DE3141295A1 - Gas spring with an extension force controlled as a function of temperature - Google Patents

Abstract

The invention relates to a gas spring having the object of achieving an extension force of the piston rod which is controlled as a function of the temperature. This object is achieved in that the volume of the operating chamber into which the piston rod descends can be varied as a function of the temperature by means of a separating wall, and the desired extension force behaviour of the piston rod is thus achieved in a temperature range.

Description

PATENT AND UTILITY MODEL APPLICATION

Gas spring with temperature-controlled extension force The invention refers to a gas spring consisting of a container, the interior of which is a has pressurized gas filling and forms a working space in which a piston rod is immersed, which is guided in the container and sealed to the outside and its extension force is the product of the pressure in the working space and the piston rod Cross-sectional area corresponds.

From DE-OS 2 526 437 a door closer is known which has a has a gas spring provided with a temperature-dependent variable variable throttle valve. This only ensures that the extension movement of the piston rod has uniform speed over a temperature interval, the extension force the piston rod is not temperature-dependent in this known construction controlled. An increase in temperature causes an increase in pressure in the work area and as a result, an extension force that increases proportionally to the rise in temperature.

The object of the present invention is to create a gas spring, the extension force of the piston rod when the temperature changes within the desired limits can be held.

According to the invention this object is achieved in that the working space from a temperature-dependent controlled and changing the volume of the work space Partition wall is limited, with a rise in temperature an increase in the working space causes. It is thus easily possible to reduce the extension force of the gas spring To keep temperature change within desired limits, so can easily a Compensation can be achieved by controlling the partition so that the When the temperature rises, the volume of the working area is increased so that in the working area the pressure is always the same, so that the extension force of the piston rod when the temperature changes remains the same * Will be a certain degree of degression the extension force ge # 4naXt, this can be done by disproportionately increasing the volume of the working area when the temperature rises be achieved.

The temperature-controlled partition becomes, like a feature of the invention shows, formed in a simple manner in that this consists of a separating piston consists, which is arranged axially movable to the container and sealed against it is, this separating piston with a space containing an expansion substance is in operative connection. A special expansion material is advantageously used Liquid, but this can also be changed by other suitable, temperature-dependent volume changes or length-changing components. So it is easily possible that the separating piston is in operative connection with expansion material or bimetallic elements, one simple operative connection of the separating piston with the one containing the expansion material Space is always obtained in that the separating piston has a connecting rod centrally carries and this connecting rod in the space containing the expansion material immersed and sealed against this room.

Since the separating piston under the action of the prevailing in the work area Gas pressure is, according to the invention, an undesired pressure-dependent change in volume of the working space is met in that the separating piston is under the action of a spring whose spring force counteracts the gas pressure in the working space, which acts on the separating piston Acting spring can, for example, be a gas spring, a helical spring, a plate spring or another suitable spring, the spring force being so designed is that this is expediently affected by the pressure in the working space on the separating piston Exerted force exceeds.

As a further feature of the invention shows, carries on the separating piston attached connecting rod at the end opposite the separating piston Disc piston, which is a movable and sealed boundary wall for the forms filled with the expansion material space, In this case, according to the invention advantageous embodiment thereby. get that the separating piston between the working space and a gas space acting as a spring is arranged, being this Gas space has a pressurized gas filling and by means of a fixed container Partition wall is bounded by the space filled with expansion material, while the Connecting rod axially movably guided and sealed in the partition wall fixed to the container In a further embodiment, the separating piston is between the working space and a gas space provided with a vent opening is arranged, this Gas space through the partition fixed to the container from the one filled with expansion material Space is limited during which the movable and sealed as well as the connecting rod disc piston connected to the separating piston on the one facing away from the expansion material Piston side is acted upon by a spring This spring can, as already mentioned, be formed by a gas spring, a helical spring or a plate spring. In Another embodiment of the invention is according to the temperature-controlled feature Partition wall connected to a cup-shaped component surrounding the container, while the container carries an outer cylinder at its end on the piston rod outlet side wherein the partition is on the outer surface of the container and the inner surface of the outer cylinder is performed sealingly and in turn the space containing the expansion material limited and on the other hand acted upon by a spring is another embodiment of the invention features according to a container 5 within an outer cylinder is arranged, this outer cylinder having a greater axial length than the container and with this an annular space serving to accommodate expansion material forms Here, as a feature of the invention shows, it is useful if the Disc piston is sealingly guided on the inner wall of the outer cylinder, while the separating piston slides on the inner wall of the container and the expansion material containing space is limited by the separating piston and disc piston.

