JPS6165927A - Temperature compensation type gas spring - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a temperature-compensated gas spring, which is provided with a main pressure chamber and a sub-pressure chamber that are airtightly separated from each other, and which is arranged in a cylinder. a piston is connected to the piston rod, and the main pressure chamber has a gas filling under pressure, which gas filling is advantageously a two-phase liquid phase and a gas phase in equilibrium. It is designed to exert a force on the piston rod that is greater than the gas pressure that dominates the sub-pressure chamber formed by the system, and the pressure changes in the main pressure chamber and the pressure changes in the sub-pressure chamber based on temperature changes, It relates to a type which is adapted to one another in such a way that it causes no change in the force on the piston rod, or at least no appreciable change in the force.

BACKGROUND OF THE INVENTION A temperature-compensated gas spring of the type described above is known from DE 33 24 214 A1. In this gas spring, the main pressure chamber is separated from the auxiliary pressure chamber by a piston that is closely guided in the cylinder, and in addition to the cylinder a container is required to surround the cylinder.

The damping effect of the entry and exit movements of the piston rod is a consideration and cannot be achieved with this construction by simple means. Moreover, the dynamic sealing of the two gas chambers can only be achieved using sealing elements of very expensive construction, and the friction occurring between the piston seal and the cylinder cannot be easily reduced to a narrow range. I can't stop it.

Problems to be Solved by the Invention The object of the present invention is to provide a structure which does not have the disadvantages of the known constructions, has a simple structure, is inexpensive to manufacture, and which can provide a damping effect against the movement of the piston rod in a simple manner. It is an object of the present invention to provide a temperature-compensated gas spring that is possible.

Means for Solving the Problem The means of the invention for solving the above-mentioned problem is such that, in a temperature-compensated gas spring of the type mentioned at the outset, an axis line between the main pressure chamber and the auxiliary pressure chamber in the cylinder is provided. A partition wall and a seal are arranged which are fixed in direction and penetrated by the piston rod, and the piston rod is constituted by two cylindrical sections, and the cylindrical section assigned to the main pressure chamber is The piston, which has a larger cross section than the cylindrical section assigned to the auxiliary pressure chamber and is connected to the piston rod, is designed as a damping piston.

Embodiment If, according to an embodiment of the invention, the partition wall arranged between the main pressure chamber and the auxiliary pressure chamber is constructed as a piston rod guide, a temperature-compensated gas temperature-compensated gas system with a very simple and operationally reliable construction can be achieved. A spring is obtained, which achieves a good centering of the piston rod section and thus a low stress on the dynamically acting piston rod seal.In a further embodiment, a spring is obtained between the main pressure chamber and the auxiliary pressure chamber. The arranged packing is made up of a seal ring,
The sole ring has an inner diameter that allows piston rond packing/
By virtue of the fact that the outer diameter of the ring is in airtight contact with the inner wall of the ring, a pressure of 7 mm is achieved between the main pressure chamber and the auxiliary pressure chamber.

According to a further embodiment, the piston rod constituted by two cylindrical sections consists of two piston rod components, which are connected in the axial direction by a fixed connection. . In order to achieve good operational reliability of the gas spring with as little friction as possible, the axially stationary connection of the piston rod component is designed as a movable joint, in which case a relatively large cross-section is required. The piston rod component has a gas-sleep-shaped extension with a surface into which a coupling head on the other piston rod component engages. As a result, stresses between the gas spring components moving relative to one another, and thus increased friction, are eliminated in a simple manner.

According to a further embodiment, an oil sump is arranged in the region of the sealing ring on the side of the main pressure chamber, and according to a further embodiment, the oil sump is sealed off with respect to the main pressure chamber by a separating piston. As a result of this, an extremely good air pressure is achieved between the main pressure chamber and the auxiliary pressure chamber. In this way/-the cylinder can be constructed very simply and a very low-friction and wear-resistant dynamic seal of the piston rod is obtained. In order to facilitate the introduction of oil into the oil sump during assembly, according to one embodiment a spacer ring is arranged between the separating piston and the sealing ring.

If a piston rod component with a relatively small diameter is provided with a guide ring in the area of the connection point, this guide ring can be designed as a damping piston, which provides better guidance of the piston rod reservoir. can. It is likewise conceivable to equip the guide ring with nine contacts sliding on the inner wall of the cylinder in a gas spring which likewise simultaneously serves as a conductor for the electric current.

