DE4116030C1 - Gas spring with hydraulic shock damping - has jacketed cylinder with shock absorbing liq. filled chamber between walls - Google Patents

Abstract

The gas spring with damper unit incorporates a gas filled cylinder (1), in which a piston (9) slides. Between the piston and cylinder is a chamber (23) which is filled with hydraulic fluid, which passes into a second chamber (4) upon the piston returning to its rest position. The fluid flow is controlled by a valve (33) and orifice (25) providing damping action. Upon compression of the spring, fluid flows from the second chamber through the valve with less restriction, allowing rapid compression as opposed to retraction. USE/ADVANTAGE - For car axles, with damping in extending direction, compact design, and long service life.

Description

The present invention relates to a hydrau Gas shock absorber, especially for cushioning of vehicle axles. The invention is based on a hydraulically shock-absorbed, towards the end driving gas spring with a compressed gas filled Cylinder in which one is a hollow cylinder with an open inner end trained unit from piston and Piston rod is slidably guided, and with a surrounding annulus, the ge with shock fluid which is filled in during the entry and exit movements the piston rod back and forth between two chambers flows here over at least one throttle channel and have a check valve connection with each other. Such a gas spring is from DE 25 11 289 A1 knows.

In this known design, the cylinder is a walled and axially through two by a central partition successive rooms divided, of which the floor side space absorbs the compressed gas and the lid side Space a closed surrounding the piston rod Represents the annular space through the middle of the Piston rod trained pistons in two chambers below is shared, between which the shock fluid when the piston rod moves in and out through throttle channels or back formed in the piston blow valves flows back and forth. From this results a considerable overall length, especially for use in vehicles can be disadvantageous.

Another disadvantage can be seen that  Compensation of temperature expansion of the shock absorbers liquid inside the piston rod Licher compensation piston must be provided. In the end it can be disadvantageous that in the known training there is no possibility of damping when compressing and / or rebounding in a simple way put or change.

The same applies to one known from DE 38 39 446 C2 hydraulic shock-absorbing gas spring. This differs different from the training considered above, that a mounting pipe attached to the cylinder bottom seals that the piston engages in the interior of the piston rod is formed at the end of this piston rod and that the chambers formed on both sides of this piston are not via throttle channels or rear provided in the piston have check valves connection but via outside flow paths of the cylinder, in which the Throttle channels or check valves are provided. Here too there is a considerable overall length. Exactly So there must be a floating here in the piston rod displaceable compensating piston can be provided, the the volume differences between the amounts of liquid compensates for that when moving out of one chamber is displaced and can flow into the other.

In itself is from DE 27 55 816 A1, specifically from Fig. 6, a hydraulic shock-absorbing gas compression spring known, because of a compact design is achieved by the cylinder being double-walled forms is. Here, however, the hydraulic Shock absorption in the central area using a throttle having pistons and check valves, and the compressed gas supplying the spring force is located in the partition wall annulus.  

This training creates the one with the movement damping associated heat development inside, so that the heat is dissipated poorly. Such training would be unsuitable for a vehicle suspension element net and indeed this well-known training is also preferably as a door closer, for windows or for other locking devices that are rarely operated thought.

In addition, the gas pressure acts only indirectly in the sense of Extending the piston rod, namely via the shock damper fluid, and this is not from the compressed gas Cut. This is also a disadvantage because it is can lead to foaming of the liquid.

The same applies to one known from DE 33 02 858 A1 hydraulically shock-absorbing gas pressure spring, however is an effective tension spring in the sense of retraction. Also there is a double-walled cylinder in the a floating piston a pressure  separates gas annulus from a liquid space, wherein at the rod end of the cylinder of the liquid filled annulus over a calibrated bore and a gap connection with the rod space of the inside cylinder, which is also filled with liquid. The lid-side space of the inner cylinder is vented. Even with this training, the gas pressure only works in directly, namely via the liquid on the piston, namely the rod-side ring surface, so that this in the sense of retraction. The damping comes from the flow resistance when flowing through of hole and gap and is not adjustable bar.

DE describes a further state of the art 24 31 527 A1, which is again intended as vehicle suspension and in the double-walled cylinder design in Partition annulus a frustoconical membrane, the one end on the inner cylinder and the other A gas space from the river liquid space separates. Here are the flow conditions and the damping generation associated with a Level regulation designed differently.

Another state of the art shows the DE 24 56 286 A1, namely a hydropneumatic Vibration damper with a hollow piston rod Compressed gas is filled. However, this compressed gas does not work as a feather.

The object of the present invention is to create one acting in the direction of the extension and at the this extending movement of hydraulically damped gas spring, the simple and compact design, in particular short overall length, consistently good damping effect development unfolded. For this purpose, overheating should be reliable be avoided. In use with lifting tow  axes should cause the lifting of the trailing axis Retraction device that occurs in normal driving do not interfere with spring movements.

