DE9212735U1 - Lockable gas spring - Google Patents

Description

DESCRIPTION Lockable gas spring

The invention relates to a lockable gas spring with the features in the preamble of the main claim.

Such a lockable gas spring is known in practice in various designs. It has a separating piston that separates a gas chamber responsible for the spring effect from a fluid chamber that is usually filled with oil, but can also contain a gas or another suitable fluid. A damping piston with a piston rod is movably mounted in the fluid chamber. The piston rod protrudes from the cylinder and has a connection head on the outside. The damping piston has an overflow channel through which the fluid can flow from one side of the piston to the other. When the piston rod with the damping piston extends or retracts, the overflow channel acts as a throttle and dampens the movement. In order to lock the damping piston in any position, a blocking valve is provided that closes the overflow channel and can be actuated by a trigger device for adjustment purposes. Such lockable gas springs are used in practice for adjusting the height or swivel of chair parts and for many other purposes. It has been shown that the known lockable gas springs only have limited overload protection. If they are loaded too heavily, this results in an undesirable change in the gas spring characteristics and also leakage losses.

The invention aims to provide a lockable gas spring that can withstand higher loads without sealing problems and while retaining the gas spring characteristics.

The invention solves this problem with the features in the main claim.

The lockable gas spring according to the invention has an overload protection device that acts on the blocking valve and opens it in the event of an overload. The blocking of the gas spring is therefore only maintained up to an adjustable overload threshold. If this is exceeded, the blocking of the gas spring is released and it gives way elastically. The lockable gas spring according to the invention can therefore no longer be overloaded and damaged. It retains its gas spring characteristics over time and does not show any sealing or leakage problems even if the nominal load is exceeded.

In the preferred embodiment, the overload protection consists of an axially movable connection between the connection head and the damping piston. However, the mobility can be blocked by a retaining device up to an adjustable load threshold. Up to this load threshold, the overload protection is inoperative and enables the lockable gas spring to function normally and assume any blocking position. Only after the load threshold has been exceeded is the axially movable connection able to bring the connection head and the damping piston closer together. This approach movement causes a driver to actuate and open the blocking valve. The piston rod can then retract and give way in the manner described above due to the overload.

The axially movable connection can be made at any point between the connection head and the damping piston, for example between the piston rod and the damping piston. The piston rod can also be split. In the preferred embodiment, the connection head is connected to the end of the piston rod in an axially movable manner. In this way, the connection point is freely accessible from the outside, which has advantages for assembly and maintenance. In this case, the driver is arranged in the same advantageous way on the connection head.

The locking force of the retaining device is adjustable. It is recommended to set the locking force to a value that is less than or equal to the supporting force of the separating piston. The supporting force of the separating piston is the force with which the separating piston presses on the medium in the fluid chamber due to the excess pressure in the gas chamber. In practice, it is recommended to set the locking force of the retaining device to approximately four times the nominal load of the lockable gas spring.

The retaining device can be designed in different ways. In the preferred embodiment of the invention, it consists of a spreading spring arrangement. This has the advantage that when the overload drops and the locking force of the retaining device or spring arrangement falls below the limit, the blocking valve is closed again. The gas spring is then blocked again with its piston rod in a load-safe position. It therefore only gives way elastically as long as the overload exists and does not have to come to a stop. Alternatively, the retaining device can also consist of a spring catch, a friction clutch or another suitable and

adjustable load threshold. In this case, the retaining device only defines a load threshold, but no longer acts against the load once it is exceeded. The gas spring can then move to the stop position. The next time the piston rod is mechanically extended, the retaining device is tensioned again.

The driver, which opens the blocking valve when the overload protection device is activated, can be designed differently depending on the type of axial connection and the retaining device. In the preferred embodiment, the already existing trigger mechanism for adjusting the lockable gas spring is used as a driver.

Further advantageous refinements of the preferred embodiment are set out in the further subclaims.

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The invention is illustrated by way of example and schematically in the drawings. In detail:

Fig. 1: longitudinal section of a lockable gas spring with an overload protection and

Fig. 2: A fragmentary view of an alternative embodiment of the retaining device.

In Fig. 1, a lockable gas spring (1) is shown in longitudinal section, which has a cylinder (2) with cylinder closures (26) at the end. Inside the cylinder (2) there is a gas chamber (5) and a fluid chamber (7) that is preferably filled with oil. A separating piston (6) is arranged between the two chambers (5, 7). In the gas chamber (5) there is an overpressure that acts on the medium in the fluid chamber (7) via the separating piston (6) that is movably mounted along the axis (10). The fluid chamber (7) is closed at the opposite end by a seal (27).

