WO2008145463A1 - Torque transmission device with a switch-over latching ball - Google Patents

Abstract

The invention relates to a device for transmitting a torque to a screwing tool element (1) in the form of a socket for wrenches, a ratchet extension or the like, with a polygonal output stub (5) for inserting into a matching polygonal opening (2) of the screwing tool element (1), with a latching ball (6) which lies in a ball-receiving cavity (7) of a polygonal surface (8) of the polygonal output stub (5) and is intended for entering a latching cutout (4) of a polygonal surface (3) of the polygonal opening (2), with a transmission element which is arranged in an axial cavity (9) and acts with a first section (12) on the latching ball (6) and the second section (10, 21') of which is displaced in the axial direction of the axial cavity (9) by a switch-over switch (13, 22) when switching over from a release position into a locking position in such a manner that the screw tool element (1) can be pulled off from the polygonal output stub (5) in the release position and is held on the polygonal output stub (5) in the locking position. In order to develop the screwing tool simply in terms of production and advantageously in terms of use, it is proposed that the transmission element has an elastic element (11) which is arranged between the first section (12) and the second section (10, 21') of the transmission element and is compressed during the switching over from the release position into the locking position.

Description

 Torque transmission device with switchable detent ball

The invention relates to a device for transmitting a torque to a screwing tool in the form of a socket wrench, a ratchet extension or the like, with a drive polygon for insertion into a form-fitting polygonal opening of the Schraubwerkzeugelementes, with a in a Kugelaufnahmehöhlung a polygonal surface of the output Mehrkantes einliegen detent ball for entry into a locking recess a polygonal surface of the polygonal opening, with a arranged in a Axialhöh- ment transmission member which engages with a first portion of the detent ball and the second portion is displaced by a switch when switching from a release position to a locking position in the axial direction of the Axialhöhlung such that the Schraubwerkzeugelement in the release position from the drive polygon deductible and is tied in the locking position to the output polygon.

A device of this type is previously known from DE 202 09 159 Ul. It has an output polygon, which is the end section of an output shaft, with which a rotational movement can be applied to a socket or ratchet extension. The output shaft has at its other end a polygonal receptacle into which a drive polygon of another device, such as a ratchet head of a ratchet can be used. The generally designated as Schraubwerkzeugelement sockets or ratchet extensions have a standardized polygonal opening into which the standard polygonal section of the device can be inserted. Usually, the output polygon has a square plan. In one of the polygonal surfaces of the output Mehrkantes is a ball receiving cavity, in which a detent ball rests. The edge of the ball receiving cavity is caulked so that the ball can not fall out. The ball can, however, with a portion of its spherical surface from the Kugelaufnahmehöh- stand out. In its maximum forward position, the edge retention of the ball receiving cavity is present. The can be brought into a complete immersion position, so that the output polygon can be inserted into the corresponding polygonal opening of the socket wrench. The polygonal surface of the polygonal opening corresponding to the polygonal surface of the output polygon has a latching recess, into which a section of the latching ball protruding from the ball receiving cavity can enter. In order to move the detent ball from the full immersion position in the maximum position, a control pin is provided in the known device, which forms a transmission element in a Axialhöhlung with which a locking movement or release movement of a switch can be transmitted to the detent ball. The switch is arranged in a transverse bore of the Axialhöhlung pin with a control edge on which abuts one end of the transmission member. The other end of the transmission element is in touching contact with the detent ball. If the transfer member controlled by the switch in the Axialhöhlung longitudinally displaced, the detent ball can be moved from its full immersion position in the maximum forward position. In this position, the socket wrench is tied to the output polygon.

A similar device is shown in EP 0 747 174 A1. Again, in an axial cavity, an axially displaceable pin is formed, which forms two different high levels, on which rests the detent ball in the release position or in the locked position. Again, a switch in a transverse bore radially displaceable switch is provided. The pin lying in the Axialhöhlung is acted upon by a compression spring in the locking position.