EXAMPLE The temperature-compensated gas splash shown in FIG. 1 comprises a cylinder 1 in which a piston /2 connected to a piston 13 slides.

The piston rod 3 has a cylindrical section 4 with a larger diameter than a further cylindrical section 5. A partition wall 8 and two meshes 9 are arranged, which are pierced by the main pressure chamber cylindrical section 4, which preferably has a nitrogen gas filling under pressure. At the end of the cylinder 1 on the side from which the piston rod projects, a piston front guide with a cylindrical section 5 and a piston rod seal are provided. The sub-pressure chamber 7 is filled with a two-phase system. The two-phase system is preferably formed by a so-called liquid gas, and in the two-phase system the liquid and gas phases are in equilibrium r. The thrust force on the piston rod 3 is exerted by the main pressure chamber 6, which thrust force is equal to the product of the pressure and the cross-sectional area of the cylinder section 4. The auxiliary pressure chamber 7 generates a counter force against this running force. This force is 2
It is equal to the difference in cross-sectional area of the two cylindrical sections multiplied by the zero pressure inside the sub-pressure chamber 7. Dimensions are -30°C to 80'C
A pressure change in the main pressure chamber 6 and in the subpressure chamber γ based on a temperature change in the range does not result in any force change with respect to the thrust force of the piston rod 3, but at least causes a negligible force change. harmonize with each other so that they are nothing more than The piston rod 3 preferably consists of two piston rod components, one of which forms the cylindrical section 4 and has a sleeve-shaped extension 12 . The connecting head 13 of the piston rod component constituting the further cylindrical section 5 engages inward, and these two piston rod components 1 are connected at this point to an axially stationary connection 11.
The connecting portion 11 is formed by, for example, bending the sleeve end of the additional portion 12.

The connection between the sleeve-like extension 12 and the connection head 13 can be constructed as a joint that is movable within predetermined limits, so that slight alignment errors of the cylindrical sections 4 and 5 can be can be compensated. Since the partition wall 8 has a guide hole 10 adapted to the outer diameter of the cylindrical section 4, a non-negligible radial movement of the cylindrical section 4 has to be counteracted by a seal 9 configured as a sealing ring. There isn't. In order to ensure satisfactory sealing of the main pressure chamber 6 to the auxiliary pressure chamber 7 without imposing high demands on the seal 9, an oil sump 14 is provided, which is connected to the main pressure by means of a separating piston 15. It is sealed against chamber 6. In order to facilitate the introduction of oil into the oil reservoir during assembly, a spacer ring 16 is disposed between the packing 9 and the separation piston 15. In order to precisely guide the cylindrical section 5 of the piston rod 3 in the cylinder 1, a guide ring 17 is provided, which guide ring 17 connects the cylindrical section 5 within the axially fixed connection 11. combined.

A damping piston 2 is mounted at the end of the cylindrical section 4, in particular to dampen the movement of the piston r3 out of the cylinder 1. The damping piston 2 has a labyrinth-type connecting ring that is always open, and the piston ring, which is axially movable in the piston groove, only has a larger cross section when the piston rod enters the cylinder. It's just opening up. When running, the piston ring closes an additional cross section, so that only a permanently open labyrinth-type connection is available between the main pressure chamber on the piston rod side and the main pressure chamber on the bottom side of the cylinder. This dampens the piston rod's running movement.

The temperature-compensated gas spring described above can also be used as a conductor for electrical current by means of a sliding contact 18 provided on the piston 2. This dual function, which is known for ordinary gas springs, ie as gas spring and electric wire, is likewise possible with temperature-compensated gas springs of this construction without any problems. FIG. 2 shows another embodiment of the arrangement of the swivel contacts. Here, the sliding contact 19 is connected to the guide ring 17 by a fixing ring 20. Such a configuration is particularly advantageous, since no sealing components slide on the inner wall of the cylinder 1 in the area on which the idler 17 and therefore also the sliding contact 19 slide. It is from.

EFFECTS OF THE INVENTION According to the invention, it is possible in a simple manner to implement a temperature-compensated gas spring in a single-tube construction, in which case a dynamic seal is formed on the piston rod on the one hand, and a gas spring on the other hand is It is sufficient to provide one sealing member which is effective as a static seal on the cylinder wall. The pressure prevailing in the main pressure chamber multiplied by the cross-sectional area of the piston rod acts as the driving force, while the gas pressure prevailing in the secondary pressure chamber, on the other hand, is the difference in cross-sectional area between the two cylindrical sections of the piston rod. This acts to counteract the propulsion force generated by the main pressure chamber.