A movable damping piston (8) is arranged in the fluid chamber (7) and is connected to a piston rod (9) that protrudes out of the cylinder (2) through the seal (27) and has a connection head (4) at the end. The damping piston (8) has an overflow channel (11) through which the medium can flow from one side of the piston to the other when the damping piston (8) moves with the piston rod (9). In the embodiment shown, the piston rod (9) is hollow and has an outlet opening in the casing. With this design, the medium flows through the damping piston and part of the piston rod (9) and exits behind the damping piston (8).

again from the piston rod (9). The overflow channel (11) can be opened and closed by a blocking valve (12). In the embodiment shown, the blocking valve (12) consists of a valve rod (13) which is guided in a longitudinally movable and sealed manner inside the hollow piston rod (9). At the end, the valve rod (13) widens out like a plate and thus covers the overflow channel (11).

At the connection head (4), the valve rod (13) emerges from the hollow piston rod (9) and interacts with a release device (14). In the embodiment shown, this consists of a pivoting release lever (15) that can be pressed against the valve rod (13) using a suitable mechanism. The evasive movement in the opposite direction is limited by a stop (16). The release lever (15) can be extended to form a handle. However, it can also be connected to a Bowden cable or to another actuating device (28).

When the release device (14) is activated, the valve rod (13) is pressed into the piston rod (9), whereby the plate-like widening is lifted off the damping piston (8) and the overflow channel (11) is opened. In this position, the damping piston (8) can be extended and retracted with the piston rod (9) depending on the load conditions.

The effective areas on the damping piston (8) are differently large and differ by the area defined by the jacket of the piston rod (9). The total effective piston area on the side facing the gas chamber (5) is larger by this piston rod area, so that an expulsion force acts on the piston rod (9) which

is calculated from the chamber pressure times the piston rod area.

The gas spring (1) can be blocked in any extension position of the piston rod (9) using the blocking valve (12). The blocking is also ensured by loads acting from the outside via the connection head (4) that are greater than the nominal load of the gas spring (1). Above a certain load threshold, there is a risk of air entering through the seal (27) and of oil leakage at the same point due to seal damage. The blockable gas spring (1) shown counteracts this with an overload protection device (3).

The invention has recognized that if an external load is applied that is greater than the supporting force of the separating piston (6), the separating piston can give way. The supporting force of the separating piston (6) is calculated from the gas chamber pressure times the separating piston area. In practice, the separating piston area is usually four times as large as the aforementioned piston rod area. The separating piston (6) therefore threatens to give way if a load is greater than four times the nominal load of the gas spring (1). If the separating piston (6) gives way, the damping piston (8) can move in the same direction due to the closed blocking valve (12), which can create a vacuum on its back in the fluid chamber (7). The vacuum acts on the seal (27) and causes it to turn over or become leaky if the vacuum level is high enough. This causes outside air to be drawn into the fluid chamber (7), which, if it occurs repeatedly, will result in damage to the seal (27). The air bubbles remain in the fluid chamber (7) and further change the damping and spring characteristics of the gas spring (1) in an undesirable manner.

The overload protection device (3) opens the blocking valve (12) in good time before this condition is reached, so that no harmful vacuum is created and the gas spring (1) gives way elastically.

In the embodiment shown, the overload protection (3) consists of an axially movable connection between the connection head (4), via which the load is introduced from the outside, and the damping piston (8). In the preferred embodiment, the connection head (4) is movably mounted on the outside end of the piston rod (9) along the axis (10). The movable connection is blocked by a retaining device (19) which counteracts the external load up to a certain threshold and then gives way. In the embodiments shown, the retaining device (19) preferably consists of a spring arrangement (20).

In the embodiment of Fig. 1, a spring cage (22) is attached to the piston rod (9) slightly set back from the end. A compression spring (21) is arranged in the spring cage (22). A compression sleeve (23) is arranged on the connection head (4), which has a central opening for the valve rod (13) to pass through. The essentially pot-shaped compression sleeve (23) engages in the opening of the spring cage (22) and presses on the spring (21). The compression sleeve (23) is guided axially on the piston rod (9) with its inner casing. In addition, there can also be an external guide on the spring cage (22). The compression sleeve (23) and the spring cage (22) are held together axially by a suitable device that transfers tensile forces from the connection head (4) to the piston rod (9). Compression forces are transmitted to the piston rod (9) via the spring (21).

The spring (21) is pre-tensioned and is held under pressure by a tensioning device not shown in detail in Fig. 1. The locking force of the spring arrangement (20) or retaining device (19) is adjusted via the tensioning device.

The locking force of the retaining device (19) is set to a value less than or equal to the supporting force of the separating piston (6). For standard gas spring designs, the locking force is therefore less than or equal to four times the nominal load of the gas spring (1).

If the loads introduced from the outside move below the locking force of the retaining device (19) or the preload force of the spring (21), the connection between the connection head (4) and the piston rod (9) is rigid. The gas spring (1) then behaves like a normal lockable gas spring. However, if the external load exceeds the aforementioned locking force , the spring (21) gives way elastically. This enables the connection head (4) to move closer to the piston rod (9) or the damping piston (8). This relative movement causes a driver to come into contact with the protruding valve rod (13) and presses it into the piston rod (9), thereby opening the blocking valve (12). In the embodiment in Fig. 1, the release device (14) serves as a driver (17). With appropriate preload of the spring (21), the axial travel until the driver (17) stops on the valve rod (13) can be small. This can vary depending on the spring design.

