DE9418129U1 - Hydraulic cylinder - Google Patents

Description

Hydraulic cylinder

The invention relates to a hydraulic cylinder with a connecting part provided in the area of the delivery lines according to the preamble of claim 1.

In known hydraulic cylinders, respective connection holes for the delivery lines are provided in the area of a cylinder head and/or a cylinder base, through which a working piston that can be moved into different stroke positions in the cylinder working chamber can be pressurized with a hydraulic fluid. To dampen the piston movement before reaching the respective end positions in the cylinder interior, respective throttle holes are provided in the cylinder head or the cylinder base to accommodate
Attenuators integrated, with which the technical
The costs involved in both manufacturing and repairing such hydraulic cylinders are disadvantageously increased.

The invention is based on the object of creating a hydraulic cylinder whose working cylinder enables a structurally simple adaptation to different damping parts in the connection area to the conveyor lines with little technical effort.

Starting from a hydraulic cylinder according to the preamble of claim 1, the invention solves this problem with the features of the characterizing part of claim 1. With regard to essential further embodiments, reference is made to claims 2 to 11.

The hydraulic cylinder designed according to the invention has a component, the connection block designed as a connection and control unit and located on the outer circumference of the cylinder tube, which can be manufactured with little effort and can be mounted in the area of the cylinder head or the cylinder base on different types of hydraulic cylinders with little effort and also enables the component to be quickly replaced. The connection block can be connected to the pressure medium via the at least one damping bore provided in addition to the pressure medium supply and directed into the cylinder interior in such a way that its outlet volume can be reduced with little effort during the piston movement and damping can be achieved that can be adjusted to different working parameters.

The connection block is provided with a flow channel connecting the pressure medium bore and the damping bore, into which a known throttle valve can be inserted, thus enabling easily accessible damping control on the connection block that can be adjusted with little effort.

With regard to further significant advantages and details of the invention, reference is made to the following description and the drawing, in which several embodiments of a hydraulic cylinder according to the invention are illustrated. In the drawing:

Fig. 1 is a detail view of a hydraulic cylinder in the area of a connection block in a first embodiment,

Fig. 2 is a detailed view of the connection block in a second embodiment,

Fig. 3 is a sectional front view of the terminal block along a line III-III in Fig. 2,

Fig. 4 a side view of the hydraulic cylinder with a working piston and the connection block according to Fig. 1,

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Fig.5

and 6 a side view similar to Fig. 4 with the working piston in different damping positions,

Fig. 7 is a side view similar to Fig. 4 with a double-acting hydraulic cylinder and two connection blocks of the first embodiment and

Fig. 8 is a side view similar to Fig. 4 with the connection block according to the second embodiment in the installed position.

In Fig. 1, a detail of a hydraulic cylinder, designated as a whole by 1, is shown, which is provided with a connecting part 4 on the outer circumference 2 of its cylinder tube 3, via which a delivery line (not shown) can be connected to the hydraulic cylinder 1 (Fig. 4) in a threaded connection bore 5 in such a way that a pressure medium can be brought into or removed from the cylinder interior 7 via a pressure medium bore 6 located in the cylinder wall 3' with simultaneous movement of a working piston 8.

In the hydraulic cylinder 1 (Fig. 4) according to the invention, the connecting part 4 is provided as a connection block 9 forming a connection and control unit,

which simultaneously has a flow channel 11 connecting the connection bore 5 both with the pressure medium bore 6 and with a damping bore 10 introduced into the cylinder tube 3 at an axial distance A from this bore (Fig. 1).

In the first embodiment of the connection block 9 according to Fig. 1, the flow channel 11 is designed as a groove 13 which, in the installed position of the connection block 9 on the cylinder tube 3, covers the pressure medium bore 6 on the one hand and the damping bore 10 on the other hand, wherein both the connection bore 5 and, parallel to it, a receiving bore 15 for a throttle element 16 open into the respective bottom region 14 of the groove 13.

Fig. 1, in conjunction with Fig. 4, shows that the damping bore 10 is arranged near the end region of the hydraulic cylinder 1 formed by the cylinder base 12 and that a precisely fitting damping element 18 of the throttle element 16 can be inserted into the damping bore 10.

In a second embodiment of the connection block 9 ¹ according to Fig. 2 or Fig. 8, the flow channel 11' is formed by a longitudinal bore 20 which runs parallel to the cylinder axis 19 in the installation position of the connection and control unit on the cylinder tube 3, into which on the one hand a first transverse bore 21 associated with the pressure medium bore 6' and

on the other hand, a second transverse bore 22 associated with the damping bore 10· opens (Fig. 8).

At one end, the conveyor line (not shown) opens into the longitudinal bore 20 in an expansion space 23 connected to the first transverse bore 21, and at the other end, the throttle element 16' (Fig. 8) is screwed into the longitudinal bore 20 while simultaneously intersecting with the second transverse bore 22.

The two previously described connection parts 4, 4' are, in a practical embodiment, fixed as a connection and control unit to the cylinder tube 3 in the installation position via a welded connection 24. It is also conceivable to fix the two connection and control units each via a detachable connection part (not shown) to the outer circumference 2 of the cylinder tube 3.

The illustration according to Fig. 4 illustrates an advantageous installation position of the connecting part 4, whereby the damping bore 10 interacting with it is provided near a closing plate 26 closing the cylinder interior 7 on the bottom side and this has a shaped projection 28 forming an annular space 27 towards the working space of the hydraulic cylinder 1. In the embodiment shown according to Fig. 4, the damping bore 10 is arranged so close to the closing plate 26 that the annular space 27 intersects with the damping bore 10 and

the working piston 8, which is in contact with the end plate 26, is limited in the annular space 27 (Fig. 6}.

