DE20314486U1 - Screw driver with torque restrictor includes magnetic coupling with inner and outer bodies joined in one piece of magnetic material and with permanent magnets oppositely pole with inner body moved steplessly by adjuster - Google Patents

Abstract

The screw driver has a drive part as handle (6) or shaft and an output part (7) as tool shaft connected through a torque restrictor formed as a magnetic coupling with inner and outer axially concentric bodies. The inner body (1) has several radially outwardly aligned permanent magnets (4) and the outer body has several inwardly directed permanent magnets (3). The two bodies are formed in one piece from magnetic material with plastics bonding and has an initially amorphous structure with several magnets produced in the bodies by locally magnetising the magnetic material. The magnets in the inner bodies are oppositely poled to those in the outer body. The inner body can be moved steplessly or in very small steps axially relative to the outer body through a scaled adjusting device which can be operated from outside the handle.

Description

The The invention relates to a screwing tool with a device for Setting a preselected Torque, when reached the transmission of the torque is interrupted by the drive part in the driven part. devices this genus are known in relatively many designs, both for use with power screwdrivers as well as hand screwing tools. Various systems are used in the known devices Application.

Of Systems of particular interest in the field of the invention are in which the drive part is arranged axially centered on the driven part.

The systems to be observed in comparison with the subject matter of the invention are described by way of example with their functional principle: a screwdriver with torque limitation according to US 5,746,298 has a complicated structure of the coupling mechanism, the parts of which are made of metal. A shaft is mounted in a handle, the shaft has a hexagonal end piece which is encompassed by finger-like segments of a sleeve which is partially slotted in the longitudinal direction. A collar which is adjustable in the longitudinal direction in the hollow of the handle surrounds the finger-like segments and acts with a radial force in this way, a corresponding radial force acts from the ends of the finger-like segments on the hexagonal end piece of the shaft. The closer the collar is to the end of the finger-like segments, the less they are able to rebound radially and allow the hexagonal end piece to rotate - so the higher the release torque. The coupling is expensive to manufacture. To pre-set a trigger torque, the handle must be partially removed, (column 6 , Lines 42 to 49 ), the system is too cumbersome for use with changing torques.

Out OS 26 47 996 a system is known which essentially consists of thrust ball or roller bearings exists, which are biased by a coil spring. The Balls or rollers sit in molded in the bearing washers Resting troughs and are held there by the preload. One of the Bearing washers is connected to the drive part, the other with the stripping section. exceeds the torque a predetermined value, so the circumferential acting force greater than by the preload of the spring in the seat of the ball or rollers acting positive and frictional force, the balls or rollers rise from the recesses, the bearing washers twist against each other, the torque transmission will be interrupted.

at a device according to OS 24 27 352 the drive part consists of a shaft with a plate-like Enlargement of the Shaft on one end. The plate-like enlargement points to the front a wave-shaped toothing in the circumferential direction and forms a driver element. The second driver element forms the same plate-like enlargement with teeth at the shaft end of the stripping section. By a compression spring, a package of disc springs or a coil spring, the driver elements are pressed together.

Out OS 101 43 181 A1 is a device for limiting the from one Screwdriver transferable Torque known. The coupling between the drive part - the handle - and stripping section - the Shaft - consists essentially with a cage sleeve slot-like perforations of the sleeve wall and balls with part of her body protrude into the slots, but with the main part of the body engage in recesses in the pressure plates, which in turn through a compression spring the balls are braced against each other. If one is exceeded by the Biasing the spring specified torque are the balls from the recesses in the openings in the sleeve wall pressed the torque transmission will be interrupted. The construction corresponds to the basic principle of construction described in OS 26 47 996. The construction according to OS 101 43 181 A1 is expensive to manufacture because the coupling is made of precision parts is made of metal.

For a screwdriver with torque limitation according to EP 1 092 510 A2 a shaft has a spherical end surface for transmitting an axial force to the inner surface of the upper handle part, the axial force of a helical spring is transmitted in the direction of the upper handle part to a bushing which is rotatably fitted onto the shaft. The bushing has a toothing on the end face facing the upper handle part and grooves on the circumference, into which ribs engage, which protrude radially from the inside of the handle cavity. A torque is introduced from the handle into the socket via these ribs and into a second toothing via the front toothing, which is formed on the underside of a plate-like enlargement of the shaft. The two toothings have flanks that are beveled in one direction and straight in the other direction, parallel to the axis of the shaft.

