DE4009431A1 - AUTOMATIC LINE COUPLING FOR RAIL VEHICLES - Google Patents

Description

The invention relates to an automatic line coupling for with automatic couplings equipped rail vehicles, with a relative to a housing part axially displaceable pipe part, the A coupling mouthpiece at the front for coupling pressure-tight a corresponding pipe part of an identical design Counter clutch forms, the coupling mouthpiece in the uncoupled State protrudes in front of a dome level and during coupling processes against the force of a first spring in the dome plane can be pushed back, the spring being weaker than the one coupled Coupling mouthpiece through its pressure medium separable force that can be produced, with at least one hook member, the transverse to the axial direction of the pipe part in a locking and a Release position is movably supported on the pipe part and with his Hook part protrudes radially outward beyond the coupling mouthpiece, with an interlocking profile arranged on the pipe part, which from the Locking position of the hook part of a coupled mating coupling is available to secure the coupling state, and with a cooperating with the hook member to control its movement Attack.

Such a line coupling is known from DE-OS 19 04 513. The housing is designed as a central buffer coupling head and the pipe part of the line coupling is relative to this in one  rear release and a front dome position movable. The The front end of the tube part forms with one surrounding its mouth Coupling sealing ring the coupling mouthpiece, in the coupling state are the coupling sealing rings of the pipe parts to be coupled axial bias against each other. Slightly to Coupling mouthpiece is set back against the pipe part Spring force axially slidably mounted on a ring part the support for the axial bracing of the coupling sealing rings in the Coupling state runs. On one of the parts ring part or pipe part is about an axis of rotation transverse to its axial direction a hook link is pivotally mounted, which with an attachment in a Groove of the other part - tubular part or ring part - engages and so by relative shifts between the two parts Experiences swivel movement. In the released state until without Pressurization of the pressurized clutch condition the hook link is pivoted in a radially outward direction Release position held. However, the coupled line coupling pressurized, this causes in the pipe parts acting fluid pressure between these a spreading force, which the mutually opposite tube parts against the Spring force slightly pushes back to the ring parts, however the coupling sealing rings are still in contact with pressure fluid remain. The relative displacement between the pipe part caused in this way and the ring part pivots the hook member radially out of the release position inward into a locked position, with its hook part a Interlocking profile on the pipe part of the respective mating coupling reaches behind and thus hooks the two pipe parts against each other, so that they can no longer separate from each other. The Coupling condition is thus retained mechanically hooked. Will the Pressure fluid pressure in the line coupling is reduced again, so return whose parts resiliently return to their starting positions. This well-known Cable coupling is afflicted with the shortcomings that the interlocking Depending on the application pressure, the pressure is temporarily depressurized State of the coupled line coupling the hooking itself, if only just temporarily, triggers. This represents one  Uncertainty factor and leads through frequent interlocking processes to unnecessary wear. In addition, for correct function the Springs or elasticities must be well coordinated. In addition, must the coupling sealing ring has a high axial elasticity, he must have its sealing function over a large, axial suspension area exercise safely.

DE-GM 18 71 648 is a different type of line coupling known, in which on the pipe parts near the coupling mouthpieces to these outwardly projecting outrigger beams are arranged, which are movable by means of a piston; the Piston is in the direction of engagement against spring force from the pressure in Pipe part actable. This arrangement is during Coupling processes very vulnerable and requires due to additional pistons considerable purchase costs; also leads here also a temporarily depressurized state of the Cable couplings to release the lock.

It is an object of the invention an automatic line coupling to design the type mentioned at the beginning with simple means such that it avoids the shortcomings of the known line couplings, in particular one of the state of action of the line coupling has independent locking of coupled pipe parts.

This object is achieved in that the at least one stop between the housing of the line coupling or counter-coupling and the hook member is arranged such that he depending on the relative movements of the Coupling mouthpiece engages relative to the housing and that To move the hook link from one to the other can This design makes the hook link dependent of the coupling condition, but not of the pressure medium of the pipe part actuated during the entire period in Coupling condition thus remains the hooking of coupled pipe parts received regardless of the pressure medium applied.  

