DE3730808A1 - Locking device for hydraulic or pneumatic working cylinders - Google Patents

Abstract

A locking device for hydraulic or pneumatic working cylinders (10) has a working piston (22) which is provided with segments (25, 35) which are arranged around and are connected to its periphery, extend along the piston and have at their free end a hook part (26, 49) which is widened on the cylinder-wall side, can be engaged in a recess (41, 44) in the cylinder wall and has the locking pistons (17, 31) which can each be moved relative to the working piston (22) and which can be pushed via the corresponding engaged hook parts (26, 49) and lock the latter in a radially fixed manner. In this arrangement, the hook parts (26, 49) can be accommodated in the recess (41, 44) in a positive-locking manner. In addition, as viewed in the direction of the segments (25, 35) to be moved towards the recess (41, 44), a ramp-like widened portion (53) of the cylinder wall is provided directly in front of the recess (41, 44), as a result of which the segments (25, 35) can be radially compressed and clamped. The end face of the locking pistons (17, 31) can be run against an end face of the hook parts (26, 49) so that the locking piston (17, 31) situated over the recess (41, 44) can be displaced by means of the segments (25, 35) until the latter engage in the recess (41, 44). The locking piston (17, 35) then returns again into its locking position. <IMAGE>

Description

The invention relates to a locking device for hydraulic or pneumatic working cylinders with one Working piston, which is arranged around its circumference and with this connected slats is provided, which along the Piston extend and a cylinder at its free end have thickened hook part on the wall, which in one Recess can be engaged in the cylinder wall, and with a Locking piston which is movable relative to the working piston and which can be pushed over the indented hook parts and these radially immovable locks, the end face of the lock butt with one end face of the hook parts bar is so that the locking piston located over the recess can be moved by means of the hook parts until it is Insert into the recess and then the locking piston as who returns in his locked position.

In such, known from DE-AS 11 63 680 Ver Locking device are around the piston in the circumferential direction Arranged pawls provided that a thickened hook part exhibit. The pawls are around the piston longitudinal axis pivoted on the piston outer surface. To Verrie the pawls move a locking bolt, the beveled edge ver swiveling the pawls causes. This pivoting builds in one with the jack connected spring element, for example a compliant Pillow, a return force. Another move  of the locking bolt outputs from the cylinder wall then the hook parts due to the click into place. The locking bolt then pushes over the latches and locks them in ra dialer direction. This construction is due to the storage the individual handles extremely complex and the additional Chen, the return force generating spring elements are very susceptible to wear and tear. For example, the Storage with compliant pillows due to material fatigue particularly susceptible to faults, so that they are not excluded can that the individual pawls with the locking bolt lock and be damaged. For example due to material fatigue in only one of the pawl bearings there is already a risk that the locking device direction becomes ineffective. The hook parts are only along a shoulder resilient to tension in the cylinder wall at. In the case of pressure loads, in particular because of the Generous storage of the pawls a displacement of the piston to be possible.

In another mecha known from DE-AS 12 52 066 African locking device is the working cylinder with connected to a spring basket, from the annular foot part several slats evenly distributed around the circumference stand. The slats end at the spring basket opposite free end into a thickened hook part, the thickening protruding from the lamella surface in Is directed towards the inner wall of the cylinder. The slats are biased in the radial direction so that the outer circumference ver points of the hook parts in the distance to the inside of the cylinder to run. In the end position to be locked, this indicates  Cylinder housing an area with a larger inner diameter with the shoulder at the transition area from the work area with a smaller diameter to the end area with a larger one Diameter serves as the contact edge for the hook part. In the end the larger diameter area is an annular barrier piston provided, which has a first area, wel cher tight between the working piston area and the cylinder housing is accommodated in a longitudinally displaceable manner. On the the hook part of the Slat-facing side is the locking piston with a ring flange provided on the outside of the working piston area and has a decreasing strength. Has the working piston and the associated spring cage one too locking end position is reached, the contact edge of the Part of the hook opposite the contact shoulder of the cylinder wall, but points from this, since the lamella is radially inward is biased towards a distance. To the hook to move part radially outwards and against the investment school ter of the cylinder housing, the locking piston with a print on the side facing away from the ring bead medium acted upon and thereby towards the hook part of the Slat moved. The ring bead pushes between piston and lamella and presses their hook part due to its increasing strength radially outward on the plant shoulder in the cylinder wall. So that the working piston in its final position to stop are radial tax pins provided in the working piston area, which on a end stop of the cylinder housing in the verrie applicable end position. To secure locking To ensure the locking piston must continuously through the pressure medium are applied, since a low Ver shift of the locking piston is already one of the radial  internally pre-stressed slats, which in turn movement of the piston rod is connected. Because the facility shoulder in the cylinder wall housing is chamfered to the off to facilitate the backward movement of the hook part, already ge slightest displacements of the locking piston to a displacement Exercise of the working piston. For a constant pressurization To ensure the locking piston is a valve control construction with numerous movable parts from need that is structurally very complex and prone to failure. During the locking process, it is not excluded that for example due to excessive radial preload in Towards the middle, the end face of the ring flange of the barrier no longer piston between the hook part of the lamella and Piston side can slide, but the end faces on butt the other and the hook part no longer on the locking edge can be created, thus ver the end position locking says. In addition, in such a jammed position a bending of the elongated, slender lamellar body take place, whereby the entire locking device radio becomes incapable of functioning. By providing only one contact edge or area between the hook part and shoulder of the cylinder house is a mechanical interlocking of these two construction parts given that only axial tensile loads in Rich spring basket base resists. Axial pressure loads in the opposite direction must go through the locking pins or the locking piston.

