DE2502204C2 - Electric clutch - Google Patents

Description

The invention relates to an electrical coupling consisting of two halves or halves that can be detached from one another Components, and particularly relates to an electrical coupling in which an unintentional Decoupling or loosening of the components should be prevented.

Various locking mechanisms have heretofore been used to prevent such couplings accidentally came off. These mechanisms are very useful in so far as the problem is concerned, minimize the possibility of accidental coupling. As far as they resist the uncoupling perform, this resistance has to be overcome by hand if a decoupling takes place on purpose target. In other words, a coupling with such a lock is relatively easy to couple, however relatively difficult to uncouple. Most couplings have locking or ratchet devices no provision is made for a pawl position that would be at any given torque value In addition, the latch action is usually initiated long before a complete locking takes place, which increases the likelihood that the coupling components themselves are only loosely coupled to one another; this condition is very undesirable in electrical

ίο clutches, because it entails wear and tear and premature mechanical failure when the coupling is used in environments prone to vibrations.

Other known couplings have used wedge elements. Here, however, becomes common when coupling, an increased effort is required. The wedge effect increases progressively the stronger the wedge element is wedged between two converging surfaces. Not only is there an increased exertion required when coupling, but also the uncoupling requires great effort as a result of the wedge-like interference fit. One known embodiment employs two interfitting coupling components having a plurality of recesses or holes that moves over a plurality of balls when the two components are coupled and it becomes more and more difficult to make the recesses to move away over the balls with the consequence that a lock is formed. Even Here, greater effort is required both during coupling and uncoupling than this would be desirable.

The object of the present invention is to provide an electrical coupling consisting of two detachable from one another To create parts or components that remain coupled until there is a real intention to uncouple them, in which, however, the possibility of unintentional uncoupling due to vibrations is excluded. It should also be avoided that the coupling is secured with a wire. In the past the coupling ring or the screw coupling member was often mechanically wired with holes that are located in the retaining flanges, or with holes in one of the components, and before a decoupling can take place, you had to loosen this wire again, which is a nuisance especially when the coupling is used in confined spaces. The object of the invention also includes that when Coupling and uncoupling only minimal forces should be exerted by hand. A certain torque

'"ment is required to couple any To effect clutch using a rotary motion, and so is some torque required to disengage such a coupling, assuming that the uncoupling process the reverse of the coupling process and it is not a so-called quick coupling. In the coupling according to the invention so neither during coupling nor during uncoupling by the Protection against unintentional disconnection, an increase in the torque to be applied take place. In doing so, however, the loosening should be countered with an appropriate level of resistance, permanently. The possibility of counteracting such coupling, for example as a result of vibration, remains latent exist until a decoupling is actually to take place, and only the unintentional decoupling is a Opposite counterforce, while the intended uncoupling should be possible without further ado.

A particular problem is that the coupling must not consist of parts that are mechanically are too weak. The coupling according to the invention can be applied to both so-called bayonet couplings as well as couplings with union nuts, whereby of course both embodiments are based on a screwing movement. In the case of a coupling with a union nut, the mechanical stress, however, lower.

The coupling according to the invention should be particularly suitable in the event that it is Plug contacts, i.e. with pin contact and socket contact, acts. In such cases there is a risk of that the mating is not completely complete and the pin contacts only partially in the Sock contacts have been introduced. Nevertheless, the coupling according to the invention should be prevented that even with only partially coupled contacts an unintentional loosening takes place. Instead of that with such an incompletely coupled coupling the risk of loosening is increased, is to be taken care of according to the invention that any vibrations that would normally occur Loosening the clutch lead, on the contrary, tends to bring about a complete clutch and then keep the clutch locked.

Finally, care should also be taken in the coupling according to the invention that the handling does not differ from the usual couplings, so there are no special ones either Precautionary measures required by the user or any learning process.

The features provided for solving this object according to the invention are set out in claim 1 summarized. This can be explained using an example.