An advantageous embodiment of the invention is according to features obtained in that the container-fixed partition with passage openings for the pressurized gas filling of the working space is provided and the expansion substance containing space carries while the connecting rod connected to the separating piston on the end face opposite the partition wall into the expansion material filled space is immersed, the separating piston on the one hand from the pressure in the working space and on the other hand is acted upon by the spring.

On the basis of the exemplary embodiments shown in the drawing the invention is explained in more detail below. It shows: Fig. 1 the schematic representation a gas spring in longitudinal section; Fig. 2 is a schematically shown gas spring, wherein whose disc piston delimiting the expansion material on the other hand from a spring applied. Fig. 3 is a temperature-compensated gas spring with a circular ring trained separating piston; Fig, @ an embodiment of a temperature-compensated Gas spring, with the disk piston connected to the separating piston on the one hand is acted upon by a coil spring; 5 shows a gas spring in longitudinal section, wherein the container is surrounded by an outer cylinder and an annular space for receiving it of the expansion material forms; 6 shows a gas spring, on the disc piston of which one space under gas pressure is limited, and FIG. 7 shows a gas spring in longitudinal section, wherein a fixed and provided with passage openings dividing the the expansion material. containing space carries, The gas spring shown in Fig, 1 consists of the container 1, on the inner wall of which the piston 3 connected to the piston rod 2 slides, A in the interior of this container 1 arranged working space 5 has a pressurized standing gas filling, which exerts an extension force on the piston rod 2 which is the product of the gas pressure in the working space 5 and the cross-sectional area of the piston rod is equivalent to. By means of one located at the end of the container on the piston rod outlet side Seal 4, the piston rod 2 is sealed. For temperature-dependent acting Control of the extension force, the working space 5 is delimited by a separating piston 6. This separating piston 6 is provided with a connecting rod 7 and a disc piston 8 connected. The connecting rod 7 is mounted in a partition 10 fixed to the container and sealed.

Located between the separating piston 6 and the partition 10 fixed to the container In the container 1, a gas space 11 with a pressurized gas filling, wherein the pressure of this gas filling is chosen so that it acts on the separating piston 6 is the same or slightly greater than that of the gas filling of the working space 5 force exerted on the separating piston 6. One with. Expansion fabric-filled space 9 is located between the partition 10, which is fixed to the container, and the disc piston 8, this disc piston 8 being the movable partition for this with expansion material represents filled space 9. On the opposite side of the piston to the expansion material of the separating piston 8, a ventilated space 12 is provided, which by means of a constantly open passage cross-section is in communication with the atmosphere.

The gas pressure in the working space 5 is chosen so that the piston rod 2 reaches the desired extension force. When the temperature rises, the im expands Space 9 located expansion substance and causes the disc piston 8 further away from the partition 10 fixed to the container. At the same time it leads over the Connecting rod 7 with the disc piston 8 connected separating piston 6 the same movement from and thus enlarges the working space 5, whereby the as a result of the temperature increase The resulting pressure increase in the working space is compensated and the piston rod is the same Has extension force, by appropriate choice of the expansion material and volume of the space 9, it is easily possible to fully compensate for the extension force to be achieved with a change in temperature or a slightly progressive or degressive one To create characteristic curve for the extension force of the piston rod 2.

A special liquid is preferably used as the expansion substance If chosen5, however, it is easily possible to use other suitable substances for this purpose to use.

When it cools down, the volume of the expansion substance in the Space 9, whereby the disc piston 8 in the direction of the partition fixed to the container 10 moves and accordingly the separating piston 6 reduces the working space 5. Included acts the resilient property of the provided with a pressurized gas filling Gas chamber 11 on the separating piston 6, in the opposite direction to the pressure in the working chamber 5. In this way, the pushing-in and pushing-out force of the gas spring can be temperature-dependent control, the extension speed of the piston rod by that in the piston 3 located damping device, which is shown as a throttle bore is achieved.

In the embodiment according to FIG. 2, the container 1 is located The working space 5 is also limited by the separating piston 6.