If a torque is applied in the direction of the oblique tooth flanks, the toothing of the bushing rises out of the toothing on the plate of the shaft when a torque set by the spring tension is exceeded. This will initiate the torque from Handle in the shaft interrupted. A disadvantage of this construction is that the axial force of the spring acts on the plate of the shaft via the toothing and thus on the spherical end surface on the inner surface of the handle. This axial force is superimposed on the axial force that is applied to the blade of the screwdriver by hand using the screwdriver via the handle and the shaft. As a result, the friction in the area of the contact surface of the end surface of the shaft with the inner surface of the handle is relatively high. As a result, the release torque is influenced not only by the spring tension, but also by the axial force exerted by the hand; in practice, the desired release torque is not maintained with accuracy.

Advantageous is that the essential parts are made of plastic by injection molding are made, but the disadvantage is that with this construction only transmit relatively low torques can be. At higher Torques occur plastic deformations on important elements the mechanics, which reduces the triggering accuracy themselves strong, possibly is the function at all no longer guaranteed.

The known versions are relatively expensive to manufacture because of their complicated structure and the parts are mostly made of metal. That too is Setting often not easy to carry out and the inaccuracy when triggered too high. Recently increased the need for Tightening tools with adjustable maximum values for the transmitted Torque, where the trigger torque should be variably adjustable in a certain range. application areas are the assembly, also in the service, of electrical components that Screwing of plastic parts and the attachment of cutting inserts of cutting tools. With the increasing demand is the demand the user connected, such screwing tools cheaper offer.

The The task is to develop a type of screwdriver that economical can be produced with torques of the required in the area of application Height charged can be quickly adjusted and its functional accuracy over a long period Service life is preserved. This object is achieved by the subject of the invention solved with the features of claim 1.

According to the innovation is provided, the device for limiting a preselected torque not to manufacture from mechanical parts, but as a permanent magnet coupling.

Permanent magnet couplings are known in principle as prior art. However, the known couplings are relatively large in size and mainly made of metal parts. From P DE 2634918 C2 such a coupling for a coal cutting machine is known. With this coupling, permanent magnets are arranged radially inwards in the outer housing. An output shaft is connected to the outer housing. Separated by an air gap, permanent magnets are arranged radially outward in the inner housing. The housing is connected to the drive shaft. North poles and south poles of the two magnet series face each other. The poles attract each other through the force of their magnetic fields and oppose a torque force acting in the circumferential direction. The number of magnets, their size and the dimensions of the outer housing and inner housing determine the load capacity of the coupling with a torque before the coupling is no longer transmitted from the drive shaft to the output shaft by rotating the inner housing relative to the outer housing or the magnets. In one embodiment, it is provided that the inner housing and the cavity in the outer housing are conical. The inner nut can be axially displaced on the shaft by the adjusting nut, thereby changing the air gap and thus the maximum transmissible torque. For this purpose, the adjustment option essentially serves to set the maximum permissible torque once and in this way to ensure that a higher torque is not introduced into the cutting device and machine parts are thereby damaged.