The coupling may comprise a component having a sleeve threaded at one end. A coupling nut engages the threads on this sleeve of the first component. The end opposite the threaded section of the nut, that is to say the rear end, has a special design. An inwardly directed flange is provided, abutting the sliding and rotational movement outwardly projecting to a ⁴ S flange on the sleeve of the second component with the first component to be connected. The specially designed end section of the coupling nut leads to a plurality of recesses which are angularly spaced, each comprising a compartment that receives a wedge block. The interior of the coupling nut is tapered in such a way that there is an inclined cam surface on which the wedge block can be effective. A drive ring encloses the coupling nut with a radial flange which has shoe elements which extend into second compartments of the recesses in the coupling nut. A compression spring, preferably a resilient rubber cushion or possibly a helical spring, biases each wedge block in the direction of the complementary cam surface inside the coupling nut. Another spring force, preferably exerted by a helical spring, acts on the shoes to normally bias them in a direction of rotation away from the associated wedge block, which, however, is strongly pushed out of the distribution when the drive ring is rotated in the opposite direction, so as to deliberately disengage to effect the coupling components.

Embodiments of the subject matter of the invention are shown in the drawings and will be explained in detail below.

Fig. 1 is a partial longitudinal section through an electrical Coupling according to the invention when the parts or components are fully coupled.

FIG. 2 is a section along line 2-2 of FIG. 1.

F i g. 3 is a section along line 3-3 of FIG. 2.

F i g. Figure 4 is a section along line 4-4 of Figure 4. 2.

F i g. 5 is a section taken generally in the direction of line 5-5 of FIG. 1, this figure showing the coupling nut without the parts interacting with it represents.

F i g. δ is a section essentially along line 6-6 of FIG. 1 to show the drive ring without with interacting parts.

F i g. 7 shows in perspective one of the wedge blocks used here, in this embodiment one Helical spring is used as shown in FIG. 2 shown.

Figure 8 is an illustration of a modified wedge block with a resilient rubber button on the left End used is shown, and

FIG. 9 is a top plan view of the modified wedge block of FIG. 8th.

The electrical coupling is shown in FIG. 1 denoted by 10 as a whole. As usual, there is the electric Coupling of two halves or components 12 and 14, respectively. The component 12 on the left-hand side of FIG. 1 comprises a metal sleeve 16 with a fastening flange 18 which has holes 20 for fastening the Coupling or the coupling components 12 on another part. The sleeve 16 has an inner one Annular groove 22 for receiving a resilient O-ring 24. A rubber isolator 25 is located inside the sleeve 16 used, a rigid retaining washer 26 and a rubber lining 27. in which a number of socket contacts 28 are recorded and held, of which only one is shown here. The sleeve 16 has an inner shoulder 29 which extends into a circumferential groove of the rubber lining 27. For one The purpose yet to be explained is a longitudinal keyway 30 which extends from the right end of the sleeve 16 extends inward. In addition, it can be seen that external threads 32 over the entire end section, in which the keyway 30 extends are provided.

The coupling component 14 also comprises a rigid sleeve 34. It is provided with a rubber isolator 36 provided, a rigid plastic retaining plate 38 and a rubber liner 40, the forehead insulator being provided with a forward lip 44; Everyone these elements are retained in the sleeve 34. Enclose and position parts 36, 38 and 40 any desired number of pin contacts 46 corresponding to the number of socket contacts 28 in FIG Components 12. The sleeve 34 is provided with external threads 48 for attaching a protective sleeve or a sleeve portion of a cable clamp 52. A wedge 56 extends radially from the sleeve 34 and is Slidably received in the above-mentioned longitudinal wedge groove 30. The sleeve 34 is integrally formed with a outwardly facing flange 58 which when components 12 and 14 are fully mated abuts the right end of the sleeve 16; from the flange 58 extends rearwardly a cylindrical one

Surface section 60. At the rear end of the cylindrical surface section 60 is located an annular outer groove 62 into which a snap ring 64 is inserted, which has a function to be explained Fulfills.

A coupling nut 66 has internal threads 68 which engage the external threads 32 on the sleeve 16. From the right end of the coupling nut 66 is offset inward an inwardly facing flange 70 adapted to be slidable on the outwardly facing flange 58 to lie so as to move the sleeve 34 to the left in FIG. 1 to pull when the coupling nut 66 is helical is moved forward to the left.

The inward displacement of the flange 70 from the right end allows a gap to be gained, which is divided into a plurality of circumferentially spaced recesses 72, between which projections or block sections 74 remain which extend into the immediate vicinity of the cylindrical surface 60 which was mentioned above. In fact, this cylindrical surface forms the inner wall of each Recess 72. Each recess 72 can be described as consisting of three compartments 76, 78 and 80 consists. A radially directed shoulder 82 forms the end wall of compartment 76. The middle compartment 78 has an inwardly sloping cam surface 84. The remaining compartment 80 points a shoulder 86 at the end facing away from the middle section 78. For one to be explained Another shoulder 88 is provided in the interior of the coupling nut 66 for this purpose. It matters that each recess 72 has a larger division 76, a middle division 78 with the cam surface 84 and an additional compartment 80. The shoulders 82 and 86 are actually the walls of the Block Sections 74. If the word "department" was used here, one could in the same way Designate this cavity with a chamber or groove which is open to the right end of the coupling nut 66, as shown in FIG. 5 can be found.