The separating piston 6 is housed here in a space of the container, which has a larger diameter, and in turn stands over the connecting rod 7 with the disc piston 8 in connection. Between the partition wall fixed to the container 10 and the separating piston 8 is a gas space 13, which by means of a ventilation opening 14 is connected to the atmosphere When the temperature rises, the expansion material expands in space 9 and causes a movement of the disc piston 8 against the force of the gas pressurized space 15. The gas pressure in space 15 thus acts as Spring on the disc piston 8, the spring force being directed in the opposite direction to the force exerted by the working chamber 5 on the separating piston 6. This temperature-dependent displacement of the separating piston 6 and thus the change in volume of the working space 5 causes the temperature-dependent control of the extension force here as well the piston rod 2.

The gas spring according to FIG. 3 has the container 1, which is provided with an outer cylinder 18 is connected. Between the inner wall of the outer cylinder 18 and the outer wall of the container 1, the ring-shaped separating piston 16 is arranged. This Separating piston 16 is connected to a cup-shaped component 17, which the container 1 surrounds. The working space 5, which is provided with a pressurized gas filling consists in this embodiment of the interior of the container 1 and the annular space between the container 1 and the cup-shaped component 17. The expansion material containing space 9 is located between the outer surface of the container 1, the Inner surface of the outer cylinder 18 and the end face on the piston rod outlet side. This space 9 is limited by the separating piston 16, on the other side of the piston Gas pressure in space 15 acts. The piston rod is by means of the piston rod seal 4 2 sealed off from the work space 5.

When the temperature increases, the expansion substance located in space 9 expands off and causes a movement of the separating piston 16 against that of the gas pressure in the room 15 resulting force, thereby with the displacement of the separating piston 16 and of the cup-shaped component 17 causes an enlargement of the working space 5 and thus counteracting a pressure build-up due to an increase in temperature in space 5.

The gas spring according to Fig. 4 is provided with a tubular container 1, whose diameter is kept constant over the entire length. On the piston rod outlet side At the end, the piston rod 2 is sealed by means of the piston rod seal 4. Of the provided with a pressurized gas filling working space 5 is through the connected to the piston rod 2 and provided with a throttle bore piston 3 divided. For temperature-dependent control of the extension force of the piston rod 2, the working space 5 is delimited by the separating piston 6, which is opposite the inner wall of the container is sealed, between a fixed in the container 1 by beads The partition wall 10 and the partition piston 6 is the gas space 13 with the vent hole 14. On the other hand, the partition 10 that is fixed to the container is the one containing the expansion material Space 9 is provided, which is delimited by the disc piston 8 and this disc piston 8 is acted upon by a helical spring 21 on its surface opposite the space 9 is. This gas spring thus corresponds in its. Structure essentially that of Fig. 2. Here, too, when the temperature rises by increasing the volume of the expansion material iR space 9 by the separating piston 6 a corresponding enlargement of the working space 5 achieved and thereby a temperature compensation of the extension force for the piston rod 2 created.

The gas springs according to FIGS. 5 and 6 have tubular outer cylinders 18 surrounding the container 1. Here, too, the working space 5 is in the container 1 provided., in which the piston rod 2 dips. Between the outer wall of the container 1 and the inner wall of the outer cylinder 18 becomes an annular space formed, which represents the space 9 containing the expansion material * The opposite the disc piston 8 provided with a relatively small piston area separating piston 6 is connected to the disc piston 8 via the connecting rod 7 and forms a seal guided on the inner wall of the container 1. The disc piston 8 is in the embodiment according to Fig. 5 under the action of a helical spring 21 and in the embodiment according to Fig, 6 under the action of a spring, which is under gas pressure Room 15 is formed. When the temperature rises, the expansion material expands in the Space 9 and causes a movement of the disc piston 8 against the force of the Spring - helical spring 21 or spring chamber 15 - so that here too the volume of the Working space 5 is changed depending on the temperature and accordingly the extension force of the piston rod 2 remains constant over a temperature range, or can be changed in a desired course.