Advantageous according to the further invention, further Training opportunities of such a line coupling are the Removable subclaims.

In the drawing are two embodiments for one after the Invention trained line coupling shown schematically and shows though

Fig. 1 as the first embodiment, a single line coupling in the release state,

Figure 2 shows the coupled condition of two such pipe couplings.,

Fig. 3 shows a modified embodiment of a line coupling and

Fig. 4 shows a further, modified embodiment in a purely schematic representation.

The same reference numbers in the drawings refer to the same or corresponding parts.

Referring to FIG. 1, the line coupling to a pipe part 1, whose front end forms a coupling mouth piece with a mouth, the surrounding coupling sealing ring 2. The pipe part 1 is axially displaceably mounted in a guide opening 3 of a housing part 4 ; the housing part 4 has an end face 5 which, in the coupling state, faces a corresponding end face of a counter-coupling at a maximum distance; the end face 5 is thus at least approximately in a dome plane. In the coupling-ready uncoupling state shown in FIG. 1, the front end of the tube part 1 with its coupling sealing ring 2 forming the coupling mouthpiece is at a distance V in front of the end face 5 and thus the coupling plane; the pipe part 1 is, however, against the force of a spring not shown -, the structure may extent that according to the already mentioned DE-GM 18 71 648 corresponding - in such a manner relative to the housing part 4 zurückverschieblich that the coupling sealing ring 2 reaches the coupling plane. The force of the spring mentioned can be less than the back pressure force exerted on the tubular part 1 by pressurizing the same.

On the tubular part 1 , a hook member 8 is articulated about an axis extending transversely to its axial direction 6 and shown as a bolt 7 . The hook member 8 extends to the front and, with its hook part 9, projects beyond the coupling sealing ring 2 . A weak spring 10 clamped between the tube part 1 and the hook member 8 loads the hook member 8 in the pivoting direction from the tube part 1 . On the back of the hook part 9 facing away from the tubular part 1 , two levers 11 and 12 are held offset at their mutually opposite ends; the mutually facing ends of the two levers 11 and 12 are guided together. At the mutual guide point 13 of the two levers 11 and 12 or near this guide point 13 a spring 14 engages which extends to the hook member 8 ; the spring 14 loads the guide point 13 in the spreading direction from the hook member 8 , such that the two levers 11 and 12 are roof-like, at an acute angle to the back surface of the hook member 8 and at an obtuse angle to each other. The spring 14 is stronger than the spring 10 . Opposite the hook member 8 , the tubular part 1 carries a radially projecting cam 15 , the back of which forms a hooking profile 16 for the hook part of a mating coupling. So that the automatic line coupling and its mating coupling can be configured in the same way, it is expedient if the hook member 8 and the cam 15 lie in a horizontal plane which contains the axial direction 6 , ie the axis of the pipe part 1 .

The guide opening 3 is designed to be widened in its end region adjacent to the end face 5 ; in this end region it has a wall 17 which is conical.

When the automatic line coupling is ready for coupling, as shown in FIG. 1, the mouth of the pipe part 1 with the coupling sealing ring 2 is at a distance V in front of the end face 5 . The hook member 8 is pivoted away from the tube part 1 under the force of the spring 10 , it forms an acute angle to the axial direction 6 thereof. The lever 11 adjacent to the bolt 7 runs close to the transition point 18 of the wall 17 to the end face 5 , the guide point 13 is located at a greater radial distance from the wall of the pipe part 1 than the transition point 18 .

In FIG. 2, the coupled state of the automatic line coupling is illustrated with a counter-coupling, the parts of the counter coupling are indicated by the same, however, supplemented by a primed reference numerals as those of the conduit coupling.