Based on the training specified at the beginning to solve the task of the cylinder double wall-shaped and the one shock absorber fluid is through the double wall annulus between the Cylinder outer wall and the cylinder inner wall formed, the other shock fluid chamber through the Piston rod annulus between the piston rod and the Inner cylinder wall is formed and the cylinder bottom Be boundary of the shock absorber fluid chamber in the double wall Annulus by a slidably seated in it Floating piston is formed, which is spring in the sense is applied that the shock absorber fluid under Pressure is maintained.

Appropriate further training results from the sub claims. The station wagon is a special design nation with a plurality of retracting cylinders. These Training is suitable for cushioning liftable Trailing axles, the spring play in normal driving drive is not affected.

The invention will hereinafter be described by the description of an embodiment further explained, wherein it to a preferred embodiment of a hydraulic shock absorber damped gas spring for cushioning a vehicle towing axis that can be raised if necessary, what by a plurality of special retracting cylinders looks. This training is shown in the drawings poses. It shows

Fig. 1 a longitudinal section of the hydraulically damped shock gas spring with Einziehzylindern;

Fig. 2 shows the section according to line II-II in FIG. 1.

The gas spring consists of a double-walled cylinder 1 with a cylinder outer wall 2 and a cylinder inner wall 3 , between which a double-walled annular space 4 remains ver. One (in the drawing upper) end of the cylinder is closed by a welded-on cylinder base 5 . On this a tab 6 is attached to the articulated connection of this cylinder end.

At the other end of the cylinder, a cover 7 is attached, through which the piston rod 9 of a piston 8 protrudes sealed. The outer end of the piston rod 9 is connected to a mounting shell 10 , which allows a flexible connection to be made while enabling all-round angular movements.

The piston rod 9 is hollow and its interior forms, together with the space enclosed by the cylinder inner wall 3 , a gas pressure chamber 11 , which via a charging valve 12 with compressed gas, for. B. with nitrogen, ge is filled. The gas pressure acts on the piston 8 in the sense of the extension.

Between the cylinder base 5 and the piston 8 , a progression spring 13 is inserted, in the bottom end of which for guiding and fixing the same, a fixing cylinder 14 attached to the cylinder bottom 5 protrudes and the cover-side end cooperates with a stop disc 15 , which in the cavity of the piston rod 9 is set. When the piston rod 9 is fully extended, a distance remains between the cover-side end of the progression spring 13 and the stop disk 15 , so that a first section of the deflection path of the piston rod 9 is only covered against the gas pressure, and on a second section of the deflection path the progression spring 13 engages. In the drawing, the state of deflection is shown, in which this happens. In this position, the spring force is still zero, and with further compression of the piston rod, the progression spring 13 increasingly engages in the force generation of the gas spring.

In the double-walled annular space 4 there is a floating piston 20 which is urged towards the cover 7 by a floating piston spring 21 which is supported on the cylinder base 5 with its rear end. The located in front of the floating piston 20 double-walled annular space 4 is filled with a shock absorber fluid and has holes 22 evenly distributed in the cylinder inner wall 3 cross connection with the piston rod annular space 23 , which is formed between the piston rod 9 and the cylinder inner wall 3 .

Another connection between the double-walled ring space 4 and the piston rod annular space 23 is established via a throttle channel 25 , in the course of the drawing of which a throttle screw 27 is built, which is easily accessible from the front side of the cover 7 and at which the throttling effect on the shock fluid flowing in the throttle duct 25 can be adjusted.

In the vicinity of the cover 7 and between the points at which the cross bores 22 and the throttle channel 25 open into the double-walled annular space 4 , a ring installation 30 covering the ring cross section is fastened in this, through which a plurality of overflow bores 31 run, which run are covered on the front side of the ring installation 30 facing the cover 7 by a check valve 33 in the form of a ring, which is held in position by one or more springs 35 . The check valve 33 thus allows a flow through the overflow bores 31 only in the direction of the cover and thus through the transverse bores 22 , namely when the piston 8 is deflected and the piston rod chamber 23 thus enlarges.

On the outside of the gas spring cylinder 1 , four evenly distributed retracting cylinders 40 are attached, the piston rods 42 of which engage a yoke plate 44 , which is connected to the end of the piston rod 9 of the gas spring cylinder 1 . Each piston rod 42 protrudes sealed by the cylinder cover 45 in a pulling cylinder 40 and has at the cylinder inner end a piston stop 46 in the form of a head, in front of which a free piston 48 which is displaceable on the piston rod 42 is seated.

To retract the piston rod 42 , the piston rod space 50 of each retracting cylinder 40 can be acted upon by a pressure liquid via a channel not provided with reference numerals. The cylinder chamber 52 on the other side is vented, for which purpose an air filter 54 is seen in the wall of the retracting cylinder 40 at the bottom end.

The gas spring described is used to cushion a trailing axle of a vehicle. When this takes part in the driving operation, the piston rod spaces 50 40 depressurized, so that the free piston 48 are seated the Einziehzylinder on the cylinder covers 45 and the piston rods 42 practically without resistance by the cover 45 and free piston can slide 48 and follow the spring vibration of the gas spring.

In the gas spring itself acts on about the first half of the deflection only the tensioned gas in the gas pressure chamber 11 as a spring and is supported on the second half of the deflection path by the progression spring 13 , so that the spring characteristic can be chosen almost arbitrarily.