The object of the present invention is a robust, con structurally simple and permanent locking creating device.  

According to the invention this is achieved in that the hook parts can be positively received in the recess, that in the direction of the lamella to be moved onto the recess len seen, just in front of the recess a ramp term thickening of the cylinder wall is provided, whereby the Slats are radially compressible and can be tensioned. By the positive reception of the hook parts in the recess the cylinder wall is a mechanical toothing between these two parts created in the axial direction so probably withstands tensile and compressive loads. The slats are not biased and run over almost the whole stroke range without interaction with the cylinder wall inside. Due to the immediately before the recess ordered ramp-like thickening, the slats become radial biased inwards and push the front with the Locking piston in the axial direction until the hook parts can move into the recess. This radial engagement movement is reduced by the tension built up previously supports, so that the hook parts quickly and safely their shape achieve a coherent fit in the recess. After that pushes the locking piston in a manner known per se via the Slats in the hook part and locks them in the radial direction. The arrangement of the ramp-like thickening also leads to the beneficial effect of a braking effect of the working col bens, shortly before it has reached its end position. This is determined by the frictional force between the fins and the ramp-like thickening achieved, caused by the too increasing restoring force of the deflected slats. To ent It is only necessary to lock the locking piston as far to move the hook parts out of the recess again can exit. After the ramp-like ver  Thickening during the disengagement movement, whereby here a start brake the slats are perfect again relaxes and does not interact with the work tendency parts of the cylinder. The locks according to the invention lungs device comes essentially with three fit components, namely an area of the cylinders wall in which the ramp-like thickening or the recess is provided, a corresponding training of the profile the hook part of the slats, so that they form one hand fit snugly in the recess and on the other hand forehead hit the locking piston on one side. The locking piston itself is to be provided with a pressure medium that the locking piston the tendency always lends itself to the recess push. To unlock it only has to be provided to move the locking piston out of this position so that the hook elements can snap out of the recess again nen. This constructively extremely simple and robust Verrie gelling device ensures a permanent failure free work.

This is realized in a structurally particularly simple manner by that the recess is formed by an annular groove.

The annular groove expediently has a V-shaped section profile on.

A particularly robust and easy to manufacture lock lungsvorrichtung is created in that a one piece GE locking sleeve is provided that works with piston is connectable. The one-piece training enables for example, the production from a single tube cut, the slats milled or cut out  will. The slats are from a bottom Ring up, by simple coupling means, for example by a thread, can be connected to the working piston is.

A working cylinder is particularly easy to construct the connectable intermediate piece is provided on the inside side the recess is provided and in which the ratchet ben is arranged. These easy to machine components can also be retrofitted to a working cylinder can be scheduled so that existing work cylinders can be converted or integrated into a production series can be accommodated without existing cylinders / To have to laboriously change the piston. The fiction appropriate locking device comes, as he already did imagines locking with the three essential components rifle, appropriately designed cylinder wall and lock piston, out.

This is particularly simple in terms of construction light that the locking piston against the force of a pretensioned ten spring is slidable. This is particularly constructive fold design looks on the facing away from the slats One side of the ram between this side and one Abutment clamped and preloaded spring before the Locking piston pushes up to the recess.