Approaches, starting from the state of Figure 1, for coupling a mating coupling with a housing part 4 ', so initially the pipe parts 1 and 1 ' with their coupling seals 2 and 2 'to mutual contact; the end faces 5 and 5 'are still at a distance of about 2V. As the coupling and counter-coupling approach further, this distance is reduced, the pipe parts 1 and 1 'being pushed back relative to the housing parts 4 and 4 ' against their spring load, not shown. The front ends of the hook parts 9 and 9 'arrive in the space enclosed by the wall 17 ' or 17 until the respective front lever 12 or 12 'runs against the transition point 18 ' or 18 and upon further approximation radially inwards, is pressed towards the pipe part 1 or 1 '; the spring 14 or 14 ', which is stronger than the spring 10 or 10 ', pivots the hook member 8 or 8 'in the direction of approach to the pipe part 1 or 1 ', finally the hook parts 9 or 9 ' engage the cams 15 'and 15 on their interlocking profile 16 ' and 16 respectively. The pivoting movement of the hook members 8 and 8 'stops when the couplings approach, until in the coupled state when the end faces 5 and 5 ' face each other with a maximum distance or even abut, the hook members 8 and 8 'a substantially to the axial direction 6 assume parallel position and completely engage the interlocking profiles 16 'and 16 ; the pipe parts 1 and 1 'are thus hooked together by means of the hook members 8 and 8 ' and the cams 15 , 15 'or their hooking profiles 16 , 16 '. The complete interlocking is achieved shortly before reaching the complete coupling state shown in Fig. 2, during the last approximation phase of the two housing parts 4 and 4 'are by further accretion of the lever 12 and 12 ' at the transition point 18 'and 18 respectively both levers 12 and 11 or 12 'and 11 ' against the force of the spring 14 or 14 'about their brackets on the hook member 8 or 8 ' rotated somewhat in the direction of this, the springs 14 and 14 'so keep in the coupled Condition the hook links 8 and 8 'under increased spring preload in their hooked positions.

For uncoupling, the two housing parts 4 and 4 'are separated from each other, resulting in the opposite processes to the above described, so that a description is unnecessary. It is essential that in this decoupling process the pipe parts 1 and 1 'move forward relative to the housing parts 4 and 4 ' and that the levers 11 and 12 or 11 'and 12 ' emerge from the spaces 17 'and 17 enclosed spaces , whereby the springs 10 and 10 ', the hook members 8 and 8 ' in the release position shown in FIG. 1 from the pipe parts 1 , 1 can pivot. The pipe parts 1 and 1 'are thus unhooked and free, they can separate from each other.

In a modification of the embodiment described above, the levers 11 and 12 can also be arranged such that when two housing parts 4 and 4 'approach each, the levers 11 and 11 ' at the transition point 18 and 18 'of their own housing part 4 and 4 ' start up and be pressed radially inwards by it. Furthermore, the coupling and uncoupling process corresponds to the above description. In a further change to both versions, it is possible to omit the other lever 11 or 12, which does not start at a transition point 18 , 18 '. On the other hand, however, it is also possible, in a further change, to arrange the levers 11 and 12 in such a way that, depending on the coupling circumstances, either at the transition point 18 'of the mating clutch, the transition point 18 of the own clutch or at both transition points 18 and 18 'Start.

In a further modification, it is possible not to form the wall 17 as a conical surface, but the guide opening 3 is essentially not expanded to show off to end face 5 and provided in the end face 5 of the adjacent area only two groove-like, open to the end face 5 and the guide opening 3 recesses , in which the hook member 8 or the cams 15 are able to enter when pushing back the tubular part 1 ; the bottom of this recess is wedge-shaped, corresponding to the wall 17 towards the rear of the tubular part 1 .

In a further modification, it is also possible to design the swivel control for the hook member 8 with the elimination of the levers 11 and 12 as well as the spring 14 : for example, similar to that already mentioned in the aforementioned DE-OS 19 04 513, a cantilever can be provided on the hook member 8 Extension are arranged, which engages in a guide groove on the housing part 4 such that when the pipe part 1 is pushed back into the housing part 4, the hook member 8 is rotated from its release position into its locked position.