Damping on the last section of the feed path is achieved in that section of the fixing cylinder 14 dips into the interior of the piston rod 9 and the remaining annular gap between the progression spring 13 is dimensioned such that there is in the annular space between the inner cylinder wall 3 and the fixing cylinder 14 can build up a higher pressure than in the central space, which is formed by the interior of the fixing cylinder 14 and the cavity of the piston rod 9 . This effect is reduced if necessary by transverse bores 17 in the bottom end of the fixing cylinder 14 , which are chosen accordingly.

To cushion the end stop is used in the cylinder bottom 5 attached ring plate 56 made of elastic mate rial.

The compression of the gas pressure spring happens pretty un damped, with the afterflow of the shock absorber fluid speed into the enlarging piston rod annulus 23 by the opening check valve 33 and is supported by the spring-loaded floating piston 20 under. This action keeps the shock absorber fluid below a certain pressure level, which prevents foaming and compensates for temperature expansion.

The rebound of the piston rod 9 is damped. A pressure builds up in the shrinking piston rod annulus 23 , which closes the check valve 33 . The shock absorber fluid can now only flow back 4 so that the damping of the rebound movement in this choke screw 27 is easily adjusted via the entities controlled by the throttling screw 27 throttle channel 25 in the double-wall annulus.

When the trailing axle not participate in driving, and is therefore to be raised, the pistons rod space 50 applied ness with compressed liquid 40 of the Einziehzylinder so that feed the free piston 48 through the piston stops 46, the piston rods 42 and thereby also the piston rod 9 of the gas spring cylinder 1 for retracting is forced. This causes the trailing axle to be raised.

Claims (8)

1. Hydraulically shock-absorbing gas spring acting in the direction of extension with a pressurized gas-filled cylinder ( 1 ), in which a unit formed as a hollow cylinder with an open inner end of the piston ( 8 ) and piston rod ( 9 ) is slidably guided, and with a surrounding one Annulus ( 23 ), which is filled with shock absorber liquid, which flows back and forth between the two chambers during the in and out movements of the piston rod ( 9 ), which have connection with one another via at least one throttle channel ( 25 ) and a check valve ( 33 ) , characterized in that the cylinder ( 1 ) is double-walled and the one shock absorber fluid chamber is formed by the double-wall annular space ( 4 ) between the cylinder outer wall ( 2 ) and the cylinder inner wall ( 3 ), that the other shock absorber fluid chamber is formed by the piston rod annulus ( 23 ) is formed between the piston rod ( 9 ) and the cylinder inner wall ( 3 ) and there ß the cylinder bottom limit of the shock absorber fluid chamber in the double-walled annular space ( 4 ) is formed by a slidably seated floating piston ( 20 ) which is spring-loaded in the sense that the shock absorber fluid is kept under pressure. 2. Gas spring according to claim 1, characterized by a floating piston ( 20 ) with its one end acting on the floating piston spring ( 21 ), which is designed as a helical compression spring, is arranged in the double-walled annular space ( 4 ) and with its other end on the cylinder bottom ( 5 ) supports. 3. Gas spring according to claim 1 and / or 2, characterized in that when retracting the overflow of the shock absorber fluid from the double wall annulus ( 4 ) in the piston rod annulus ( 23 ) back check valve ( 33 ) is an annular disc, which with a the double-walled annular space ( 4 ) in the vicinity of the end of the cylinder coverelseiti gene ( 1 ) covering ring installation ( 30 ) cooperates with a plurality of overflow bores ( 31 ). 4. Gas spring according to one or more of the preceding claims, characterized in that an externally accessible, adjustable throttle screw ( 27 ) is provided in the throttle channel ( 25 ) between the double-walled annular space ( 4 ) and the piston rod annular space ( 23 ). 5. Gas spring according to one or more of the preceding claims, characterized by a central progression spring ( 13 ) designed as a helical compression spring, one end of which cooperates with the piston rod ( 9 ) and the other end of which is supported on the cylinder base ( 5 ), the length this progression spring is chosen so that it begins to work in an intermediate position. 6. Gas spring according to claim 5, characterized in that the cylinder bottom end of the progression spring ( 13 ) is fastened and at this end a fixing cylinder ( 14 ) attached to the bottom of the cylinder protrudes into the spring so that when the free end of the fixing cylinder is immersed in the Piston rod cavity creates an additional gas end stop damping. 7. Gas spring according to one or more of the preceding claims, characterized by a plurality of evenly distributed on the circumference, the gas spring cylinder ( 1 ) surrounding pull-in cylinder ( 40 ), the piston rods ( 42 ) with the piston rod ( 9 ) of the gas spring cylinder ( 1 ) are connected. 8. Gas spring according to claim 7, characterized in that the piston rods ( 42 ) of the retracting cylinder ( 40 ) have a piston stop ( 46 ) at their cylinder inner end and a displaceable free piston ( 48 ) sits on them in front of them, the rod chamber ( 50 ) the pull-in cylinder ( 40 ) can be acted upon hydraulically and its cylinder space ( 52 ) is vented.