From US 3,467,231 a drive polygon is known in the polygonal surface a blind hole is introduced. The arranged in the blind hole Detent ball is supported on a compression spring, which is supported with its other end against the ground.

From US 4,218,940 a screwing tool with a drive polygon is known in which the lying in a ball receiving cavity locking ball is also displaced by a control pin. The control pin is supported by a compression spring against a bottom of a Axialhöhlung. A similar solution is shown in US 4,614,457 and US 4,367,663.

Based on the above-mentioned prior art, the invention has for its object to make the generic device, so a screw manufacturing technology simple and nutzsvorteilhaft on.

The object is achieved by the invention specified in the claims, each claim represents an independent solution to the problem and can be combined with any other claim.

First and foremost, it is provided that the transmission element has an elastic element arranged between its first section and its second section, in particular in the form of a compression spring, which is compressed upon switching from the release position into the locking position. The compression spring is now between detent ball and switch. While in the prior art, a rigid transmission member is provided, the invention preferably an elastic transmission member. The distance between the two sections of the transmission member thus decreases when switching from the release position to the locking position. According to this embodiment, it is not only possible to hold the detent ball in the locked position spring force. It is also possible to hold the detent ball in the release position spring force. The pressure spring counteracts here in the release position with a lower spring force the detent ball as in the locked position. This makes it possible that the Schraubwerkzeugelement, which may be a socket insert or a ratchet extension or the like, by hand from the output polygon is deductible. This is done without the help of an additional tool. In the locking position, the detent ball is acted upon by such a large spring force that the Schraubwerkzeugelement can not or can not be deducted without the aid of a tool from the output polygon. The transmission member also has a simple structure, if it consists only of balls and springs. According to a first variant, the transmission member consists only of two balls and a pressure spring arranged between the two balls. A pressure ball is acted upon directly by the switch. A blocking ball lies in surface contact with the spherical surface of the detent ball. In another variant of the invention more than two balls are arranged in the Axialhöhlung. These additional balls are used to transmit motion. Instead of the motion transmission balls, motion transmission pins can also be arranged in the axial cavity. As is generally known in the prior art, the changeover switch can be arranged to be radially displaceable in a transverse bore to the axial cavity. It can have a control flank which displaces the pressure ball during the radial displacement of the changeover switch in the axial cavity. Along with the displacement of the switch from the release position to the locking position, the compression spring is tensioned, so that the force acting on the detent ball force is increased. The switch can also be arranged rotatably in a transverse cavity to Axialhöhlung. It can have a radial recess in which the pressure ball rests in the release position. If the switch is rotated, the pressure ball exits under an axial displacement of the radial recess and biases the compression spring. This radial recess of large radial depth can be opposite to a radial recess of low radial depth. This radial recess low radial depth can serve as a latching recess when in the locked position the Pressure ball engages there. As a result, the switch is held in its rotational position. In an analogous manner, a longitudinally displaceable changeover switch can also have such depressions arranged one behind the other in its axial direction, into which the pressure ball can enter in its two operating positions, so that the longitudinal displacement position of the changeover switch is thereby fixed. In addition, it is possible to arrange the switch axially displaceable in an extension of the Axialhöhlung. The switch acts in this variant together with a pressure pin. The pressure pin is located in the Axialhöhlung and is displaced axially when adjusting the switch. One end of the pressure pin then acts instead of the above-mentioned pressure ball with the compression spring, which acts with its other end against the locking ball acting on the locking ball. The pressure pin may have radially projecting control cam, which cooperate with a housing-fixed control edge. The latter can be formed by an insert. A quarter turn of the pressure pin thus leads to a shift from a release position to a locking position or vice versa. The rotation of the pressure pin is done with the switch. This can be firmly connected to the pressure pin. The changeover switch can in this case be a turntable which rests in a front recess of a ratchet head. The switch can also be in a threaded hole, which is substantially flush with the Axialhöhlung. By turning this switch, its end face, against which the pressure ball bears, displaces in the axial direction to the axial cavity and thereby influences the tension of the compression spring acting on the blocking ball. In a particularly preferred variant of the invention, the individual Wendelgänge the compression spring in the locking position are so small spaced from each other that the detent ball can not be pushed back by applying a large radial force in its full entry position into the ball receiving cavity. Before the detent ball reaches its immersed position, the individual helical turns of the compression spring come into contact with each other, so that blocks further compression of the compression spring is. If the changeover switch is moved starting from a locking position into a release position, the pressure spring is released as a result of the associated axial displacement of the compression spring. It only loads the locking ball with a smaller spring force. As a result, a small radial force on the detent ball is sufficient to displace the detent ball in the direction of the pressure ball against the restoring force of the compression spring. This force can be applied by hand, so that the Schraubwerkzeugelement, so the socket wrench with little effort on the output polygon can be postponed, the detent ball initially from the edge of the polygonal opening against the restoring force of the largely relaxed