The locking piston can also expediently counter pressure medium adjustable.

The end face of the hook part is advantageously abge slants. The locking piston is through the beveled forehead  side moved so far that the hook parts in the Ausneh indentation is a gentle glide along the possible on both ends during the engagement movement.

This is achieved particularly advantageously in that the Face of the locking piston corresponding to the face of the hook part is chamfered, so that it is approximately parallel get lost.

Particularly inexpensive and to the exclusion of Verklemmungsmög possibilities is the sliding movement on the one hand between the hook part and the inside of the cylinder wall and on the other hand between the hook part and locking piston in that each lamella has a roof-shaped hook part, the end face of which is chamfered in such a way that the slope has a somewhat different inclination angle α compared to the angle β , which the rising roof surface, seen in the longitudinal direction from the slats floor.

A particularly constant sliding of the hook parts without sudden or jerky encounter with the Zylin derwand is given by the fact that the slat body such at a distance from the inside of the cylinder and the outside of the piston runs that the outermost circumference of the hook parts along the Cylinder wall slides.

A particularly gentle on the material and therefore the service life the locking device increasing arrangement is thereby given that the level of the ramp-like thickening in radia direction corresponds to the incision depth of the recess, so that the bottom of the recess is in alignment with the  Cylinder wall in front of the ramp-like thickening. The Slats are thus again after they are inserted into the recess completely relaxed, so that in the material in the holding state no clamping forces with internal restoring forces available are.

It is useful for each end position of the work cylinder a locking device is provided.

The invention will become more apparent from the enclosed drawings explained and described. Show it:

Fig. 1 devices is a longitudinal section of a working cylinder according to the invention with two locking,

FIGS. 2a to 2d is a detailed section of a locking device OF INVENTION to the invention in different positions during a Ver lock-out operation, and

Fig. 3 is a perspective view of a part of a locking device according to the invention with a part of the circumferential slats.

A working cylinder 10 shown in Fig. 1 has a multi-part cylinder housing 11 which has a closed cylinder bottom 12 , a first intermediate piece 13 , a cylinder tube 14 , a second intermediate piece 15 and a cylinder head 16 . The aforementioned parts of the cylinder housing 11 are connected to one another in the order mentioned via screw connections. The cylinder tube 14 is not shown in its entire length, since this length can vary depending on the stroke of the working cylinder without the other components having to be changed. In the cylinder base 12 , which is tightly screwed to the first intermediate piece 13 , a first locking piston 17 is arranged which is movable in the axial direction, the side of which facing the cylinder base 12 represents a movable end wall of a first piston chamber 18 on the bottom side of the cylinder. On the opposite side, the first locking piston 17 forms a movable end wall of a second piston chamber 19 .

In the first piston chamber 18 , a plurality of compression springs 20 are arranged which press the first locking piston 17 in the direction of the second piston chamber 19 . The second piston chamber 19 is separated from the first piston chamber 18 by a seal 21 .

In the cylinder tube 14, a piston 22 is received, which is provided at its end facing the first locking piston 17 facing end with a first locking bush 23rd

The first locking sleeve 23 has a ring-shaped bottom part 24 , which is screwed ver with a central pin 28 of the piston rod 27 , which extends through the working piston 22 . Eight slats 25 protrude from the annular base part 24 and end in a thickened hook part 26 .

The working piston 22 is opposite the first Verrie gelungsbüchse 23 connected to a piston rod 27 which penetrates the end of the cylinder head 16 .

The piston rod 27 is connected via a pin 28 to the working piston 22 . Between the piston rod 27 and the working piston 22 , an annular bottom part 29 of a second locking bush 30 is arranged, which is pushed onto the pin 28 and the piston 22 is clamped between the piston rod 27 and the working piston. The pin 28 which protrudes through the working piston 22 is connected via the aforementioned screw connection of the first locking bush 23 , so that this screw connection ben ben assembly, first and second locking bush 23 , 30 and Kol rod 27 holds.

On the piston rod 27 , a second locking piston 31 is pushed on, which is designed as an annular piston and is movable along the piston rod 27 . The second locking piston 31 seals a third piston chamber 33 via a seal 32 , in which the slats 35 of the two locking latch 30 projecting in the direction of the second locking piston 31 from the annular base part 29 are received. The third Kol benraum 33 is abge seals working piston side via seals 36 .