A magnetic coupling, in which individual magnets are inserted into the outer housing and the inner housing, is relatively expensive to manufacture and is not ideal for use with a screwing tool. Therefore, according to the innovation, a simpler construction is proposed: the device for limiting the transmitted torque according to the innovation essentially consists of two rotatable, axially concentric bodies, consisting of magnetic materials, preferably of rare earths / neodyne, which are bound by plastic. The bodies are shaped using the injection molding process. For this purpose, magnetic material and plastic are first processed into amorphous granules, which are further processed in the injection molding process. The bodies produced in this way initially have an amorphous structure. A plurality of magnets are produced in these bodies by appropriate magnetization processes. The magnetization is such that, for example, the inner of the two concentrically arranged bodies has a plurality of magnets which are pressed radially outward with the north poles, while the outer body is the same che number of magnets, the south poles of which are directed radially inwards. Of course, the poles can also be arranged in reverse. The magnetic poles attract each other and the two bodies adjust so that the north and south poles face each other directly. The attraction of the magnetic poles counteracts an angular adjustment of the two bodies relative to each other, so that a torque can be transmitted from one body to another. If the tangentially acting force of a torque exceeds the tangential component of the attractive force acting between the magnetic poles of the two bodies, then an angular rotation of the two bodies takes place relative to one another. The technical application of this physical phenomenon is that a torque is to be transmitted from a drive part to an output part, but the transmission is interrupted when a preselected torque is exceeded. This interruption is caused by the angular movement of the two bodies relative to one another - which is shown by the drive part turning relative to the driven part blocked by a force against rotation. In the screwing tool with the device for limiting the transmitted torque, the drive part consists of the handle or a drive shaft, which is connected, for example, to a power drive, for example an electric screwdriver. This drive part is connected to the outer body. The second, inner body is connected to the driven part, for example a shaft with a device for holding interchangeable screwing tools. Both bodies are mounted concentrically to one another, for example in such a way that the body of the drive part has a cavity in which the body of the drive part is mounted. The body of the driven part is supported, preferably by a ball bearing, for absorbing axial forces in the drive part and is also guided radially in this area. A second radial guide is preferably provided in such a way that the shaft of the screwing tool is guided in a cap or cover plate which is fastened to the end face of the outer body. The cavity in the outer body can have a cylindrical shape, the inner body also has a cylindrical shape, it is with its undersize its diameter is matched to the diameter of the cavity so that there is a small air gap between the two bodies. The size of the transmitted torque is determined by several design measures. How long the magnets can be in the radial direction depends on the diameter of the inner body and the diameter of the shaft inserted therein. The length of the inner body in the axial direction determines the possible length of magnets in this direction. The width of the magnets depends on the number of magnets selected in the circumferential direction. The resulting size of the individual magnets determines the strength of their magnetic field.

In The outer diameter is determined analogously of the outer body and the diameter of the cavity formed therein, the wall thickness, respectively the possible Length of Magnets in the radial direction. The length of the magnets in axial Direction is by length the cave determines and corresponds to the length of the cylindrical inner body. The width of the magnets in the circumferential direction is essentially the same with the width of the magnets in the inner body because of its outer diameter is substantially equal to the diameter of the cavity in the outer body. It will be convenient chosen the same number of magnets in the outer body and the inner body.

The Magnetization is done so that the magnetic fields on each other facing poles of the inner and outer bodies emerge on the opposite side the magnet, however, over the fields the body material are closed. So it is not in the radial direction full radial length as a magnet length used. There are also neutral, non-magnetic ones in the circumferential direction activated zone between the magnets.

The Amount of to be transferred Torque can be changed in two ways:

A possibility is, the coverage the opposite one Change magnets. If the magnets face each other directly with their full pole area, is the strongest Attraction and thus the greatest resistance against rotation in the circumferential direction, it can transmit the highest torque become. This position is given when the inner body is in full length into the cave of the outer body immersed is. To set a lower torque, the inner one body pushed out of the cavity by an adjusting device. Then the magnets face each other only with a part of their axial length The force of attraction is lower and thus the resistance to twisting in the circumferential direction. If the adjustment via a screw spindle or spirally rising ring surfaces the adjustment elements takes place, the desired torque until its interruption Forwarding - that Tripping torque - stepless can be set. The dimensioning of both bodies and hence the magnet, or the degree of filling of the body material with magnetic material, determine the area within which torques are transmitted can be.

The other possibility is to enlarge the air gap between the magnets of the inner and outer body, thereby increasing the magnetic fields acting on one another and their attraction weaknesses. In order to achieve this with an axially concentrically arranged inner and outer body by adjusting the inner body in the longitudinal direction, the inner body is conical in the longitudinal direction and the cavity in the outer body as well. As with the version with a cylindrical inner body and cylindrical cavity, the magnets are most attractive when the magnets face each other with their full pole face and the smallest possible air gap. This is the case when the entire length of the inner body is immersed in the hollow of the outer body. If the inner body is pushed out of the cavity by an adjusting device, the covering of the magnets changes on the one hand, and on the other hand an air gap is created, which increases the further the inner body is pushed out of the cavity. The attraction of the magnet is weakened in two ways. In this version, therefore, the tripping torque is changed with a shorter adjustment path than in the version with a cylindrical body.

The Subject of the invention is illustrated by the drawings.

It demonstrate

1 a longitudinal section through the screwing tool with a device for limiting a preselected torque in the embodiment with an inner body in a cylindrical shape and corresponding outer body, in a setting for the lowest triggering torque.