Fig. 2 shows an alternative. Instead of a spring basket (22), the compression spring (21) is guided inside the correspondingly recessed pressure sleeve (23). The pressure sleeve (23) slides with its offset inner walls on the

Valve rod (13) and the piston rod (9). The pressure sleeve (23) has a blind hole-like guide bore (18), the base of which acts as a driver (17) and presses on the end of the valve rod (13) when the spring (21) yields. The driver (17) can also be designed as a stop screwed into the guide bore (18).

The spring (21) is pre-tensioned by a tensioning device (24). This consists of a stepped union ring that is screwed onto the pressure sleeve (23). The piston rod (9) has a collar at the end that interacts with the union ring, via which the distance between the piston rod end and the spring support surface of the pressure sleeve (23) is reduced when the union sleeve is tightened and the spring (21) can be tensioned accordingly.

In the embodiment of Fig. 2, the connection head (4) is formed in one piece with the pressure sleeve (23). In both embodiments, the connection head (4) has the usual eye (25) for fastening the gas spring (1). At the opposite end of the gas spring (1), a corresponding fitting is arranged on the cylinder (2). In the embodiment of Fig. 2, the triggering device (14) is implemented in a different way than in Fig. 1 and is arranged in a different location (not shown).

In the embodiments shown with a spring arrangement (20), the retaining device (19) permanently acts against the load introduced from the outside. As soon as the external load falls below the blocking force again, the spring (21) pushes the pressure sleeve (23) back into the starting position, whereby the driver (17) again disengages from the valve rod (13). The pressure in the fluid chamber (7) causes the blocking valve (12) to be automatically activated.

closed. The gas spring (1) then blocks again in the normal way.

Modifications to the overload protection device (3) shown are possible in various ways. On the one hand, the piston rod (9) can be connected to the damping piston (8) in an axially movable manner and provided with a retaining device (19). On the other hand, a division of the piston rod (9) and an axially movable connection of the rod parts with a retaining device is also possible. These measures can be carried out instead of or in addition to the connection shown in Fig. 1 and 2 between the connection head (4) and the piston rod (9). The important thing here is that the connection head (4) can approach the damping piston (8) against the force of a retaining device.

The retaining device (19) can also be varied. Instead of a spring (21), an elastically compressible cushion can also be provided. It does not have to be a permanently acting spring arrangement (20). The retaining device (19) can consist of a spring catch, a friction clutch, an elastically yielding latch or another suitable locking device that uses a certain adjustable force to block the relative movement between the connection head (4) and the damping piston (8) and releases it in the event of an overload. The retaining device then locks again as soon as a tensile load is applied to the connection head (4).

LIST OF REFERENCE SYMBOLS

1 Gas spring 2 cylinder 3 Overload protection 4 Connection head (Jl Gas chamber 6 Separating piston 7 Fluid chamber 8th Damping piston 9 Piston rod 10 Longitudinal axis 11 Overflow channel 12 Blocking valve 13 Valve rod 14 Release device 15 Release lever 16 attack 17 Driver 18 Guide hole 19 Restraint device 20 Spring arrangement 21 Feather 22 Spring basket 23 Pressure sleeve 24 Clamping device 25 Eye 26 Cylinder lock 27 poetry 28 Actuator

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Claims (8)

PROTECTION CLAIMS 1.) Lockable gas spring with a separating piston and a damping piston, which has a piston rod connected to a connection head and an overflow channel which can be closed by a blocking valve actuated by a trigger device, thereby characterized in that the gas spring (1) has an overload protection device (3) which opens the blocking valve (12) in the event of an overload. 2.) Lockable gas spring according to claim 1, characterized in that there is an axially movable connection between the connecting head (4) and the damping piston (8), which can be locked by a retaining device (19) up to an adjustable load threshold and, after the load threshold has been exceeded, allows the connecting head (4) and the damping piston (8) to approach each other, wherein a driver (17) is provided in the connection area, which opens the blocking valve (12) when the parts (4,8) approach each other. 3.) Lockable gas spring according to claim 2, characterized in that the connection head (4) is connected to the piston rod (9) in an axially movable manner, the driver (17) being arranged on the connection head (4). 4.) Lockable gas spring according to claim 2 or 3, characterized in that the blocking force of the retaining device (19) is less than or equal to the supporting force of the separating piston (6). 5.) Lockable gas spring according to claim 2, 3 or 4, characterized in that the retaining device (19) is designed as a spreading spring arrangement (20). 6.) Lockable gas spring according to claim 5, characterized in that the spring arrangement (20) has a tensioning device (24) for adjusting the spring force. 7.) Lockable gas spring according to claim 5 or 6, characterized in that the spring arrangement (20) is arranged between the piston rod (9) and the connection head (4), wherein the piston rod (9) has a spring basket (22) with a spring (21) into which a pressure sleeve (23) connected to the connection head (4) and guided along the piston rod (9) engages. 8.) Lockable gas spring according to claim 2 or one of the following, characterized in that the triggering device (14) is designed as a driver (17).