Compression spring is urged into the ball receiving cavity. When fully inserted socket insert the detent ball then enters a relaxation of the compression spring and an axial displacement of the locking ball in the locking recess. The screwing tool element is thereby temporarily fixed. If the changeover switch is then moved out of the release position into the locking position, the screwdriving tool element can no longer be pulled off the output polygon by hand. The device may be a torque wrench. The device can also be a ratchet with reversible ratchet or freewheel gear. In this variant, the changeover switch is preferably the abovementioned pressure pin or the threaded pin which rests in a bore aligned with the axial cavity and which can be actuated by the end face of a gear head of the ratchet opposite the output polygon. There, the direction of rotation switching member for the cogged transmission can be arranged. The device may also be a ratchet extension or a cross wrench. The switch can then be arranged in an output shaft of cylindrical shape. In a further variant of the invention, the changeover switch is likewise designed as a circular-cylindrical pin which is inserted in a bore of the output shaft. The switch has two at an angle of 90 ° to each other standing stages which have a different distance to the center of rotation of the switch. These stages are scanned by an end portion of a pressure pin, which points with its other end to the compression spring and acts on the compression spring. By turning the switch only by 90 ° can be switched between locking position and release position, the end of the pressure pin is in the locking position on a flat level and in the release position at a low level.

Embodiments of the invention are explained below with reference to accompanying drawings. Show it:

1 is a perspective view of a first embodiment of the invention in the form of a ratchet extension,

2 a socket,

3 shows a section along the line III-III in Figure 1 in a release position,

4 shows a representation according to FIG. 3 in a locking position, FIG.

5 is an enlarged view of Figure 4,

6 shows a second embodiment of the invention in a perspective view,

7 is a section along the line VII-VII in a release position,

8 shows a representation according to FIG. 7 in a locking position, FIG. 9 shows a third embodiment of the invention in the form of a ratchet head in the release position,

10 shows the embodiment according to FIG. 9 in the locked position, FIG.

11 is a section along line XI-XI in Figure 9,

Fig. 12 is a view according to Figure 11 in the locked position and

13 shows a fourth embodiment of the invention, in which the switching rotational angle is only 90 °,

14 is an enlarged view of the pressure pin of the fourth embodiment,

15 is a section along the line XV-XV in Figure 13 in the release position,

Fig. 16 is a view according to Figure 15 in the locked position and

17 is a section along the line XII-XII in Figure 16.

The reference numeral 1 denotes a socket wrench. This has a suitable for placement on a screw head hexagonal opening and one of these opposite polygonal opening 2, which is a square opening in the embodiment. This has four polygonal surfaces 3, each forming a latching recess 4. The device according to the invention is in the first two embodiments, a ratchet extension with an output shaft 18, which has a circular cross-section. The one end of the output shaft 18 has an insertion opening for a drive polygon. The other end of the output shaft 8 is designed as a drive polygon 5. The output polygon 5 has a square outline and can be inserted into the polygonal opening 2.