Furthermore, it is also possible to equip the tubular part 1 with a plurality of hook members 8 distributed over its circumference and a corresponding number of cams 15 . In order to achieve similar designs of coupling and counter coupling, it is expedient to arrange the hook members 8 and cams 15 in mirror image to a vertical plane through the axis of the pipe part 1 .

In the exemplary embodiment according to FIG. 3, the hook member 8 articulated via the bolt 7 on the tubular part 1 has, at its end facing away from the hook part 9, a cam 19 which projects radially outward to the tubular part 1 and which surrounds the tubular part 1 at a radial distance Section 20 of the guide opening 3 is located, which is open to the end face 5 . The cam 19 ends at a short distance in front of the wall 21 of the section 20 . In the direction of the end face 5, just in front of the cam 19 , a cam 22 projects essentially radially inwards from the wall 21 , so the cam 19 engages behind the cam 22 . A compression spring 23, which is supported backwards against the housing part 4, loads the cam 19 in such a way that a torque pivoting to the locking position is exerted on the hook member 8 . The stop formed by the two cams 19 and 22 19, 22 passes in this embodiment, the line coupling during the forward movement of the coupling mouth piece representing coupling sealing ring 2 from the coupling plane into engagement and pivots the hook member 8 from its locking into the release position. This has the advantage that, should the coupled line couplings have stiff or immovable hook elements 8 in the locked position, as can occur, for example, due to icing, then the pipe parts 1 when the hook parts 8 are still hooked out of the housing parts 4 when the line couplings are uncoupled and detached are pulled out at the front until the cams 19 start on the respective cams 22 and the respective hook member 8 is thus moved positively and possibly with great force, namely the separating force of the couplings, into the release position, whereupon the pipe parts 1 of the two line couplings can be moved apart .

During coupling processes, reverse processes take place, when the pipe part 1 is pushed back from its front position into the coupling plane 1 , the stop 19 , 22 comes out of engagement and the compression spring 23 rotates the hook member 8 from its release position into its locked position, the coupled pipe parts two Cable couplings are thus hooked together.

In a modification of the exemplary embodiment shown in FIG. 3, of course, instead of the compression spring 23 , a different type of spring device, for example a tension spring clamped between the tubular part 1 and the shaft of the hook member 8 , can also be provided, which likewise loads the hook member 8 in the direction of the locking position Exerts torque.

In the exemplary embodiment according to FIG. 3, the hook member 8 carries on its shaft side facing away from the tubular part 1 a cam 24 facing the end face 5 with the cam 22 and which has an oblique run-up surface 25 on the housing part side; The end face 5 can have a corresponding bevel 26 in the region of the cam 22 . The run-up surface 25 and the bevel 26 cooperate in such a way that when the tube part is pushed back, these surfaces forming a stop 25 , 26 come to rest and pivot the hook member 8 in a positive manner in the direction of its locked position; in the area of the rear end position of the tubular part 1 , the cam 24 is located radially within the end face 27 of the cam 22 and is thus positively prevented from moving from its locked position. In this embodiment, the compression spring 23 or a corresponding, different type of spring can be omitted.

Furthermore, it is shown in Fig. 3 that the hook member 8 on the hook part 9 has a run-up slope 28 which, when two line couplings to be coupled come together, can run against the pipe part of a mating coupling or a part connected to this pipe part and, when the line couplings continue to approach, the hook part 8 pivots from its locking position to the release position. This function is advantageous if the pipe parts 1 are pushed back during a coupling process without the hook members 8 already being able to engage; the respective mating couplings then open the hook members 8 until they have approached so far that the hook members 8 are pivoted into the locking positions again in a force-locking or form-fitting manner by hooking the two pipe couplings.