1

der innere Körper

2

der äußere Körper

3

Magnet im äußeren Körper

3a

die magnetisch neutrale Zone hinter rückwärtigen Ende der

Magnete

4

Magnet im inneren Körper

4a

die magnetisch neutrale Zone hinter rückwärtigen Ende der

Magnete

5

der Luftspalt zwischen dem Magneten

6

der mit dem inneren Körper (1) verbundene Handgriff, das An

triebsteil

7

der in den inneren Körper eingesetzte Schaft, das Abtriebsteil

8

der Verstellzapfen mit Verstellbüchse (11) zur achsialen Ver

stellung des inneren Körpers gegenüber dem äußeren Körper

9

die Verstellbüchse

10

die Verschiebebüchse, mit einer äußeren

Verzahnung (23) undrehbar in dem Griff (6) geführt.

10a

ein einstückig mit der Verschiebebüchse verbundener Schaft

11,12

die einander anliegende spiralig ansteigenden Ringflächen

13

die axiale Lagerung des inneren Körpers durch eine Kugel

14

eine Kappe, an der vorderen Stirnseite des Gehäuses (17)

befestigt, zur radialen Führung des Schaftes (7)

15

eine Ausnehmung am Ende des Verstellzapfens (8), zum Ein

stecken eines Werkzeuges zum Drehen des Verstellzapfens

16

die Innenverzahnung in der Höhlung des Handgriffes (6)

17

das Gehäuse

18

eine Stirnverzahnung am Grund der Höhlung des Handgriffes

(6) und an der Rückseite der Verstellbüchse (9)

19

eine Druckfeder, die die Verzahnung (18) in Eingriff hält

20

eine Skalenscheibe, mit dem Verstellzapfen (8) verbunden, zum

Einstellen des vorgewählten Auslösedrehmomentes

21

eine Verrippung von Gehäuse (17) und äußerem Körper (2) zur

drehfesten Verbindung der beiden Teile

22

eine Verrippung von Handgriff (6) und Gehäuse (17) zur festen

Verbindung der beiden Teile

23

eine Verzahnung am Umfang der Verschiebebüchse (10) zur

drehfesten Verbindung mit dem Handgriff (6) über die Innenver

zahnung (16)

24

eine Druckfeder

Are in it

1

the inner body

2

the outer body

3

Magnet in the outer body

3a

the magnetically neutral zone behind the rear end of the

magnets

4

Magnet in the inner body

4a

the magnetically neutral zone behind the rear end of the

magnets

5

the air gap between the magnet

6

the one with the inner body ( 1 ) connected handle, the on

driving part

7

the shaft inserted into the inner body, the stripping part

8th

the adjustment pin with adjustment sleeve ( 11 ) for axial ver

position of the inner body in relation to the outer body

9

the adjustable sleeve

10

the sliding bush, with an outer

Gearing ( 23 ) non-rotating in the handle ( 6 ) guided.

10a

a shaft connected in one piece to the sliding sleeve

11.12

the mutually adjacent, spirally rising ring surfaces

13

the axial support of the inner body by a ball

14

a cap on the front face of the housing ( 17 )

attached, for radial guidance of the shaft ( 7 )

15

a recess at the end of the adjustment pin ( 8th ), to my

insert a tool to turn the adjustment pin

16

the internal toothing in the hollow of the handle ( 6 )

17

the housing

18

a serration at the bottom of the hollow of the handle

( 6 ) and on the back of the adjustable sleeve ( 9 )

19

a compression spring, which the toothing ( 18 ) engages

20

a dial with which the adjusting pin ( 8th ) connected to

Setting the pre-selected trigger torque

21

ribbing of the housing ( 17 ) and outer body ( 2 ) to

non-rotatable connection of the two parts

22

a ribbing of the handle ( 6 ) and housing ( 17 ) for fixed

Connection of the two parts

23

a toothing on the circumference of the sliding bush ( 10 ) to

non-rotatable connection with the handle ( 6 ) via the interior

toothing ( 16 )

24

a compression spring

2 a longitudinal section through the screwing tool with a device for limiting a preselected torque in the embodiment with an inner body in cylindrical shape and corresponding outer body, in a setting for the highest triggering torque.

24

eine Druckfeder

Are in it

24

a compression spring

3 a longitudinal section through the screwing tool with a device for limiting a preselected torque in the off Guide with inner body in a conical shape and corresponding outer body, in a setting for the highest tripping torque.