A polygonal surface 8 of the output Mehrkantes 5 has a radial opening which forms a ball receiving opening 7. The ball receiving opening 7 opens into an axial cavity 9, of a bore with a circular

Cross section can be formed, which runs in the central axis of the output Mehrkantes 5. In the ball receiving cavity 7 is a detent ball 6, which can be displaced in the radial direction to the axis of the output Mehrkantes 5, but is prevented by a caulking of the edge of the Kugelaufnahmehöh- 7 from falling out.

In the Axialhöhlung 9 is initially a blocking ball 12 whose diameter corresponds to the diameter of the Axialhöhlung 9 and is smaller than the diameter of the detent ball 6. This locking ball 12 is in surface contact with the detent ball 6 and is acted upon by a rear compression spring 11. The

Compression spring 11 is located between the locking ball 12 and the same diameter as the locking ball 12 having transmission ball 10 '. The transmission ball 10 'is in contact with a pressure ball 10th

In the same way, it is also possible to provide a plurality of motion transmission balls 10 'or instead of a motion transmission ball a movement transmission pin.

The pressure ball 10 is supported on a changeover switch 13. In the first exemplary embodiment, the changeover switch 13 is inserted in a transverse bore 14 to the axial height. 9 and has a substantially circular cylindrical shaft which forms two opposite radial recesses 15, 16, wherein the radial recess 15 has a greater radial depth than the radial recess 16. The radial recesses 15, 16 are arranged so that they depend form the bottom of Axialhöhlung 9 from the rotational position of the switch 13, where the pressure ball 10 is supported.

With a switching arm 17, the changeover switch 13 can be brought from a release position, in which the pressure ball 10 rests in the lower radial recess 15 in a locking position in which the pressure ball 10 rests in the less deep radial recess 16. In both positions, the pressure ball 10 is spring-loaded by the compression spring 11 in the respective radial recess 15, 16 a. Depending on this, the blocking ball 12 is subjected to a large or a lower spring force. As a result, in the release position, the detent ball 6 can be pressed with a lower radial force in the receiving cavity 7, wherein thereby the locking ball 12 axially displaced against the restoring force of the compression spring 11 in the axial cavity 9.

In the locking position, the compression spring 11 acts with a large biasing force against the locking ball 12, so that it requires a considerably larger radial force to move the locking ball 6 in the ball receiving cavity 7.

Preferably, the individual helical turns of the helical gear spring 11 are so closely in the locking position next to each other, that they are already brought at a slight displacement of the detent ball 6 from its full leading position in a contact position. In this investment position further compression of the compression spring 11 is no longer possible, which is why the locking ball 12 is displaced in the locking position only by a small distance in the axial direction, which is less than the path that would be necessary to completely displace the detent ball 76 into the ball receiving cavity 7. In the drawings, the compression spring 11 is already shown fully compressed in the locking position.

In the second embodiment shown in Figures 6 to 8, the switch 13 is displaced in the radial direction. Again, stored a pressure ball 10 in the release position in a radial recess 15 of the switch 13, which has a large radial depth. If the switch 13 is moved, the pressure ball 10 moves out of this deep radial recess out into the less deep radial recess 16 and reaches the locking position.

The switch 13 is located in a transverse bore 14, which opens into opposite recesses 19, 20. The length of the switch 13 is adapted to the recesses 19, 20 such that the end of the switch 13 does not protrude beyond the outer contour lateral surface of the output shaft 18. The displacement of the switch 13 is carried out by exercising a face pressure and a subsequent displacement until the end face of the switch 13 is flush in the bottom surface of the recess 19, 20 rests.

In the exemplary embodiments illustrated in FIGS. 1 to 8, an optional transmission ball 10 'is provided. But it is also possible that the pressure ball 10 acts directly on the compression spring 11.

The third exemplary embodiment illustrated in FIGS. 9 to 12 is a ratchet head. This is located in a fork-shaped opening, not shown, of the arm of the ratchet. To this end protrude from the fork opening not shown driving pin, which engage in mounting holes 24 of a gear head 23. From the gear head 23 protrudes a drive polygon 5 from. In one of its polygonal surfaces 3 is a detent ball 6 in a ball receiving cavity 7 a. As can be seen from FIGS. 11 and 12, the output polygon 5 has an axial cavity 9, into which the ball receiving cavity 7 opens. The diameter of the detent ball 6 is also larger than the wall of the axial cavity 9, so that a portion of the detent ball 6 both protrudes outwardly from the ball receiving cavity 7 and projects into the Axialhöhlung 9.

