with a cover 20 that is crimped in the opposite direction to the external thread 19. The housing 21 on its outer periphery can have a hexagonal projection, not detailed, for screwing the housing 21 into the cover 12. There can also be a hexagonal recess, which is not shown, in the cover 20 of the housing 21, for purposes of being able to effect this screwing-in.

Viewed from the region of the housing 21 which bears the external thread 19 to roughly an axial center, the housing 21 is penetrated by a through bore 22 which widens in diameter upward and undergoes transition into a perpendicular cross channel 23 extending radially through the housing 21.

Both the cross channel 23 and the through bore 22 are closed by a plug-like or piston-like component 7 in the initial state of the safety device 1 shown in FIG. 2. The piston-like component 7, with an extension 25 of almost the same diameter, fits in the through bore 22 with a sealing element 26 (not shown) along its radial periphery 27 and is dimensioned like the diameter d₁ of the through bore 22. The extension 25 then widens to about twice the diameter with which the piston-like component 7 then closes the cross channel 23 in the illustrated initial state of the safety device 1. With this diameter d₂, the piston-like component 7 projects into a space 5 of the housing 21 and then in turn widens in the shape of a plate to a diameter d₃ that is slightly smaller than the inside diameter of the cylindrically shaped space 5.

Viewed in the axial direction toward the cover 20, the diameter of the piston-like component 7 in turn diminishes incrementally so that the cross section which is provided with two diameter offsets for the piston-like component 7 is in the shape of steps.

A relief device 2 in the form of a thick-walled, cylindrical component 4, whose outside diameter is greater than its axial length, is placed or clamped between the piston-like component 7 and the cover 20 and is held to the top and bottom in both directions by respective centering surfaces 28 on the cover 20 and the piston-like component 7.

The relief device 2 is loaded by shear resulting from the gas pressure of the gas side 15. The space 5 has a significantly larger inside diameter than the outside diameter of the relief device 2 so that in principle, when shear increases, the relief device 2 can buckle or bulge. The relief device 2 is preferably formed as a plastic body 9 from a polyvinyl fluoride plastic which has a temperature of continuous use of from −40° C. to +140° C. so that, particularly when a temperature of +140 ° C. is exceeded by the action of heat in the event of a fire in the vicinity of the safety device 1, the relief device 2 under the shear of the component 7 deforms away from its axis 8 of symmetry and is deformed away, for example, by bulging or buckling into the space 5 or melts away altogether without further orientation. Since the relief device 2 is a hollow cylinder, such a bulging or buckling motion into the interior of the hollow cylinder is also in principle enabled. In addition to the initial bulging or buckling process, as a result of material softening at high temperature, then, however, at correspondingly even higher temperature, the relief device 2 melts and the plastic material, as shown, is displaced into the closed space 5. These processes take place comparably when the relief device 2 consists of a metallic material, such as a bimetal.

In this case of failure, it is then possible for the piston-like component 7, which until then keeps closed the fluid-conducting connection 6 formed by the through bore 22 and the cross channel 23, to move under the overpressure arising under the action of heat on the container 30 on the gas side in the through bore 22 such that it moves partially into the space 5, as a result of which a controlled outflow of the gas, such as, for example, the working gas nitrogen, is enabled via the cross channel 23 to the outside so that an explosion or other damage of the container 3 cannot accidentally occur. Since the cross channel 23 is being continuously cleared, slow and controlled pressure relief occurs on the gas side.

Provided that, as shown in FIG. 1, the cross channel 23 with its two opposite cross channel segments discharges into a transition space 29, which is spaced on the edge side by a projection 30 of the wall of the accumulator housing 10, deflection of the gas overpressure jet upward takes place, and a further reduction of the overpressure, which may be in the region of 1000 bar or more, can occur, so that individuals in the vicinity of the container definitely cannot be endangered. The collar solution shown in FIG. 1, in which the container 30 is encompassed, forming a protective collar or protective jacket, can also be omitted without the safety function of the device being adversely affected.

Claims

1. A safety device for gas-pressurized containers, in particular for safeguarding the gas side of the working space of hydropneumatic devices, such as hydraulic accumulators, comprising a relief device (2) for reducing an elevated gas pressure in the respective container (3) caused by the action of heat, characterized in that the relief device (2) is a component (4) which is loaded to buckle or bulge under the action of a shear force or compressive force, whose change of shape under the action of heat on the safety device (1) into a space (5) closed to the outside takes place such that a fluid-conducting connection (6) from the interior of the container (3) to the outside is enabled in the direction of the environment.

2. The safety device according to claim 1, characterized in that the relief device (2) under the action of heat is deformed away from an axis (8) of symmetry of the safety device (1) by the action of the shear force or compressive force by a component (7) which directly or indirectly closes the fluid-conducting connection (6).

3. The safety device according to claim 1, characterized in that the relief device (2) is disposed in a space (5) of the safety device (1), which space accommodates several times the volume of the relief device (2).

4. The safety device according to claims 1, characterized in that the relief device (2) is formed from a plastic body (9) which deforms under the action of heat.

5. The safety device according to claim 4, characterized in that the plastic body (9) is formed from a fluoroplastic material.

6. The safety device according to claim 5, characterized in that the fluoroplastic material is a polyvinylidene plastic.

7. The safety device according to claim 1, characterized in that the relief device (2) is a rod-shaped hollow body.

8. The safety device according to claim 2, characterized in that the relief device (2) is disposed between a cover (20) of its housing (21) and the component (7) which blocks the fluid-conducting connection (6) and which component (7) is pressurized via a through bore (22) from the gas side of the container (3).

9. The safety device according to claim 8, characterized in that when the fluid-conducting connection (6) is cleared by the plug-like or piston-like component (7), the through bore (22) discharges into a cross channel (23) which is encompassed to the outside by a projection (30) of the wall of the accumulator housing (10) of the container (3).