1

der innere Körper

2

der äußere Körper

3

Magnet im äußeren Körper

3a

die magnetisch neutrale Zone hinter rückwärtigen Ende der

Magnete

4

Magnet im inneren Körper

4a

die magnetisch neutrale Zone hinter rückwärtigen Ende der

Magnete

5

der Luftspalt zwischen dem Magneten

6

der mit dem inneren Körper (1) verbundene Handgriff, das An

triebsteil

7

der in den inneren Körper eingesetzte Schaft, das Abtriebsteil

8

der Verstellzapfen zur axialen Verstellung des inneren Kör

pers gegenüber dem äußeren Körper

9

die Verstellbüchse

10

die Verschiebebüchse, mit einer äußeren mit einer Außenver

zahnung (23) undrehbar in dem Griff (6) geführt

10a

ein einstückig mit der Verschiebebüchse verbundener Schaft

11,12

die einander anliegenden spiralig ansteigende Ringfläche

13

die axiale Lagerung des inneren Körpers durch eine Kugel

14

eine Kappe, an der vorderen Stirnseite des Gehäuses

befestigt, zur radialen Führung des Schaftes (7)

15

eine Ausnehmung am Ende des Verstellzapfens (8) zum Ein

stecken eines Werkzeuges zum Drehen des Verstellzapfens

16

die Innenverzahnung in der Höhlung des Handgriffes (6)

17

das Gehäuse

18

eine Stirnverzahnung am Grund der Höhlung des Handgriffes

(6) und an der Rückseite der Zahnbüchse (11)

19

eine Druckfeder, die die Verzahnung (18) in Eingriff hält

20

eine Skalenscheibe, mit dem Verstellzapfen (8) verbunden, zum

Einstellen des vorgewählten Auslösedrehmomentes

21

eine Verrippung von Gehäuse (17) und äußerem Körper (2) zur

drehfesten Verbindung der beiden Teile

22

eine Verrippung von Handgriff (6) und Gehäuse (17) zur festen

Verbindung der beiden Teile

23

eine Verzahnung am Umfang der Verschiebebüchse (10) zur

drehfesten Verbindung mit dem Handgriff (6) über die Innenver

zahnung (16)

24

eine Druckfeder

Are in it

1

the inner body

2

the outer body

3

Magnet in the outer body

3a

the magnetically neutral zone behind the rear end of the

magnets

4

Magnet in the inner body

4a

the magnetically neutral zone behind the rear end of the

magnets

5

the air gap between the magnet

6

the one with the inner body ( 1 ) connected handle, the on

driving part

7

the shaft inserted into the inner body, the stripping part

8th

the adjustment pin for the axial adjustment of the inner body

pers towards the outer body

9

the adjustable sleeve

10

the sliding sleeve, with an outer with an outer ver

toothing ( 23 ) non-rotating in the handle ( 6 ) guided

10a

a shaft connected in one piece to the sliding sleeve

11.12

the adjacent, spirally rising ring surface

13

the axial support of the inner body by a ball

14

a cap on the front face of the case

attached, for radial guidance of the shaft ( 7 )

15

a recess at the end of the adjustment pin ( 8th ) to my

insert a tool to turn the adjustment pin

16

the internal toothing in the hollow of the handle ( 6 )

17

the housing

18

a serration at the bottom of the hollow of the handle

( 6 ) and on the back of the tooth box ( 11 )

19

a compression spring, which the toothing ( 18 ) engages

20

a dial with which the adjusting pin ( 8th ) connected to

Setting the pre-selected trigger torque

21

ribbing of the housing ( 17 ) and outer body ( 2 ) to

non-rotatable connection of the two parts

22

a ribbing of the handle ( 6 ) and housing ( 17 ) for fixed

Connection of the two parts

23

a toothing on the circumference of the sliding bush ( 10 ) to

non-rotatable connection with the handle ( 6 ) via the interior

toothing ( 16 )

24

a compression spring

4 a longitudinal section through the screwing tool with a device for limiting a preselected torque in the embodiment with an inner body in a conical shape and a corresponding outer body, in a setting for a low trigger torque.