In the axial cavity 9 is a locking ball 12, which has a smaller diameter than the detent ball 6. The locking ball 12 is acted upon by a tensioned compression spring 11. Against the compression spring 11, the end 21 'of a pressure pin 21, which lies in a bore which is in alignment with the axial cavity 9 acts.

The pressure end 21 'opposite end of the pressure pin 21 is fixed to a switch 22 in the form of a hub. The latter is located in a front side recess of the gear head 23 a. In detail, the front side opening is formed by the central opening of a changeover ring 25 for a freewheel gear, not shown.

The switch 22 forming the switching disk is acted upon by a further compression spring 26. The pressure pin 21 is mounted in an insert part 29, which forms a control edge 28 with a front edge, on which are supported two diametrically opposite control cam 27 projecting radially from the pressure pin. A lowermost portion 28 "of the control edge 28 corresponds to the release position. If the control cam 27 in the region of this lowest point 28", then the end 21 'of the pressure pin 21 has the greatest distance to the ball 22. The compression spring 11 has its lowest in this position Preload. The detent ball can be displaced in this state in the ball receiving cavity 7 in the radial direction, wherein the blocking ball 12 in the direction of the pressure pin 21 displaced. If the displaced detent ball released, so the compression spring 11 can relax. In this case, the locking ball 6 is displaced back into the position shown in Figure 11 on the blocking ball 12.

A quarter turn of the switch 22 leads to a quarter turn of the control cam 27 along the stationary control edge 28 toward the position 28 '. There, the control edge 28 form a detent recess, not shown, into which the control cam 27 can enter to fix it in the locked position. Along with the axial displacement of the pressure pin 21 from the release position shown in Figure 11 in the locking position shown in Figure 12, the switch 22 is displaced in the axial direction within the front side recess. The compression spring 11 is tensioned and acts with a higher force on the blocking ball 22, so that the effect discussed above with reference to the first two exemplary embodiments occurs.

The end 21 'of the pressure pin 21 has a cross-section reduced extension 30, which engages in the turns of the compression spring 11. In the locking position, the end face of the extension 30 may have such a small distance to the blocking ball 12 that the blocking ball 12 abuts the end face of the extension 30 when the detent ball 6 moves radially inward, before the detent ball 6 protrudes from the detent recess 4 of FIG Socket insert 1 has emerged. It is therefore also a positive trigger lock possible, so that the socket set can not be deducted by means of a tool in the locking position of output polygon 5.

The embodiment shown in Figures 13 to 17 has a switch in which switched by turning the switch only by 90 ° between the release position and the locking position back and forth can be. Again, the switch 13 consists of a substantially circular cylindrical pin, which rests in a form-matched transverse bore 14 to axial cavity 9. At the level of the axial bore 9, the changeover switch 13 has a recess 31, which forms two essentially planar steps 32, 33.

Opposite the axis of rotation, that is to say the central line of the changeover switch 13, the two stages 32, 33 which are at a 90 ° angle to one another have a different distance. A flat step 32 and a deep step 33 are formed.

The compression spring 11 is acted upon in this embodiment by a pressure pin 21 which is slidably mounted in the Axialhöhlung 9. The switch 21 to the end 13 'of the pressure pin 21 has a reduced diameter and protrudes into the recess 31 inside. Depending on the rotational position of the switch 13, the end face of the end 21 'of the pressure pin 21 lies either on the flat step 32 (FIG. 16) or on the deep step 33 (FIG. 15).

Regarding the locking ball 12, the spring 11 and the detent ball 6 occur while the effects described above. If the pressure pin 21 is supported on the flat step 32, then the device assumes its locking position, the pressure pin 21 is supported on the deep step 33, the device assumes its release position.

