DE4414485A1 - Working cylinder actuatable by pressure medium - Google Patents

Description

State of the art

The invention is based on a pressure medium actuable Working cylinder according to the preamble of claim 1 specified genus.

Such is already known from DE 34 45 481 A1 Working cylinder with a damping device for one longitudinally guided and on a piston rod attached piston known in which to brake the Piston a damping bush when reaching an end position between a piston rod section and the piston is mounted in a suitable passage opening in the Cylinder head can immerse to the unhindered drain of pressure medium from a bordering the piston Throttle or interrupt the cylinder chamber. Pressure medium can then only be via a parallel connection Use the throttle screw to flow out to the cylinder connection. To at then return stroke of the piston from its end position a sufficiently large pressure medium flow in the flow To enable cylinder chamber is in the damping bush a plate-like check valve installed, which in a line connecting both sides of the damping bush  axially and radially extending channels. With this Damping device can be relatively good Achieve damping values; due to the built-in Damping bushing, the check valve and the additional, Connection with throttle screw arranged in the housing the result is a complex and costly design. The A large number of parts also increases the assembly effort for the working cylinder. The throttle screw is also suitable not for progressive damping. The one on the Piston rod fixed damping bush must open exactly the passage opening in the cylinder head be coordinated, resulting in an elaborate production leads.

Advantages of the invention

The working cylinder according to the invention with the characteristic In contrast, features of the main claim have the advantage that it has a high damping effect with simpler and cheaper Construction achieved. The working cylinder with Damping device comes with only a few parts and is also easy to manufacture. Furthermore, the Damping device from a rapid leakage of the piston its end position, so that relatively high Working speeds can be achieved with the working cylinder are. Furthermore, the damping device works relatively soft and avoids pressure surges, which too an unfavorable material load and thus one can lead to low lifespan.

By the measures listed in the subclaims advantageous further developments and improvements of the Main claim specified working cylinder possible. Designs according to the claims are particularly advantageous  2 or 3, which is a particularly space-saving and cost-effective design with good damping properties enable. Through the formation of all pressure medium channels the movably guided damping bushing, which at the same time as Seat valve works, becomes a simple, easy to manufacture and robust construction favors. More beneficial Refinements result from the other dependent ones Claims.

drawing

An embodiment of the invention is in the drawing shown and in the following description explained. Show it

Fig. 1 shows a longitudinal section through part of a pressure-operated cylinder and

Fig. 2 is a partial section through the cylinder according to Fig. 1 in another working position, in which the damping bush works as a check valve.

Description of the embodiment

Fig. 1 shows part of a fluid-actuable working cylinder 10 in a half section in which a cylinder tube 11 include a cylinder chamber 13 with a cylinder cover 12 and a not-drawn cylinder bottom, in which a piston 14 is guided slidably. The piston 14 is fastened to a piston rod 15 which is stepped down several times and which leads outwards via a sealing sleeve 16 arranged in the cylinder cover.

In the cylinder cover 12 , an annular space 17 is formed which has a connection in the radial direction to a cylinder connection 18 and which is connected in the axial direction via an annular passage opening 19 to a cylinder chamber 21 which is separated from the piston 14 in the cylinder space 13 and from which Piston 14 and the cylinder cover 12 is limited.

In the working cylinder 10 shown in FIG. 1, the piston 14 is in the vicinity of its end position, into which it is just entering. In the area of the cylinder chamber 21 , a damping bushing 22 is axially movably guided on the stepped piston rod 15 , the stroke of which is limited by two stops 23 , 24 on the piston rod side. The first stop 23 assigned to the passage opening 19 is formed by an annular shoulder 25 , via which the piston rod 15 merges into a guide section 26 with a smaller diameter, on which the damping bush 22 is guided. This guide section 26 merges via a second annular shoulder 27 into a rod section 28 with a reduced diameter, on which the piston 14 is fastened. The piston 14 forms the second stop 24 with its side facing the cylinder chamber 21 .