Fig. 4 to 6 illustrate different phases of movement of the working piston 8 during its axial movement to the respective end area of the hydraulic cylinder 1. When moving in the direction of arrow 30 up to the stroke position according to Fig. 4, the pressure medium in the cylinder interior 7 is completely drained via the pressure medium bore 6 and the connection bore 5 and then the working piston 8 forms a residual cylinder chamber 31 towards the end plate 26, whereby the pressure medium located therein imparts increasing braking to the working piston 8 as it continues to move.

As the remaining cylinder space 31 (Fig. 5) becomes increasingly smaller, the moving working piston 8 closes the pressure medium bore 6 completely, whereby in a first phase the reduction of the passage cross-section in the area of the pressure medium bore 6 acts as a damping effect and a first braking of the piston movement takes place, and then in a second phase a further damping of the piston movement is determined by the passage capacity in the area of the damping bore 10 or the throttle element 16. With this combination of the pressure medium bore 6 and the damping bore 10 with the respective connection block 9,9', an effective damping part for the working piston 8 is created with little technical effort.

that can be used on different types of hydraulic cylinders 1.

A variable damping path can be formed via different distances A, A ¹ (Fig. 2) between the two bores 6 and 10, which can be varied, for example, on the connection block 9 (according to Fig. 1) according to the groove length N. With little technical effort, a change in the damping volume in the remaining cylinder space 31 is thus possible via the respective axial distance A, A ¹ between the pressure medium bore 6, 6' and the damping bore 10, 10', so that hydraulic cylinders 1 with different damping properties can be provided with little manufacturing effort.

In a practical design, the working piston 8 is provided with at least one piston ring 34 near its piston face 32, which passes over the two bores 6, 6' and 10, 10' in the end region 33, 33', 33'' of the hydraulic cylinder 1, so that a high level of wear resistance is ensured in this friction-loaded region. In the design of the piston 8 according to Fig. 8, two piston rings 34, 34' made of metal are provided, whereby the two middle sealing rings 35, 36 can also be made of metal.

Claims (11)

Expectations 1. Hydraulic cylinder which has on the outer circumference of its cylinder tube (3) at least one connecting part (4,4') which receives a delivery line in a connecting bore (5) and connects the delivery line to the cylinder working chamber (7) via a pressure medium bore (6,S ¹ ) made in the cylinder wall (3'), characterized in that the connecting part (4,4·) is designed as a connecting block (9,9') which acts as a connecting and control unit and which has a flow channel (11,11') which simultaneously connects a connecting bore (5) both to the pressure medium bore (6) and to a damping bore (10,-10 ¹ ) provided in the cylinder tube (3) at a distance (A,A') from this bore near the cylinder base (12). 2. Hydraulic cylinder according to claim 1, characterized in that the flow channel (11) as a in the installed position of the connection block (9) on the cylinder tube (3) on the one hand the pressure medium bore (6) and on the other hand the -2- · Damping bore (10) covering groove (13), wherein both the connection bore (5) and parallel to this a receiving bore (15) for a throttle element (16) open into the bottom region of the groove (13), 3. Hydraulic cylinder according to claim 1 or 2, characterized in that the receiving bore (15) in the connection and control unit is arranged coaxially to the damping bore (10) in the cylinder tube (3). 4. Hydraulic cylinder according to one of claims 1 to 3, characterized in that a precisely fitting damping member (18) of the throttle element (16) can be introduced into the damping bore (10). 5. Hydraulic cylinder according to claim 1, characterized in that the flow channel (II ¹ ) is formed by a longitudinal bore (20) which runs parallel to the cylinder axis (19) in the installed position of the connection and control unit on the cylinder tube (3), into which a first transverse bore (21) associated with the pressure medium bore (6 ¹ ) and a second transverse bore (22) associated with the damping bore (10') open on the one hand. 6. Hydraulic cylinder according to claim 5, characterized in that the delivery line opens into the longitudinal bore (20) at one end in an expansion chamber (23) connected to the first transverse bore (21) and the throttle 1 ft ·; -3- element (16') can be screwed into the longitudinal bore (20) while simultaneously intersecting with the second transverse bore (22). 7. Hydraulic cylinder according to one of claims 1 to 6, characterized in that the connection block (9,9') is welded to the cylinder tube (3) in the installed position. 8. Hydraulic cylinder according to one of claims 1 to 7, characterized in that the damping bore (10) cooperating with the connection block (9, 9') is provided near a closure plate (12) closing the cylinder interior (7) on the head and/or bottom side and this has a shaped projection (28) forming an annular space (27) towards the working space of the cylinder (1). 9. Hydraulic cylinder according to claim 8, characterized in that the annular space (27) with the damping bore (10) intersected. 10. Hydraulic cylinder according to one of claims 1 to 9, characterized in that the pressure medium bore (6) and the damping bore (10,10 ¹ ) have an axial distance {A,A ¹ ) determining the damping volume before the end of stroke position of the working piston (8). 11. Hydraulic cylinder according to one of claims 1 to 10, characterized in that the cylinder working chamber (7) · movable working piston (8) has a piston ring (34,34') designed as a metal ring in its jacket surface area which travels over the pressure medium bore (6,6·) and/or the damping bore {10,10') during the stroke movement. ·