DE8803289U1 - Torque wrench - Google Patents

Description

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Utility model application

j Eduard Wille GmbH & Co.,Lindenallee 27,0-5600 Wuppertal 12 J

Torque wrench

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Technical area | The invention relates to a torque wrench,

containing 15

(a) an elongated outer casing

(b) a housing extending in and connected to the outer housing near a first end of the

Torque wrench pivoting inner part,

(c) a tool arranged at the first end

(d) a handle portion disposed at the second end of the torque wrench and

(e) a spring-loaded toggle mechanism acting between the handle part and the tool-carrying part, which, when a force exceeding the handle part, the toggle mechanism and the said part of the torque transmitted to the tool and allows a pivoting movement between the outer housing and the inner part,

Underlying state of the art

Such a torque wrench is known, for example, from US Patent No. 4,655,104. In this torque wrench, the inner part is a solid body that is mounted in the outer housing at its first end and carries a tool at its end protruding from the outer housing. A handlebar is hinged at one end to the handle-side end of the inner part. At the other end of the handlebar there is a pin on which a spring acting in the longitudinal direction of the outer housing presses. The inner part and the spring-loaded handlebar form a toggle lever mechanism that is triggered when a predetermined torque is exceeded by overcoming the preload of the spring and allows an audible and tangible snapping movement of the inner part relative to the outer housing.

Similar triggering torque wrenches are shown in US-PS 3 202 021 and DE-OS 25 53 326. There, the toggle lever mechanism consists of a spring-loaded lever, which is supported by a roller on the inner wall of the outer housing, and a link that connects this lever to the inner part.

In another known torque wrench, the knee lever mechanism contains a lever that is pivotally mounted in the outer housing and the handle part that is made up of one part. This lever presses with one end on the handle-side end of the inner part. The other end of the lever is connected via a link to a spring-loaded sliding piece that can move longitudinally in the outer housing.

In the known torque wrenches, the torque is transmitted via the inner part. This inner part must therefore be very stable. Since the inner part is located inside the outer housing, this stability can only be achieved by a solid design of the inner part, usually as a forged part. This in turn means that the torque wrench becomes quite heavy.

A further disadvantage of the known torque wrenches of the type described above is that the screw pivot point, around which the torque is exerted by the user on the screw, is very different from the pivot point of the inner part relative to the outer housing, which acts as the "functional pivot point". This means that the release point depends heavily on the force application point on the handle part.

Disclosure of the invention

The invention is based on the object of creating a simple and lightweight torque wrench.

The invention is further based on the object of bringing the pivot point of the inner part closer to the screw pivot point and thereby reducing the dependence of the release point on the force application point at which the user grips the handle part.

The invention is further based on the object of increasing the length of the lever arm on which the toggle lever mechanism acts in a torque wrench of the type defined at the outset, so that the effective forces and the preload of the spring can be reduced.

According to the invention, these objects are achieved in that

(f) the tool is attached to the outer casing and (g) the inner part is rigidly attached to the handle part.

Because the tool is mounted on the outer casing, which is naturally larger than the inner part, with a relatively small wall thickness of the outer casing the required stability can be achieved. The torques acting on the inner part are smaller. The inner part can therefore be made considerably lighter than with the known torque wrenches described. This results in an overall result with the same dimensions and equal torques a weight reduction of the entire torque wrench.

Because the tool is mounted on the outer housing, the distance between the tool and the pivot point between the outer casing and the inner part can be reduced. Since the toggle lever mechanism acts on the outer casing as the part that carries the tool and not on the inner part, the point of action of the toggle lever mechanism can be shifted to the handle side. Both influences act to enlarge the "function lever", i.e. the lever arm with which the knee lever mechanism engages the inner part.

The pivot point of the inner part can be moved closer to the screw pivot point.

Embodiments of the invention are the subject of the dependent claims.

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An embodiment of the invention is explained in more detail below with reference to the accompanying drawings.

Short description of the drawings Fig.1 shows a torque wrench according to the state of the Technique to illustrate the Invention achievable improvement of the

iü Lever arm lengths and the mutual position of

Screw pivot point and pivot point of the inner part.

Fig.2 is a schematic representation, similar to Fig.1, of a torque wrench constructed according to the invention.

Fig.3 is a longitudinal section of a structural

Design of the torque wrench from Fig.2.
20

Presentation of the state of the art

Fig.1 shows a torque wrench according to the state of the art. 25

The torque wrench has an outer housing 10, which is made of a profile tube with a rectangular cross-section. The profile tube 10 forms a handle part 12 at its right-hand end in Fig. 1, which the user's hand grips. The middle force application point is designated 14.