The damping bush 22 is essentially sleeve-shaped, its axial length approximately corresponding to its outer diameter and in particular being a multiple of its wall thickness. The damping bush 22 has a first end face 29 which faces the first stop 23 and forms a seat valve 31 together with the first annular shoulder 25 working as a valve seat, so that the damping bush 22 can work as a check valve. At the first end face 29 , the damping bushing 22 is chamfered on the outside in order to facilitate entry of the damping bushing 22 into the passage opening 19 . Starting from the first end face 29 , a plurality of throttle grooves 30 extend in the outer circumferential surface 32 , which are distributed uniformly along the circumference, run in the axial direction and end near the other, second end face 33 of the damping bush 22 . In this second end face 33 , which faces the piston 14 , a plurality of radial grooves 34 run . These radial grooves 34 are part of a pressure medium connection 35 , which is controlled by the seat valve 31 and which is designed essentially as grooves 26 running spirally or helically on the inner wall of the damping bushing 22 . These grooves 36 connect the two end faces 29 , 33 of the damping bush 22 to one another, so that an essentially unthrottled pressure medium connection 35, controlled by the check valve 31, is created between the cylinder connection 18 and the cylinder chamber 21 . The damping bush 22 is guided with a relatively large radial play on the piston rod 15 , while its outer diameter is so matched to the diameter of the passage opening 19 that a good damping effect can be achieved.

The damping bush 22 is thus part of a damping device 38 in the working cylinder 10 , which enables the piston 10 to enter its end position in a damped manner and, on the other hand, allows it to run out of its end position as quickly as possible. A second cylinder chamber delimited by the piston 14 and by the cylinder bottom (not shown) is designated by 39 .

The mode of operation of the working cylinder 10 is explained as follows, the function of the damping device 38 being discussed in particular.

In Fig. 1 the running of the piston 14 is shown in its end position, wherein the damping device 38 is effective. The piston 14 is pressurized in the second cylinder chamber 39 and / or a pulling load acts on the piston rod 15 on the outside. The pressure medium flowing out of the first cylinder chamber 21 was able to flow out unthrottled to the cylinder connection 18 via the latter before the damping bush 22 is immersed in the passage opening 19 . When the damping bushing 22 is moved into the passage opening 19 , this outflow is throttled and the pressure builds up in the first cylinder chamber 21 . This pressure of the first cylinder chamber 21 acts on the second end face 33 and presses the damping bushing 22 with its first end face 29 against the stop 23 serving as a valve seat, so that the seat valve 31 shuts off the pressure medium connection 35 . Pressure medium from the first cylinder chamber 21 can only flow throttled via the throttle grooves 30 to the cylinder port 18 . By appropriate design of the throttle grooves 30 , progressive damping can be achieved. The relatively large radial play between the damping bush 22 and the piston rod 15 allows a tight fit in the passage opening 19 , so that good damping values can be achieved without the damping bush 22 tending to lock.

Fig. 2 now shows in the partial longitudinal section of the working cylinder 10 the situation when the piston 14 moves out of an end position and the function of the damping device 38 is largely canceled by the damping bushing 22, which now functions as a check valve, in order to achieve a rapid extension. The cylinder connection 18 is pressurized, which acts in the annular space 17 on the first end face 29 of the damping bush 22 . As a result of the somewhat lower pressure level in the first cylinder chamber 21 , the damping bushing 22 is pushed with its second end face 33 against the second stop 24 on the piston 14 , whereby the seat valve 31 opens. Via the seat valve 31 working as a check valve, a sufficiently large pressure medium flow can now flow from the cylinder connection 18 via the pressure medium connection 35 and the radial grooves 34 into the first cylinder chamber 21 and load the piston 14 , so that the piston 14 moves relatively quickly out of its damped end position can. When the damping bushing 22 has completely moved out of the cylinder cover 12 , pressure medium can flow unthrottled from the cylinder connection 18 through the passage opening 19 into the cylinder chamber 21 and the piston 14 can perform a rapid movement.