In a modification of the exemplary embodiments described above, it is also possible to firmly connect the hook member with its end facing away from the hook part to the tubular part 1 and to form at least one shaft part of the hook member resiliently radially to the tubular part 1 , for example as a leaf spring. The movement control of the hook part 9 is carried out by one or more of the abovementioned stops against resilient tensioning of the shaft part, separate springs or resilient designs of stops can be omitted. In this embodiment, it can be particularly expedient to form the entire hook member from a leaf spring.

It is known that in Willison clutches, the coupling profile of which, as can be seen from FIG. 4, is characterized in supervision by a hook-like, rigid pulling claw 29 and a prismatic, rigid thrusting claw 30 which is laterally spaced apart, during the last coupling phase or In the first decoupling phase, the housing part 4 experiences a relative movement in the arrow direction 31 relative to the housing part (not shown) of a mating coupling, that is to say essentially transversely to the longitudinal direction of the coupling corresponding approximately to the axial direction 6 ; during this transverse displacement, the pawl 30 of one clutch engages with the pawl 29 of the other clutch. In such Willison couplings, it is also common, as can also be seen from FIG. 4, to arrange the pipe part 1 of the line coupling in a relatively wide line channel 32 of the housing part 4 with a large amount of lateral play such that it can be pivoted to a limited extent about a vertical axis set back to the dome plane that the above-mentioned transverse displacement of the housing parts is not compensated for by relative displacements, but by displacement-free, joint rotation of the pipe parts 1, which abut one another with their coupling sealing rings, of two Willison couplings. It is expedient to take advantage of this turning to actuate the hook member 8 ; 4 shows a suitable arrangement for this purpose . The hook member 8 , which is pivotable about the bolt 7 on the part of the pawl 30 on the tubular part 1, has an extension 33 to the rear, which ends with a stop part 34 which, in the uncoupled state of rest, is at a distance from the front thrust-claw-side boundary wall 35 is located. A spring 36 loads the hook member 8 in the direction of the locked position. The tube part 1 carries the cam 15 opposite the hook member 8 . From Fig. 4 it is understood that when the tube part 1 is deflected in the direction of the boundary wall 35 , as occurs during the first movement phase in a decoupling process, the stop part 34 comes to rest against the boundary wall 35 and then the hook member 8 rotates into its release position . Thus, the pipe part 1 is already unhooked from the corresponding pipe part of the mating coupling at the start of decoupling and the two pipe parts can separate.

In a modification of the exemplary embodiment described above, the hook member 8 can be held solely by the spring 36 in a recess of the tubular part 1 which is open on one side towards the spring 36 , with the bolt 7 not being shown, a stop being provided between the hook member and the recess , which prevents the hook link from being pulled out to the front. There is therefore no special fastening or storage for the hook member, which results in a particularly simple and inexpensive construction.

Of course it is possible with a cable coupling Training characteristics according to those described above Exemplary embodiments in any other way than described Wise to combine with each other, as long as these features do not exclude each other.

short version

The automatic line coupling for rail vehicles has a pipe part ( 1 ) projecting in front of a housing part ( 4 ) in the uncoupled state; when coupling, this pipe part ( 1 ) can be moved back against spring force. On the pipe part ( 1 ) a hook member ( 8 ) is articulated, which can be pivoted from a release position into a locking position or vice versa during coupling processes by running onto the housing part ( 4 ) or on the housing part ( 4 ') of the counter coupling, in which there is a hooking profile ( 16 ') of the tubular part ( 1 ') engages behind a mating coupling. The pipe parts ( 1 and 1 ') of two coupled couplings are mutually mechanically hooked.

The hooking of the pipe parts ( 1 and 1 ') is only dependent on the coupling condition, regardless of the pressure in the pipe parts. The hook member ( 8 ) only moves during coupling or uncoupling processes. This ensures secure hooking of the pipe parts ( 1 ) in the coupled state and low wear of the hook member ( 8 ) and the parts interacting with it.