The second locking piston 31 puts on the end face 37 of the cylinder head 16 side facing a movable from the end of a fourth piston chamber 38. In the fourth piston chamber 38 a plurality of pressure springs 34 are arranged, which push the second locking piston 31 toward the third piston chamber 33. The movement of the second locking piston 31 in Rich direction third piston chamber 33 is limited by a stop 39 in the second intermediate piece 15 .

In the position shown in Fig. 1, the second locking piston 31 rests on an annular end face at the stop 39 . The second locking piston 31 is provided with an annular extension piece 40 which extends in the direction of the third piston space 33 beyond the stop 39 and is received between the piston rod 27 and the inside of the second intermediate piece 15 . The annular extension piece 40 covers a recess 41 in the wall of the second intermediate piece 15th The recess 41 is designed as an annular groove 45 with an approximately V-shaped profile.

The first locking piston 17 at the cylinder bottom end of the working cylinder 10 is designed as a solid piston and is provided with a corresponding pin-shaped extension piece 43 , which covers a recess 44 in the inner wall of the first intermediate piece 13 , the recess 44 also being designed as a V-shaped annular groove 42 . The first locking piston 17 is pressed via compression springs 20 in the direction of the second piston chamber 19 and, in the illustration shown in FIG. 1, lies against a stop 46 in the inner wall of the first intermediate piece 13 .

The second piston chamber 19 can be acted upon by a pressure medium via a connection 47 . The third piston chamber 33 can also be acted upon by a pressure medium via a connection 48 .

In the position shown in FIG. 1, the working cylinder 10 is locked in an end position via the second locking bush 30 and the second locking piston 31 . Hook parts 49 of the slats 35 are positively received in the annular groove 45 of the second intermediate piece 15 . The annular extension piece 40 of the second locking piston 31 is pushed over the hook parts 49 and locks them against radial disengagement movements.

The working piston 22 rests against a stop 50 in the cylinder tube 11 , which limits its movement in the direction of the cylinder head 16 . A corresponding stop 50 'limits the movement of the working piston 22 in the opposite direction.

In FIGS. 2a to 2d the end of the locking operation of the second locking sleeve 30 is shown step by step, wherein Fig corresponds. 2d in Fig. Locked position shown. 1

As already mentioned, the inside of the second intermediate piece 15 is provided with an annular groove 45 which has a V-shaped profile.

The annular third piston chamber 33 is delimited on the left side by the working piston 22 on the right side by the second locking piston 31 and in the radial direction by the inside of the intermediate piece 15 or the outside of the piston rod 27 . On the pin 28 of the piston rod 27 , the annular bottom part 29 of the second locking bush 30 is pushed and, as described above, clamped. From the bottom part 29 are lamellae 35 , the lamellar bodies 51 at a distance and parallel to the inside of the first intermediate piece 15 or to the outside of the piston rod 27 . The hook parts 49 of the slats 35 have a ge see in section, roof-shaped thickening 52 which rises from the inner surface of the second intermediate piece 15 facing slats body surface. The roof-shaped thickening 52 is designed so that it fits exactly in the annular groove 45 .

Seen from the direction of the slat bottom part 29 on the annular groove 45 , immediately before the annular groove 45 a ramp-shaped thickness 53 of the inside of the second intermediate piece 15 is seen before.

The ramp-shaped thickening 53 has a rectilinear ver ramp 54 which merges into a straight region 55 extending parallel to the piston rod surface, to which the inclined surfaces of the annular groove 45 adjoin. The depth of cut of the annular groove 45 is such that its bottom lies in alignment 56 with the inside of the second intermediate piece 15 .

The second locking piston 31 abuts the stop 39 on the inside of the second intermediate piece 15 and its annular extension piece 40 extends over the annular groove 45 and the straight region 45 of the ramp-shaped thickening 53 .

The annular extension piece 40 is ver seen on its end facing the slats 35 with a bevel 57 , the angle of inclination α is approximately equal to that of a bevel 58 on the end of the hook part 49 facing the second locking piston 31 . The bevel 58 of the hook part 49 is provided on the side facing the piston rod 27 and stands out from the lamella body surface facing this side. The angle of inclination β of a first roof surface 59 of the hook part 49 rising from the slat body 51 is different from the angle of inclination α and, in the embodiment shown in FIGS. 2a-d, is slightly larger than the angle α , so that the imaginary extension lines of the slope 58 or cut the roof surface 59 at a point 60 located in the direction of the central longitudinal axis of the piston rod 27 .