A drive ring 90 plays an important role. The drive ring 90 loosely encloses the coupling nut 66 and like this can be composed of parts. First, the drive ring 90 has a cylindrical or Cup shape that allows the ring to be pushed loosely over the coupling nut 66. Of the The inner edge or the lip is, as indicated at 92, crimped to prevent the ring 90 from becoming after rerhts (according to FIG. 1) can move away. One any number of flutes or ribs 94 can be provided around the periphery of the drive ring to be able to twist it more easily. As perhaps best the representations according to FIG. 3 and 4 can be removed, but also in FIG. 6, an inwardly folded radial flange% can be provided which can be placed against the right end of the coupling nut 66, as shown in FIG. 1 can be found. The beaded Lip 92 prevents drive ring 90 from moving to the right and flange 96 prevents the drive ring 90 moves to the left. More importantly, the flange 96 is in the Angularly spaced shoes 98 wears, which are movable together with the drive ring 90 when this twisted in any direction.

The ends 100 of the shoes 98 rest on the above-mentioned inner shoulders 86 of the coupling nut 66. Accordingly, when the drive ring 90 is rotated clockwise, the ends 100 of the various shoes 98 abut the shoulders 86 so that the coupling nut 66 is forcibly rotated clockwise, and such rotation of the coupling nut 66 leads to its axial forward movement due to the internal threads 66, which are in engagement with the external threads 32. The shoes 98 are provided with cuts, as shown in FIGS. In this way there is a shoulder

ίο 102 for a purpose to be explained. This results in a reduced radial thickness 104 in the greater part of each shoe 98, and this reduced section in its radial dimension terminates in a pointed end 106 . The convergence of this section will be explained later.

First, however, reference should be made to a helical spring 108 which is inserted between the inner shoulder 88 of the coupling nut 66 and the shoulder 102 of the associated shoe in question. The various coil springs 108 resiliently bias the shoes 98 in a clockwise direction, as in FIG. 2 recognizable. However, this bias by the various coil springs 108 can easily be overcome if the drive ring 90 is rotated counterclockwise.

While the various shoes 98 are within the compartments 80, the larger compartments 76 contain a plurality of wedge blocks or claws S10, one wedge block in each compartment 76. One embodiment of a wedge block 110 is shown in FIG. After mentioning the tapered cam surface 84 on the inside of the coupling nut 66, it should be noted here that a complementary bevel or tapering to form a cam surface 112 is provided after the end of each wedge block 110 . The end of the wedge block 110 which faces the relevant shoe 98 has an incision 114 . Accordingly, the pointed end 106 of the shoe 98 can extend into the recess 114 when the shoes 98 the

-to move or push away different wedge blocks 110 when turning the drive ring 90 counterclockwise.

A bore 116 extends inwardly from the other end 115 of each wedge block 110 and contains a coil spring 118 , the protruding end of which rests against the shoulder 82 on the inside of the coupling nut 66. The various coil springs 118 tension the associated wedge blocks 110 in a clockwise direction as shown in FIG. 2 forward and bring

hence the tendency for the cam surface 112 on each wedge block 110 to abut the complementary, contoured cam surface 4 provided in the interior of the coupling nut 66. The shoes 98 can very easily overcome this biasing action of the individual coil springs 118 to move the wedge blocks 110 counterclockwise and thereby move the cam surface 112 away from the cam surface 84 of the clutch nut 66. Thus, the wedge blocks 110 different for clutches 10 size can be used, that for different diameter of the nut 66, the portion between the ends 114,115 is curved or outwardly concave, as indicated by reference numeral 120, formed in this way results in rounded portions 122, J24, and these rounded portions are the only ones seated on or in contact with surface 60.
The use of springs 118 and in particular

making the bores 116 is relatively expensive. Therefore, one can reduce the manufacturing cost by using modified wedge blocks 110a, one of which is shown in FIG. 8 and 9 is shown. Instead of Coil spring 118, a resilient rubber pad 118a is used, with the end of the block 110a slightly is excluded at 116a (see Figure 9) to accommodate this resilient element. Also the rubber pillow 118a is compressible to enable loosening, as is the case for coil spring 118 ίο applies.