Reference symbol list

1 , 1 'pipe part
2 , 2 ′ clutch sealing ring
3 guide opening
4 , 4 'housing part
5 , 5 'end face
6 axial direction
7 bolts
8 , 8 'hook link
9 hook part
10 , 10 'spring
11 levers
12 , 12 'lever
13 leadership
14 , 14 'spring
15 , 15 ′ cams
16 , 16 'interlocking profile
17 , 17 'wall
18 , 18 ′ transition point
19 cams
20 section
21 hike
22 cams
19 , 22 stop
23 compression spring
24 cams
25 ramp area
26 slant
25 , 26 stop
27 end face
28 contact surface
29 pull claw
30 kick claw
31 arrow direction
32 line channel
33 extension
34 stop part
35 boundary wall
36 spring

V distance

Claims (20)

1.Automatic line coupling for rail vehicles equipped with automatic couplings, with a tubular part ( 1 ) movable relative to a housing part ( 4 ), the front end of which forms a coupling mouthpiece (coupling sealing ring 2) for pressure-tight coupling with a corresponding tubular part ( 1 ') of a similarly designed mating coupling , the coupling mouthpiece protruding in front of a coupling plane in the uncoupled state and being able to be pushed back into the coupling plane against the force of a first spring during coupling processes, the spring being weaker than the separating force which can be produced on the coupled coupling mouthpiece by its pressure medium, with at least one hook member ( 8 ) , which is movable transversely to the axial direction ( 6 ) of the tube part ( 1 ) into a locking and a release position on the tube part ( 1 ) and with its hook part ( 9 ) projects beyond the coupling mouthpiece ( 2 ) radially outwards, with one on the tube part ( 1 ) arranged interlocking profile ( 16 ), which can be engaged by the hook part ( 9 ) in the locked position of a coupled counter-coupling to secure the coupling state, and with a stop cooperating with the hook member ( 8 ) for controlling its movement, characterized in that the at least one Stop (lever 11 , 12 and transition point 18 , 18 '; Stop part 34 and boundary wall 35 ) between the housing ( 4 , 4 ') of the line coupling or counter-coupling and the hook member ( 8 ) is arranged such that it is dependent on the relative movements of the coupling mouthpiece ( 2 ) relative to the housing ( 4 , 4 ') comes into engagement and the hook member ( 8 ) from which one is able to move into its other position. 2. Cable coupling according to claim 1, wherein the stop (lever 11 , 12 and transition point 18 , 18 ') in the coupling state can secure the hook member ( 8 , 8 ') in its locked position, characterized in that the stop (lever 11 , 12 and transition point 18 , 18 ') is disengaged when the coupling mouthpiece ( 2 ) protrudes in front of the coupling level and comes into engagement when it is pushed back into the coupling level, the hook part ( 8 ) being brought into engagement by the engaging stop (lever 11 , 12 and transition point 18 , 18 ') is moved from its release into the locked position. 3. Cable coupling according to claim 2, characterized in that the stop (lever 11 , 12 and transition point 18 , 18 ') has at least one to the axial direction ( 6 ) of the tubular part ( 1 ) inclined wedge surface (lever 11 , 12 ) through Wedge action moves the hook link ( 8 ) during the coupling process from the release to the locked position. 4. Cable coupling according to one or more of the preceding claims, characterized in that at least one surface (lever 11 , 12 ) of the stop (lever 11 , 12 and transition point 18 , 18 ') is arranged to be deflectable against the force of a second spring ( 14 ) ( Fig. 1, 2). 5. Cable coupling according to claims 3 and 4, characterized in that the hook member ( 8 ) facing away from the tube part carries two opposing, resiliently deflectable wedge surfaces (levers 11 , 12 ) for the stop (transition point 18 , 18 '). 6. Cable coupling according to claim 5, characterized in that the two wedge surfaces are formed by two levers ( 11 , 12 ) which are guided together at the facing ends and on the other hand are movably supported on the hook member ( 8 ), the second spring ( 14 ) extends essentially in the direction of movement of the hook member ( 8 ) and is clamped between the hook member ( 8 ) and approximately the mutual guide point ( 13 ) of the levers ( 11 , 12 ). 