All disclosed features are essential to the invention. The disclosure content of the associated / attached priority documents (copy of the prior application) is hereby also incorporated in the disclosure of the application. also included for the purpose of including features of these documents in claims of the present application.

Claims

1. Device for transmitting a torque to a screwing tool element (1) in the form of a socket, a ratchet extension or the like, with a drive polygon (5) for insertion into a shape-adapted polygonal opening (2) of the screwing tool element (1), with a detent ball (6) inserted into a ball receiving cavity (7) of a polygonal surface (8) of the output polygon (5) for entry into a latching recess (4) of a polygonal surface (3) of the polygonal opening (2), with an axial cavity ( 9) arranged on the locking ball (6) and the second portion (10, 21 ') of a switch (13, 22) when switching from a release position to a locking position in the axial direction of the Axialhöhlung (9) is displaced so that the screwing tool element (1) in the release position from the output polygon (5) removable and in the locking position to the output smehrkant (5) is tied, characterized in that the transmission member between its first portion (12) and its second portion (10, 21 ') arranged elastic element (11) which is compressed when switching from the release position to the locking position.

2. Device according to claim 1 or in particular according thereto, characterized in that the elastic element (11) in the release position with a ner such a small spring force on the detent ball (6) acts, that the

Screwing tool (1) without the aid of a tool from the output polygon (5) can be deducted.

3. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the Elastikele- ment (11) in the locking position with such a large spring force on the detent ball (6) acts that the screwing tool (1) can not or not without the aid of a tool from the output polygon (5) can be deducted.

4. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the first portion and / or the second portion of the transmission member is a ball (10, 12).

5. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the elastic element (11) is arranged directly between two balls (10 ¹ , 12).

6. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the elastic element is a particular existing steel compression spring.

7. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the transmission member consists exclusively of balls (10, 10 ', 11) and springs (12).

8. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the changeover switch (13) radially längsverlagerbar or rotatable in a transverse bore (14) for

Axialhöhlung (9) or axially längsverlagerbar in axial extension to the axial cavity (9) is arranged.

9. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the radially storable in a transverse bore (14) inserting switch (13) forms a control edge for the axial displacement of a ball (10) in the Axialhöh- ment (9).

10. The device according to one or more of the preceding claims or in particular according thereto, characterized in that the rotatable in the transverse bore (14) arranged switch (13) has a radial recess (15) in which in the Axialhöhlung (9) inset ball ( 10) rests in the release position.

11. The device according to one or more of the preceding claims or in particular according thereto, characterized by a radial recess (15) diametrically opposed second radial recess (16) with a smaller radial depth, in which the ball (10) rests in the locked position.

12. The device according to one or more of the preceding claims or in particular according thereto, characterized in that the axially displaceable switch (22) cooperates with a in the Axialhöhlung (9) inlying pressure pin (21).

13. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the pressure pin is cam-controlled from its release position into its locking position displaced.

14. Device according to one or more of the preceding claims or in particular according thereto, characterized by by the pressure pin (21) radially projecting control cam (27) to which a control edge (28) is associated net.

15. The device according to one or more of the preceding claims or in particular according thereto, characterized in that the helical turns of the compression spring (11) in the locking position are so little spaced from each other that they at a Radialeinwärtsverlagerung the

Detent ball (6) from its maximum forward position of the ball receiving cavity (7) before reaching their full immersion position in the ball receiving cavity (7) in a movement of the detent ball (6) blocking contact position occur.

16. The device according to one or more of the preceding claims or in particular according thereto, characterized in that the diameter of the transmission member formed by the balls (10, 12) is smaller than the diameter of the detent ball (6).

17. The device according to one or more of the preceding claims or in particular according thereto, characterized in that the switch (13) has two mutually standing at an angle stages (32, 33) having recess (31), wherein the steps at a different distance from the center of the changeover switch (13) and with the end

(21 ') of a pressure pin (21) cooperate.

18. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the two different levels (32, 33) are at an angle of 90 ° to each other.