The force exerted on the piston rod based on temperature changes in the main pressure chamber and the sub-pressure chamber is adjusted so that there is no change in the force acting on the piston rod within a relatively large temperature range, or at least no negligible change. harmonize with.

Furthermore, it is possible in a simple manner to provide a damping mechanism, in particular for the running movement of the piston rod, which damping mechanism is constituted by a damping piston. This damping piston can be arranged both in the main pressure chamber and in the auxiliary pressure chamber.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal cross-sectional view of one embodiment of a temperature-compensated gas spring according to the present invention, and FIG. 2 is a longitudinal cross-sectional view of the partition wall between the main pressure chamber and the sub-pressure chamber of the temperature-compensated gas spring. It is a diagram. DESCRIPTION OF SYMBOLS 1... Cylinder, 2... Piston, 3... Piston rod, 4, 5... Cylindrical section, 6... Main pressure chamber, 7... Sub-pressure chamber, 8... Partition wall , 9... Packing, 1°... Guide hole, 11... Joint part, 12...
Additional part, 13... Connection head, 14... Oil sump, 1
5... Separation piston, 16... Spacer ring, 1
7... Guy)'! J 7ri, 18. 19...Sushi contact, 20...Fixing ring.

Claims (1)

[Claims] 1. A temperature-compensated gas spring, comprising a main pressure chamber and a sub-pressure chamber airtightly separated from each other, in which a piston disposed in a cylinder is connected to a piston rod. and the main pressure chamber has a gas filling under pressure, the gas filling exerting a force on the piston rod that is greater than the gas pressure prevailing in the secondary pressure chamber,
so that pressure changes in the main pressure chamber and pressure changes in the auxiliary pressure chamber due to temperature changes do not cause a change in the force acting on the piston rod, or at least cause only a negligible change. In a type that is harmonized with one another, the main pressure chamber (
A partition wall (8) and a packing (9) are arranged between the auxiliary pressure chamber (7) and the auxiliary pressure chamber (7), and are fixed in the axial direction and penetrated by the piston rod (3), and The piston rod (3) is composed of two cylindrical sections (4, 5), and the cylindrical section (4) assigned to the main pressure chamber (6) is assigned to the auxiliary pressure chamber (7). temperature-compensated piston, characterized in that the piston (2), which has a larger cross section than the cylindrical section (5) and is connected to the piston rod (3), is configured as a damping piston. Gas spring. 2. The temperature-compensated gas according to claim 1, wherein the partition wall (8) arranged between the main pressure chamber (6) and the sub-pressure chamber (7) is configured as a piston rod guide. Spring. 3. The packing (9) disposed between the main pressure chamber (6) and the sub-pressure chamber (7) is composed of a seal ring, and the seal ring also constitutes a piston rod packing at its inner diameter. Cylinder (1)
A temperature-compensated gas spring according to claim 1 or 2, which is in airtight contact with an inner wall of the gas spring. 4. The piston rod (3) composed of two cylindrical sections (4, 5) consists of two piston rod components, which form an axially immovable connection (11). A temperature-compensated gas spring according to any one of claims 1 to 3, which is connected by a temperature-compensated gas spring. 5. The axially stationary connection (11) is designed as a movable joint, in which case the piston rod component, which is a cylindrical section (4) with a relatively large cross section, is a sleeve-shaped extension. (12), and the additional part (
12) in which the coupling head (13) of the other piston rod component, which is the cylindrical section (5), is engaged; Temperature-compensated gas spring as described in section. 6. Claim 1, in which the oil reservoir (14) is arranged on the main pressure chamber side within the area of the seal ring (packing 9).
The temperature-compensated gas spring described in any one of Items 1 to 5. 7. According to one of claims 1 to 6, wherein the oil sump (14) is sealed off from the main pressure chamber (6) by a separating piston (15). Temperature compensated gas spring. 8. Separation piston (15) and seal ring (packing 9)
), a spacer ring (16) is arranged between the
A temperature compensated gas spring according to any one of claims 1 to 7. 9. The piston rod component, which is a cylindrical section (5) with a relatively small diameter, has a guide ring (17) in the region of the axially fixed connection (11);
A temperature compensated gas spring according to any one of claims 1 to 8. 10. According to any one of claims 1 to 9, the guide ring (17) has a sliding contact (19) that slides on the inner wall of the cylinder (1). Temperature compensated gas spring.