7. Cable coupling according to claim 6, characterized in that the housing ( 8 ) on a tubular part ( 1 ) encompassing an end portion through the tubular part ( 1 ) penetrated guide opening ( 3 ) with a conically widening end portion, the wall ( 17 ) at least forms a wedge surface. 8. Line coupling according to one or more of claims 4 to 7, characterized in that between the tubular part ( 1 ) and the hook member ( 8 ) a latter in the direction of movement to release position loading third spring ( 10 ) is clamped, the third spring ( 10 ) is weaker than the second spring ( 14 ). 9. Line coupling according to claim 1, wherein the stop ( 19 , 22 ) in the uncoupled state holds the hook member ( 8 ) in its release position, characterized in that the stop ( 19 , 22 ) when pressed into the coupling plane coupling mouthpiece ( 2 ) out of engagement and when it is pushed in front of the dome plane, the hook part ( 8 ) is moved by the engaging stop ( 19 , 22 ) from its blocking position into its release position ( FIG. 3). 10. Line coupling according to claim 9, characterized in that the stop ( 19 , 22 ) on the hook member ( 8 ) near the end of the hook part ( 9 ) facing away from the tubular part projecting cam ( 19 ) and with this can be brought into engagement on the housing ( 8) arranged and by a pipe part (1) at a distance encompassing portion of a guide opening (3) near the end face (5) of the housing (1) in the direction to the tubular part (1) projecting cam (22) (Fig. 3). 11. Cable coupling according to claim 9 or 10, characterized in that the hook member ( 8 ) is loaded in the direction of movement to the blocking position by a spring ( 23 ). 12. Line coupling according to claim 1, characterized by a Training according to the features of claim 2 in combination with the features of claim 9 and possibly one or more of the Claims 3 to 11 relating to these claims 2 or 9. 13. Cable coupling according to one or more of the preceding claims, characterized in that the hook member ( 8 ) together with its plane of movement and the interlocking profile ( 16 ) are in a horizontal plane through the axis (axis direction 6 ) of the tubular part ( 1 ). 14. Cable coupling according to claim 1 for a Willison coupling, wherein the pipe part ( 1 ) in a conduit ( 32 ) to which the shock claw ( 30 ) adjacent boundary wall ( 35 ) is held deflectable, characterized in that the hook member ( 8 ) is held on the boundary wall side on the tubular part ( 1 ) and has a stop part ( 34 ) which, when the tubular part is deflected, comes into contact with the boundary wall ( 35 ) and moves the hook member ( 8 ) from the blocking position into the release position. 15. Cable coupling according to claim 14, characterized in that the hook member ( 8 ) is loaded by a spring ( 36 ) towards the locking position. 16. Line coupling according to claim 15, characterized in that the hook member of the spring in a recess open on one side the pipe part is supported. 17. Cable coupling according to one or more of the preceding claims 1 to 15, characterized in that the hook member ( 8 ) about a transverse to the axial direction ( 6 ) of the tubular part ( 1 ) extending bolt ( 7 ) is pivotally connected to the tubular part ( 1 ). 18. Line coupling according to one or more of the above Claims 1 to 13, characterized in that the hook member on  its end facing away from the hook part is held firmly on the pipe part and between this bracket and the hook part at least one in Radial direction to the tube part has resiliently deformable section. 19. Line coupling according to claim 18, characterized in that the shaft of the hook member consists of a leaf spring. 20. Cable coupling according to one or more of the preceding claims 1 to 19, characterized in that the hook part-side end face of the hook member ( 8 ) is designed as a bevel ( 28 ) which, when starting on a pipe part ( 1 ') of a mating coupling or with this connected part ( 15 ') moves the hook member ( 8 ) in its released position.