Fig. 7 shows a gas spring in which one is under pressure Working space 5, which has gas filling, through the partition 10 that is fixed to the container arranged passage openings 19 is enlarged. In the one located in the container 1 Working chamber 5, the piston rod 2 is immersed and the pressure of the working chamber 5 acts on the separating piston 6. The other piston side of the separating piston 6 is through from one side Disc springs 20 formed spring acted upon. From the partition fixed to the container 10, the space 9 containing the expansion material is carried, in which the with the connecting rod 7 connected to the separating piston 6 is immersed. When the temperature rises the connecting rod 7 protruding into the space 9 by increasing the volume of the The expansion substance displaces and causes a displacement of the separating piston 6 in the opposite direction the force of the plate spring 20, which at the same time increases the volume of the Working space 5 and thus a temperature compensation is achieved, L. e e r e i t e

Claims (12)

P A T E N T A N S P R ü C H E as spring, gas spring, consisting of a Container, the interior of which has a pressurized gas filling and a Forms working space in which a piston rod is immersed, which is guided in the container and is sealed to the outside and its extension force is the product of pressure in the Working space and piston rod cross-sectional area, dad. gek. that the Working space (5) from a temperature-controlled and the volume of the working space (5) changing partition wall is limited, with a rise in temperature an enlargement the working space (5) causes. 2. Gas spring according to claim 1, dad. gek. that the temperature dependent controlled partition by an axially movable to the container (1) and arranged opposite this sealed separating piston (6, 16) is formed with a one Expansion material containing space (9) is in operative connection. 3. Gas spring according to claims 1 and 2, dad, gek. That the separating piston (6) centrally carries a connecting rod (7) and this connecting rod (7) in the space (9) containing the expansion material is immersed and opposite this space (9) is sealed 4. Gas spring according to claims 1 to 3, dad. gek that the separating piston (6, 16) under the action of a spring (gas chamber 11, chamber 15, disc springs 20, helical spring 21), the spring force of which counteracts the gas pressure in the working chamber (5). 5. Gas spring according to claims 1 to 4, dad. gek. that the on the separating piston (6) attached connecting rod (7) to the one opposite the separating piston (6) End of a disc piston (8) carries which a movable and sealed boundary wall forms for the space (9) filled with expansion material. 6. Gas spring according to claims 1 to 5, dad. gek. that the separating piston (6) arranged between the working chamber (5) and a gas chamber (11) acting as a spring is, wherein this gas space (11) has a pressurized gas filling and by means of a partition (10) fixed to the container from the one filled with expansion material Space (9) is limited, while the connecting rod t7) is axially movable in the container-fixed partition (10) is guided and sealed. 7. Gas spring according to claims 1 to 5,, dad. gek. that the separating piston (6) between the working space (5) and one provided with a ventilation opening (14) Gas space (13) is arranged, this gas space (13) through the partition fixed to the container (10) is bounded by the space (9) filled with expansion material, while the over the connecting rod C7) with the separating piston (6) connected disc piston (8) acted upon by a spring on the side of the piston facing away from the expansion material is. 8. Gas spring according to claims 1, 2 and 4, dad. gek. that the temperature-dependent controlled separating piston (16) with a cup-shaped, the container (1) surrounding Component (17) is connected, while the container (1) at its piston rod outlet side End carries an outer cylinder (18), the partition wall (16) on the outer surface of the container (1) and the inner surface of the outer cylinder (18) in a sealing manner is and on the one hand delimits the space (9) containing the expansion material and on the other hand is acted upon by a spring. 9. Gas spring according to claims 1 to 5, dad. gek. that the container (1) is arranged within an outer cylinder (18), this outer cylinder (18) has a greater axial length than the container (1) and with this one forms an annular space (space 9) serving to accommodate expansion material, 10. Gas spring according to claims 1 to 5 and 9, dad gek. That the rotary piston C8) on the Inner wall of the outer cylinder (18) is sealingly guided, while the separating piston (6) slides on the inner wall of the container (1) and the one containing the expansion substance Space (9) is bounded by the separating piston (6) and the disc piston (8). 11. Gas spring according to claims 1 to 4, dad. gek. that the container-proof Partition wall. (10) with passage openings (19) for the pressurized gas filling of the working space (5) is provided and the space containing the expansion material (9), while the connecting rod (7) connected to the separating piston (6) dips into the space (9) on the end face opposite the partition (10), wherein the separating piston (6) on the one hand from the pressure in the working space (5) and on the other hand is acted upon by a spring. 12. Gas spring according to claims 1 to 4 and 11, dadg gek. That the the spring acting on the separating piston (6) is formed by disc springs (20).