The annular groove 62 around the sleeve 34 of the components 14 has already been mentioned. The job of this groove 62 is to accommodate the snap ring 64, which extends radially so far outward that the flange 96 of the Drive ring 90 can rest against it when the drive ring is rotated counterclockwise.

The mode of operation of the clutch 10 should become clear from the preceding description be. However, when reading the following summary one should remember the object of the invention which is to prevent the loosening of the components 12 and 14 when the clutch is under operating conditions is used wherever significant vibration loads must be expected.

It is now assumed that component 14 is to be coupled to component 12. In this Momentarily the coupling 66 is completely detached from the sleeve 16 of the components 12. To the To engage contacts 46, the operator merely guides the wedge 56 into alignment with keyway 30 and moves component 14 forward, after which one begins to drive ring 90 to rotate clockwise, the indicated directions of rotation always with reference to F i g. 2 should be understood.

By turning the drive ring 90 clockwise, the various shoes 98 move, which are integrally connected to the drive ring 90, common in a clockwise direction, with the ends 100 of the shoes rest against the shoulders 86 of the coupling nut 66. This results in a metallic one Contact between the drive ring 90 and the clutch nut 66, with the shoes 98 as Intermediate links in the transmission of the rotational movement of the drive ring 90 to the coupling nut 66 to serve. With the internal threads 68 of the coupling nut 66 engaged with the external threads 32 of the sleeve 16 of the component 12, the coupling nut 66 becomes the axial direction along the sleeve 16 of the component 12 is moved, the wedge 56 simply being displaced along the Kei'nui 30 of the sleeve 16.

During this rotation, the wedge blocks 110 move circumferentially around the Cylindrical surface 60 of the sleeve 34 of the component 14. It can be seen from FIG. 2 that the coupling nut 66 in Is rotated clockwise and this causes the various shoulders 82 to also rotate clockwise turn. As far as the projecting ends of the coil springs 118 on the shoulders 82 of Clutch nut 66, a small amount of force is transmitted to the various wedge blocks 110 in order to to move these together with the coupling nut 66 when it rotates, of course, moves also the sch; äge cam surface 84 on clutch nut 66 is continuously clockwise and has always the same distance from the shoulders 82; the inclined cam surface 84 therefore hinders never the movement of the various wedge blocks 110 under these conditions.

Continued clockwise rotation of the drive ring 90 will result in the coupling nut 66 moves axially relative to component 12. During this forward movement of the coupling nut 66 as a result of Inwardly facing flange 70 lies in a helical configuration of threads 68 and 32 of the coupling nut 66 rotatably and slidably on the outwardly directed flange 58 of the sleeve 34 of the Component 14. In this way, the front of the flange 70 acts on the rear of the Flange 58 with the result that the sleeve 34 progressively telescopically into the sleeve 16 is drawn into it. When full coupling is achieved, the flange 58 of the sleeve 34 is on the right End of the sleeve 16, and this condition is shown in FIG. 1 shown. The coupling nut 66 cannot now be moved further forward.

If the coupling is installed in operating conditions where there is significant vibration is expected, one can expect that the coupling nut 66 will tend to move counterclockwise to vibrate. If this is not braked or prevented, continued vibration could cause the clutch nut 66 to retract axially and ultimately the Completely detach component 14 from component 12.

However, this cannot occur with the subject matter of the invention, since as soon as there is any tendency to vibrate would cause counterclockwise rotation, the cam surface 84 on the inside of the Coupling nut 66 would simply act on the cam surface 112 on the wedge block 110, namely this applies to all three wedge blocks 110. If so occurs, the sections 122 and 124 of the various wedge blocks 110 are inwardly against the Cylinder surface 60 pressed. The greater the vibration, the tighter the wedging. There is no torque or torque on the drive ring 90 transfer. In other words, since the clutch 10 remains unmonitored and only simply performs its clutch function, one can under these conditions simply cannot tolerate the loosening of components 12 and 14.