1

der innere Körper

2

der äußere Körper

5

der Luftspalt zwischen den Magneten

24

eine Druckfeder

Are in it

1

the inner body

2

the outer body

5

the air gap between the magnets

24

a compression spring

5 a cross section along the line AA in 3

1

der innere Körper

2

der äußere Körper

5

der Luftspalt zwischen dem Magneten

7

der in den inneren Körper eingesetzte Schaft, das Abtriebsteil

13

Magnete (3) im inneren Körper

11

Magnete (4) im äußeren Körper

12

die im Körpermaterial geschlossenen Magnetfelder der hinteren

Pole der Magneten

Are in it

1

the inner body

2

the outer body

5

the air gap between the magnet

7

the shaft inserted into the inner body, the stripping part

13

Magnets ( 3 ) in the inner body

11

Magnets ( 4 ) in the outer body

12

the magnetic fields of the back that are closed in the body material

Pole of the magnets

6 , A cross section along the line B – B in 4

1

der innere Körper

2

der äußere Körper

5

der Luftspalt zwischen dem Magneten

7

der in den inneren Körper eingesetzte Schaft, das Abtriebsteil

13

die Magneten (3) im inneren Körper

14

die Magneten (4) im äußeren Körper

15

die im Körpermaterial geschlossenen Magnetfelder der hinteren

Pole der Magneten

Are in it

1

the inner body

2

the outer body

5

the air gap between the magnet

7

the shaft inserted into the inner body, the stripping part

13

the magnets ( 3 ) in the inner body

14

the magnets ( 4 ) in the outer body

15

the magnetic fields of the back that are closed in the body material

Pole of the magnets

The Structure and interaction of the inner body and outer body, as the two parts the magnetic coupling, is through the drawings and descriptions explained.

Because different in the screwing tool according to the innovation Torques to be preselected in a certain range comes the construction of the adjustment device is of particular importance to. The adjustment must be simple but accurate can.

According to the construction of the screwing tool with the device for limiting the preselected torque, a handle forms in the example represented by the figures ( 21 ) preferably made of plastic by injection molding - the drive part. It is form-fitting, e.g. by ribbing, pressing, gluing to the housing ( 17 ) connected. In a hole at the end of the handle ( 6 ) and in a cavity is an adjustment pin ( 8th ), connected to the adjustable bushing ( 9 ) rotatably and axially via a spur toothing ( 18 ) on the back of the adjustable sleeve ( 9 ) and at the bottom of the hollow of the handle ( 6 ) supported.

If the adjustment pin ( 8th ) rotates, the adjusting sleeve connected to it rotates ( 9 ) and their ring surfaces rising spirally in the circumferential direction ( 12 ) against the spiraling ring surface ( 12 ) of the opposite sliding bush ( 10 ). The spreading length changes depending on the angular position of the two bushings. The change in length causes the inner body to shift ( 1 ) to change the coverage of the magnets ( 3 . 4 ) and, in the conical design of the air gap, and thus the attraction of the magnets to each other. So that the sliding bush ( 10 ) when adjusting against the handle ( 6 ) are twisted, the sliding bush ( 10 ) with external teeth ( 23 ) and the hollow in the handle ( 6 ) with an internal toothing ( 22 ), both gears interlock positively. In the inner body ( 1 ) engages on the face of the pin facing the handle ( 10a ) of the sliding bush and form the radial bearing for the inner body ( 1 ). For radial storage, the shaft ( 7 ) so far through the inner body ( 1 ) that a pin protrudes from the rear face of the inner body and into the pin ( 10a ) intervenes. At its end, the inner body can also be supported axially, for example via a ball ( 13 ). For radial support of the inner body ( 1 ) on the front is a cap or cover plate ( 14 ) on the housing ( 17 ) attached, the shaft ( 7 ) is guided radially in the bore of this cap or the cover. Although the between the inner ( 1 ) and outer ( 2 ) Magnetic force acting on the body pulls the inner body - if it is slightly shifted outwards from the hollow in the outer body - the inner body into the hollow, it is useful to place between the front face of the inner body and the cap / cover plate ( 14 ) a compression spring ( 24 ) to proceed. The axially acting compressive force can be low, but it must ensure that the inner body on its rear side - or the shaft - so on the axial bearing ( 13 ) that no bearing element, such as a ball, can fall out of the bearing. In a simplified version, the screwing tool with a device for limiting the transmitted torque can also be constructed so that the housing ( 17 ) is eliminated and the outer body ( 2 ) is shaped so that it also forms the housing.

An advantage of the innovation compared to other devices for such a purpose is the simple, inexpensive way of producing the parts in the injection molding process and the production of integrated magnets in the injection molded parts of the inner body ( 1 ) and outer body ( 2 ). Another advantage is that the torque transmitting parts do not touch and are therefore almost wear-free. Manufacturing using the injection molding process also opens up opportunities to manufacture the parts of the adjustment device also cost-effectively using the injection molding process and to assemble all parts without any significant reworking.