In the position shown in Fig. 2a, the lamella body 51 runs parallel and the lamella 35 lies at its outer circumferential point of the thickened hook part 49 with a dachför shaped profile on the inside of the second intermediate piece 15 . When the piston rod 27 moves in the direction of the second locking piston 31 , the hook part 49 thus slides along this surface.

When the piston rod 27 is shifted further to the right, the hook part 49 hits the ramp 54 and the lamella 35 is bent in the direction of the piston rod 27 (cf. FIG. 2b) and is thus preloaded.

With further feed, the bevel 58 of the hook part 49 meets the bevel 57 of the second locking piston 31 and moves it with further feed to the right, so that it moves away from the stop 39 (see FIG. 2b). Upon further advancement of the hook member 49 engaged in the annular groove 45 and the second locking piston 31 pushes due to the springs 34 (see FIG. 1) via the depressed into the groove 45 hook part 49 (see. Fig. 2d).

Characterized in that the roof surface 59 of the hook part 49 a ande ren inclination angle β when the inclination has 58 (α), a self-inhibition of the hook portion 49 between the inner surface of the second intermediate piece 15 and the annular extension 40 of the second locking piston 31 located is avoided ver. It is therefore excluded that a malfunction of the locking device occurs by jamming the moving parts during the locking process.

To unlock the locking device shown in FIG. 2d or FIG. 1 via the second locking bush 30 or the two locking pistons 31 , the third piston chamber 33 is pressurized via the connection 48 with pressure medium. The inflowing medium simultaneously exerts a compressive force on the third piston chamber 33 in the direction of the second piston chamber 19 and on the second locking piston 31 in the direction of the fourth piston chamber 38 . If this compressive force piston to the second barrier 31 is greater than that of the hook portions 49 frictional force and acting the force of the springs 34, so the second locking piston 31 moves to the right and outputs the hook portions 49 to disengage from the annular groove 45 freely. The piston rod 27 with the attached components moves to the left until it has reached its other end position. Then, as previously described in connection with FIGS. 2a to 2d, the hook parts 26 of the slats 25 of the first locking bush 23 slide along the inner surface of the first intermediate piece 13 until they meet the ramp-shaped thickening 53 . The end faces of the hook parts 26 , which are beveled to the same extent as described in connection with FIGS. 2a to 2d, push the first locking piston 17 to the left until they engage in the annular groove 45 and then the first locking piston 17 is pushed over them.

In this position, the working cylinder 10 is locked in its second end position.

To unlock from this position, the second piston chamber 19 is pressurized via the port 47 with pressure medium, whereby the first locking piston 17 is pushed back to the left, the hook parts 26 of the slats 25 disengage from the annular groove 45 and a movement of the piston rod 27 to the right in the direction of the other end position is enabled again.

To control the unlocking or locking process, no additional connections or valves are therefore necessary, but are controlled via the connections 47 , 48 , which act alternately on the working piston ben 22 with pressure medium.

The material of the intermediate pieces 13 and 15 is high-strength steel, the surface of which has also been made wear-resistant. This ensures exact guidance of the hook parts of the slats during the locking and unlocking process, which allow permanent use.

As already mentioned above, the deflection of the slats leads to a force-consuming bending of the slats after hitting the ramp 54 , so that an increased resistance is opposed to the pressure medium. This leads to the fact that damping takes place immediately before reaching the end position.

In the embodiment shown in Fig. 1 an additional Lich adjustable throttle screw 65 is provided, which closes the bore 66 and 67 and is adjustable such that the speed of the piston rod 27 can be varied shortly before reaching the end position depending on the medium flow rate set.

In the embodiment shown in FIG. 1, two locking devices are provided for each end position of the piston rod 27 .

Of course, it is also possible to have only one lock provision device and to ver only in one end position latch.

In the exemplary embodiment shown in FIG. 1, the first 17 and second locking pistons 31 were acted upon by compression springs 20 and 34, respectively. In further execution examples, not shown here, this pressurization takes place via a pressure medium.