However, the situation is quite different if there is an intentional uncoupling of the component 14 from the Component 12 should be done. In this case, the drive ring 90 is rotated counterclockwise, this direction being related to the representation according to FIG. 2 refers. If there have been vibrations should shift so that the wedge blocks 110 have been pressed against the cylinder surface 60 a rotation of the drive ring 90 directly the various shoes 98 in a counterclockwise direction, the pointed ends 106 engaging the recessed ends 114 of the wedge blocks 110, the Coil springs 118 develop sufficient compressive force for this to occur. Continued rotation in the Counterclockwise then releases the various wedge blocks 110. The shoes 98 accordingly push the Blocks 110 counterclockwise, with the coil springs 118 together with these wedge blocks 110 develop a certain counterforce to allow this loosening to occur. Even if there is no cam action has taken place that resulted in wedging between surfaces 84 and 112 becomes a Rotation of the drive ring 90 counterclockwise

ne cause the shoes 98 the wedge blocks 110 in the Push counterclockwise with the result that the coil springs 118 associated with the blocks are to be compressed so far that the ends 115 of the wedge blocks 112 to the shoulders 82 of the Coupling nut 66 come to rest. Then there is a positive force transmission in one Direction to disengage components 12 and 14 as the wedge blocks 110 apply the torques is transmitted to clutch nut 66 via shoes 98 and wedge blocks 110 under these circumstances. Such a process simply results in the coupling nut 66 being unscrewed, the threads 68 move helically relative to the threads 32. During this uncoupling, the presses inwardly folded flange 96 on the drive ring 90 against the radially protruding portions of the Snap rings 64. As a result, a compressive force is exerted on the snap ring 64 which acts on the rigid sleeve 34 is transmitted and this forces it to be moved to the right (according to FIG. 1), the wedge 56 also moved to the right in the keyway 30 in the longitudinal direction. A sufficient number of revolutions loosens the coupling nut 66 completely from the sleeve 16 when the contacts 46, 28 are completely disengage.

While it is not intended that only a partial coupling of the components 12, 14 take place, it can this can occur if the operator is careless. From Fig. 1 you can see that the base con- ^ o bars 46 accommodate a substantial length of pin contacts 28 when components 12 and 14 are fully coupled together. However, if only a partial coupling of the components takes place, each pin contact 28 sits with, for example, only its tip in the associated circular contact 46. When it comes to low electrical currents, this is not a serious night:! If one of the The possibility that the likelihood is greater that the clutch 10 will disengage again if Vibrations occur. However, the same wedging occurs as when the clutch 10 is fully engaged because of any tendency for the coupling nut 66 to close in a counterclockwise direction rotate, then, when there is no drive by the drive ring 90, the cam surfaces 84 to rest against the Brings cam surfaces 112 on the wedge blocks 110. That is why they need to be completely nested of components 12 and 14 not to be reached in order for the lock to take effect. While uncoupling is prevented under these operating conditions, the clutch can, however Trends towards tighter coupling follow, which is very beneficial. In other words, can never be unintentional uncoupling can occur, but unintentional coupling that is in the direction of a the fully retracted position of the components progresses, but not in the other direction.

It has been mentioned that the shoes 98 abut the blocks 110 in a counterclockwise direction and that the coil springs 118 apply pressure to allow the blocks to move. When using the modified blocks 110a according to FIG. 8 and 9 has that Rubber cushions have the same effect.

For this purpose 3 sheets of drawings

Claims (12)