By designing the damping device 38 with a single movable part, namely the damping bushing 22 , particularly effective and shock-free damping can be achieved with the simplest of means. By designing the damping bushing 22 as a movable seat valve member, on which the throttle grooves 30 and the pressure medium connection 35 are additionally arranged, a particularly simple and inexpensive damping device can be achieved.

Of course, changes can be made to the embodiment shown without departing from the spirit of the invention. The shape and arrangement of the throttle grooves and the pressure medium connection on the damping bushing 22 can thus be varied. The annular shoulder 25 serving as the valve seat and first stop can also be designed on an additionally attached ring. Under certain circumstances, it may also be expedient to form a suitable slide valve with the damping bushing 22 instead of the seat valve 31 .

Claims (9)

1. Pressure-actuated working cylinder with a piston guided in a cylinder space, which is attached to a piston rod and is displaceable in the cylinder space between two end positions and with a damping device for braking the piston as it moves into an end position, with a damping bushing arranged on the piston rod in a passage opening immersed and a throttled outflow of pressure medium from a cylinder chamber delimited by the piston to a cylinder connection for a slow entry of the piston into its end position and with a check valve assigned to the damping device, which unhindered pressurization of this cylinder chamber from the cylinder connection for a rapid discharge of the piston allows its end position, characterized in that the damping bush ( 22 ) on the piston rod ( 15 ) between two piston rod-side stops ( 23 , 24 ) axially freely movable and that one end ( 29 ) of the damping bush ( 22 ) forms a valve ( 31 ) on the stop ( 23 ) associated with the passage opening ( 19 ), which valve takes over the function of the check valve. 2. Working cylinder according to claim 1, characterized in that the damping bush ( 22 ) is sleeve-shaped and forms a seat valve ( 31 ) through an end face ( 29 ) with the piston rod-side stop ( 23 ) and that on its outer lateral surface ( 32 ) throttle grooves ( 30 ) are arranged. 3. Working cylinder according to claim 1 or 2, characterized in that the controlled by the check valve ( 31 ), between the two end faces ( 29 , 33 ) of the damping bush ( 22 ) extending pressure medium connection ( 35 ) is arranged in the damping bush ( 22 ). 4. Working cylinder according to claim 3, characterized in that the pressure medium connection ( 35 ) is formed by spiral grooves ( 36 ) in the inner wall ( 37 ) of the damping bushing ( 22 ). 5. Working cylinder according to one of claims 1 to 4, characterized in that the damping bush ( 22 ) is guided with a relatively large radial clearance on the piston rod ( 15 ). 6. Working cylinder according to one of claims 1 to 5, characterized in that the piston rod ( 15 ) on an annular shoulder ( 25 ) merges into a guide section ( 26 ) with a smaller diameter on which the damping bush ( 22 ) is guided and that this annular shoulder ( 25 ) serves as a valve seat and as a stop ( 23 ). 7. Working cylinder according to claim 6, characterized in that the guide section ( 26 ) via a second annular shoulder ( 27 ) merges into a rod section ( 28 ) on which the piston ( 14 ) is arranged, which in turn is the second stop ( 24 ) for the damping bushing ( 22 ) forms. 8. Working cylinder according to one of claims 1 to 7, characterized in that the passage opening ( 19 ) is arranged in a cylinder head ( 12 ) and the diameter of which is matched to the outside diameter of the damping bushing ( 22 ), in particular has a narrow clearance. 9. Working cylinder according to one of claims 1 to 8, characterized in that the sleeve-shaped damping bush ( 22 ) has the same size end faces ( 29 , 33 ), and their axial length corresponds approximately to their outer diameter, in particular a multiple of the wall thickness of the damping bush ( 22 ) is.