The locking sleeves 23 and 30 (see FIG. 3) are made in one piece. The material is a highly stressable steel which, in addition to being very strong, also has good elasticity. In the second locking bush 30 shown in FIG. 3, only three of the eight slats 35 distributed around the circumference are shown. The ring-shaped bottom part 29 is used for attachment to the piston rod 27 . The lamellar bodies 51 have a cylindrical wall section-like shape and run in a straight line and parallel to one another. The lamellar bodies 51 are sufficiently stable to absorb compressive forces when the bevel 58 of the hook parts 49 impinges on the bevel 57 of the locking piston. At the same time, they are also able to absorb pressure and tensile forces, such as occur with hook parts 49 locked in the annular groove 45 . By a correspondingly strong design of the thickness of the lamellar body 51 , a ver increased braking effect is achieved when the hook parts 49 hit the ramp 54 , so that, for example, the aforementioned throttle screw 65 can be used. The bending of the slats 35 leads to a radially outward bias of the slats, which is sufficient to press the hook parts 49 into the groove 45 . In the engaged locking position, the slats are then completely relaxed again, so that in this state no bending moments act on the slats in the radial direction.

Claims (13)

1. Locking device for hydraulic or pneumatic table cylinder with a working piston, which is provided with arranged around its circumference and connected to lamellas, which he stretch along the piston and have at its free end a thickened part of the cylinder wall side hook part, which in a Ausneh mung in the cylinder wall, and with a locking piston which is movable relative to the working piston and which is slidable over the indented hook parts and locks them radially immovably, the end face of the locking piston with an end face of the hook parts is abuttable so that the locking piston located above the recess can be moved by means of the hook parts until they move into the recess, and the locking piston then returns to its locking position, characterized in that the hook parts ( 26 , 49 ) form-fit in the recess ( 41 , 44 ) are recordable, that in the direction of the A recess ( 41 , 44 ) to be moved slats ( 25 , 35 ), immediately in front of the recess ( 41 , 44 ) a ramp-like thickening ( 53 ) of the cylinder wall is provided, whereby the slats len ( 25 , 35 ) are radially compressible and clampable . 2. Locking device according to claim 1, characterized in that the recess ( 41 , 44 ) is formed by an annular groove ( 42 , 45 ). 3. Locking device according to claim 1 or 2, characterized in that the recess ( 41 , 44 ) has a V-shaped profile. 4. Locking device according to claim 1 or one of the following, characterized in that a one-piece locking sleeve ( 23 , 30 ) is seen before, which can be connected to the working piston ( 22 ) and is provided with the slats ( 25 , 35 ). 5. Locking device according to claim 1 or one of the following, characterized in that an intermediate piece ( 13 , 15 ) which can be connected to a working cylinder tube ( 14 ) is provided, on the inside of which the recess ( 41 , 44 ) is provided, and in which the Locking piston ( 17 , 31 ) is arranged. 6. Locking device according to claim 1 or one of the following, characterized in that the locking piston ( 17 , 31 ) against the force of a pre-tensioned spring or springs ( 20 , 34 ) is displaceable. 7. Locking device according to one of claims 1 to 5, characterized in that the locking piston ( 17 , 31 ) is adjustable against the force of a pressure medium. 8. Locking device according to claim 1 or one of the following, characterized in that the end face of the hook part ( 26 , 49 ) is chamfered ( 58 ). 9. Locking device according to claim 1 or one of the following, characterized in that the end face of the locking piston ( 17 , 31 ) accordingly the end faces of the hook parts ( 46 , 49 ) beveled ( 57 ) so that they run approximately parallel ver . Is 10. A locking device according to claim 1 or one of the following, characterized in that each blade, an approximately roof-shaped in cross-section hook portion (26, 49) whose end face in such a way abge bevels (58) that the bevel (58) has a slightly ver different angle of inclination α compared to the angle β , which the rising roof surface ( 59 ), seen in the longitudinal direction from the slat floor. 11. Locking device according to claim 1 or one of the following, characterized in that the lamellar body ( 51 ) extends at a distance from the cylinder wall inside and to the piston rod outside and that the outermost circumferential point of the hook parts ( 26 , 29 ) slides along the cylinder inner wall side. 12. Locking device according to claim 1 or one of the following, characterized in that the height of the ramp-like thickening ( 53 ) in the radial direction corresponds to the incision depth of the recess ( 41, 44 ), so that the bottom of the recess ( 41 , 44 ) in an alignment line ( 56 ) with the cylinder wall surface in front of the ramp-like thickening ( 53 ). 13. Locking device according to claim 1 or one of the following, characterized in that a locking device is provided for each end position of the working cylinder ( 10 ).