Patent claims: 1. Electrical coupling, consisting of a first and a second component, the longitudinal a longitudinal axis can be brought into a plug connection, with a screw coupling member for coupling and uncoupling the components and having a drive member that is about the axis relative to the Screw coupling member is rotatable and a stop member movable with the drive member, has for pressing against the screw coupling member for its distortion in a first Direction of rotation for coupling when the drive member is rotated in this first direction of rotation, characterized by wedge members (110, UOaJL which are slidable in an arcuate shape Distance around the axis relative to both the screw coupling member and the drive member , the screw coupling member having elements (82) for sliding the wedge members in their arcuate path in the first direction of rotation when the screw coupling member is rotated in this direction by the drive member, while the wedge members screw back the screw coupling member in the opposite second direction of rotation and thus the decoupling of the component provide resistance, the stop member (98) on the drive member, however, makes the wedge members ineffective when the Drive member in the second, the first direction of rotation opposite direction. 2. Electrical coupling according to claim 1, characterized in that the wedge members (110, HOaJ a cam block (112) having a tapered cam surface on that of the stop member (98) nearer end, and that the screw coupling element (66) to the wedge member cam surfaces having complementary cam surfaces (84). 3. Coupling according to claim 2, characterized by elastic elements (118, 118aJ for the Biasing the wedge members towards the cam surface. 4. Electrical coupling according to claim 3, characterized in that the stop member (98) is designed as a ⁴ S shoe element in one piece with the drive member (9) for acting on the wedge members to push them in the direction away from the cam surface when the Drive link in the reverse direction. 5 <> 5. Electrical coupling according to claim 4, characterized by spring elements (108) for the preloading of the shoe elements in a direction away from the associated wedge members. 6. Electrical coupling according to claim 1, characterized in that the first and second components in the coupled state have sections abutting one another in the longitudinal direction, that the screw coupling member enclosing a portion of the first component & ° end portion and a second, a portion of the second component enclosing Has end portion, wherein the first-mentioned end of the screw coupling member and the first component have interlocking threads, while ^b5 the other end portion of the coupling member with the portion of the second component that is enclosed by it, have interlocking flanges, so that the rotation of the screw coupling member in said The first direction causes a displacement of the same along the first component, with the result that the interlocking flanges cause the first-mentioned sections to abut when the components are fully coupled to the wedge member he have a sloping cam surface, that the other end portion of the screw coupling member is recessed to form a first arcuate chamber for receiving the wedge member, while a second arcuate chamber of smaller diameter and an intermediate chamber between the first and the second chamber are provided that the intermediate chamber is a inclined cam surface of the wedge element has complementary inclined surface that the drive member encloses the screw coupling member and protrudes with a portion in the second arcuate chamber, that a first elastic element biases the wedge member relative to the screw coupling member in the first direction of rotation such that normally the inclined cam surface of the same against the Complementary inclined surface of the intermediate chamber is pressed to counteract the rotation of the screw coupling member in the opposite direction, wihre.id second elastic biasing members the drive member relative to the Pre-tension the screw coupling member in the first direction of rotation, so that the portion of the drive member projecting into the second arcuate chamber has a circumferential extension such that it strikes the nearest end of the wedge member to move the wedge member in the opposite direction of rotation in order to cancel the action of the first tendons and to move the inclined cam surface of the wedge member away from the complementary inclined surface of the intermediate chamber. so as to enable the component to be released. 7. Electrical coupling according to claim 1, characterized in that the screw coupling member a coupling nut comprises in screw engagement with the first component and with an inwardly directed flange that the second component has an outward flange in front of the inwardly directed flange and a cylindrical surface extending rearward from the outward flange to behind the inward directed flange of the screw coupling member extends that the forward side of the inward-facing flange rests against the rear of the outward-facing flange, when the clutch nut is rotated in a first direction to effect the clutch Components that the nut has an inwardly facing surface which is radially spaced enclosing the cylindrical surface and a first portion with a first radius and a second portion of smaller radius that the wedge members have a sloping Having cam portion between the first and second surface portions and a wedge block between the first surface portion and the cylindrical surface with a sloping one Cam surface is provided at the end of the same close to the cam portion that the nut turns radially extending shoulder at the end of the first Has the surface portion facing away from the cam portion that elastic tendons are supported on the shoulder and on the opposite end of the wedge block to support them normally to be preloaded in the first direction of rotation so that there is an inclined cam surface abuts the cam portion that the drive member comprises a drive ring which the Coupling nut encloses and the stop member of the drive member is in the room between the inwardly facing surface of the nut and the cylindrical surface of the second Component extends such that one end abuts one end of the wedge block, around the wedge block be able to move in a direction opposite to the first direction of rotation, so as to Effect of the elastic biasing elements overcome when the drive ring in the opposite Direction of rotation is rotated. 8. Electrical coupling according to claim 7, characterized in that the nut has a second radiai has directed shoulder, and that additional elastic biasing elements on the second shoulder and are supported on the stop member, the latter normally in the first direction of rotation bias away from the wedge block. 9. Electrical coupling according to claim 8, characterized in that the nut has a third radial directed shoulder at the end of the second surface portion facing away from the cam portion has and that the stop member comes to rest on the third shoulder when the Drive ring is rotated in the first direction of rotation. 10. Electrical coupling according to claim 9, characterized in that the second shoulder is arranged between the cam portion and the third shoulder and a smaller radial extent as the third shoulder. 11. Electrical coupling according to claims, characterized characterized in that the first elastic biasing element is formed by a rubber pad is. 12. Electrical coupling according to claim 11, characterized in that the second is elastic Biasing element is formed by a helical spring.