Claims (11)

Screwing tool with a device for limiting the transmitted torque, consisting of a drive part in the form of a handle ( 6 ) or shaft for insertion into a power wrench, and an output part in the form of a shaft ( 7 ) a screwing tool or a receiving device for interchangeable insert tools, the drive part and the driven part being connected to one another by the device for limiting the transmitted torque, the device is essentially designed as a magnetic coupling and consists of an inner body and an outer body, both bodies being axially concentric with one another arranged in such a way that the inner body in a cavity of the outer body with an air gap ( 5 ) between its surface the Wall of the cavity is rotatably mounted, the inner body ( 1 ) a plurality of radially outwardly directed permanent magnets ( 4 ) and the outer body has a plurality of inward-pointing permanent magnets ( 3 ), characterized in that the inner body ( 1 ) and outer body ( 2 ) is made in one piece from magnetic material with a plastic bond by injection molding, initially has an amorphous structure and in these bodies ( 1 . 2 ) a plurality of magnets (by means of a corresponding locally limited magnetization of the magnetic material) 3 . 4 ) is generated, whose magnetic fields on the inner body ( 1 ) directed radially outwards and with the outer body ( 2 ) are directed radially inwards, the magnets ( 4 ) in the inner body ( 1 ) are polarized opposite to the magnets ( 3 ) in the outer body ( 2 ) to the individual magnets ( 3 . 4 ) around each other zones ( 3a . 3b . 4a . 4b ) that are not magnetically activated, that the inner body ( 1 ) continuously or in very small steps by a scaled, from outside the handle ( 6 ) adjustment device to be confirmed axially with respect to the outer body ( 2 ) can be moved. Screwing tool with a device for limiting the transmitted torque according to claim 1, characterized in that the drive part ( 6 ) with the outer body ( 2 ) and the driven part ( 7 ) with the inner body ( 1 ) is non-rotatably connected. Screwing tool with a device for limiting the transmitted torque according to claim 1 and 2, characterized in that the inner body ( 1 ) and the hollow of the outer body ( 2 ) have a cylindrical shape. Screwing tool with a device for limiting the transmitted torque according to claim 1 and 2, characterized in that the inner body ( 1 ) and the hollow of the outer body ( 2 ) have a conical shape Screwing tool with a device for limiting the transmitted torque according to claim 1 to 4, characterized in that the adjusting device in the cavity of the handle ( 6 ) is stored and essentially from the adjustment sleeve ( 9 ) and the sliding sleeve ( 10 ) there is the adjustable sleeve ( 9 ) to the end of the handle ( 6 ) adjusting pin ( 8th ) against the sliding bush ( 10 ) can be rotated, the sleeve on the mutually facing end faces spirally rising ring surfaces ( 11 . 12 ) exhibit. Screwing tool with a device for limiting the transmitted torque according to claim 1 to 5, characterized in that the sliding bush ( 10 ) by an external toothing ( 23 ) in an internal toothing ( 16 ) in the handle ( 6 ) engages and is guided non-rotatably. Screwing tool with a device for limiting the transmitted torque according to claim 1 to 6, characterized in that the sliding bush ( 10 ) a shaft ( 10a ) that has the inner body on its front and circumference ( 1 ) rotatably mounted. Screwing tool with a device for limiting the transmitted torque according to claim 1 to 6, characterized in that the outer body ( 2 ) in the cavity of a housing ( 17 ) stored and over a rib running in the longitudinal direction on a circumference ( 21 ) with a corresponding ribbing in the cavity of the housing ( 17 ) is rotatably connected to the housing. Screwing tool with a device for limiting the transmitted torque according to claim 1 to 8, characterized in that the adjusting sleeve ( 9 ) a toothing on its rear face ( 18 ), with which they have an identical toothing at the bottom of the hollow of the handle ( 6 ) intervenes. Screwing tool with a device for limiting the transmitted torque according to claim 1 to 8, characterized in that the magnetic material in the inner body ( 1 ) and outer body ( 2 ) consists of rare earths and / or Neodyne. Screwing tool with a device for limiting the transmitted torque according to claim 1 to 9, characterized in that the adjusting sleeve ( 9 ), the sliding bush ( 10 ) with the shafts ( 8th . 10a ) the handle ( 6 ) the housing ( 17 ) are preferably made of plastic by injection molding.