Near the left end in Fig.1 is in the Outer housing 10 an inner part 16 around a bearing pin 18

The inner part 16 is supported by a

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solid forged part 1. The inner part 16 protrudes from the outer housing 10 on the left in Fig. 1 and forms a tool holder 20 for an insert tool 22. The insert tool 22 acts around a screw pivot point 24.

A shaft 26 of the inner part 16 projects to the right in Fig. 1.

In the middle area of the outer housing 10, a two-armed lever 30 is mounted on a bearing pin 28. The two-armed lever 30 has a nose 32. The nose 32 rests on the inner part 16. The second arm of the lifting element 36 is connected via a link 34 to a sliding piece 36 which is guided in the outer casing 10. The sliding piece 36 is under the influence of a spring 38 which is supported on a nut 40. The nut 40 is in the The outer housing is rectangular in cross-section and is non-rotatably guided and sits on a threaded spindle 42. The threaded spindle 42 is mounted in a bearing part 44 so that it can rotate but cannot move axially. The threaded spindle 42 can be rotated using a knob 46. The Nut 40 is adjusted axially and the preload of spring 38 is changed.

The spring 38, the link 34 and the lever 30 form a toggle lever mechanism 48. The spring 38 seeks via the Handlebar 34, which forms an angle with the longitudinal direction of the outer housing 10, is pivoted counterclockwise. The lever 30 thereby holds the inner part 16 in the position shown. If a torque is exerted on the outer housing 10 in the clockwise direction of Fig.1, then, due to the reaction torque of the screw on the inner part 16, a torque acts around the bearing pin 18, which tries to pivot the inner part 16 relative to the outer part 10 in the anti-clockwise direction of Fig.1. This is counteracted by the spring 38 via the toggle lever mechanism 48 with torque exerted on the lever 30. If a

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If a certain torque exerted on the screw around the screw pivot point, the size of which can be adjusted using the knob 46, is exceeded, the reaction torque acting on the inner part 16 overcomes the spring 38 via the toggle lever mechanism 48. The inner part 16 is jerkily pivoted relative to the outer housing 10. The lever 30 strikes the inner wall of the outer housing. This is heard and felt by the user.

It can be seen that the bearing pin 18 of the inner part 16 is offset by a fairly large distance from the screw pivot point 24. The "function lever", i.e. the distance between the bearing pin 18 and the nose 32, is quite short.

Preferred embodiment of the invention

In the torque wrench of Fig.2, an outer housing is designated by 50. The outer housing 50 is formed from a profile tube with a rectangular cross-section. A handle part 52 also consists of a profile tube with a rectangular cross-section. However, the handle part is designed as a component separate from the outer housing. An inner part 54 is also designed as a profile tube with a rectangular cross-section. This inner part 54 is firmly connected to the handle part 52. The outer housing 50 is pivotally mounted on the inner part 54 by means of a bearing pin 56. A tool 58 is inserted into the left end of the outer housing 50 in Fig.2.

The right end of the outer casing 50 in Fig.2 is cut off at an angle. The lower wall of the outer casing 50 in Fig.2 protrudes from the upper wall in Fig.2. The handle part 52 is at its end in Fig.2

left end is cut off at an angle accordingly. The upper wall shown in Fig.2 protrudes from the lower wall shown in Fig.2. This creates a narrow, diagonal gap 60 between the outer casing 50 and the handle part 52. which allows relative movement of the parts.

A two-armed lever 62 is mounted on a bearing pin 64 in the side walls of the handle part 52 which project obliquely relative to the lower wall. The lever 62

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the protruding wall 66 at the right end of the outer housing 50. The other end of the lever 62 is connected to a sliding piece 70 via a link 68. The sliding piece 70 is displaceable in the handle part 52 A pre-tensioned spring 72 rests against the sliding piece. The spring 72 is supported on a nut 74. The nut 74 has a rectangular cross-section and is non-rotatable but slidably guided in the handle part 52. The nut 74 is on a threaded The adjusting spindle is rotatably but axially immovably mounted in an end piece 78 of the handle part 52. At the end of the ^adjusting spindle there is an adjusting knob 80.

The arrangement with the lever 62, the handlebar 68, the slider 70 and the spring 72 forms a toggle lever mechanism 82.

The upper part 84 of the wall of the handle part 52 in Fig. 2, which projects to the left, is firmly connected to the inner part 54.

The central force application point at which the user acts on the handle part 52 is indicated in Fig.2 &ii 86.

The torque wrench described works as follows:

In normal operation, the outer housing 50 is held in its position shown relative to the inner part by the lever 62 against the effect of the torque applied via the tool 58. The upper turn of the outer housing in Fig.2 rests against the upper wall of the inner part 54 in Fig.2 when rotated clockwise in Fig.2. When a certain torque is exceeded, the lever 62 of the toggle lever mechanism 82 gives way and presses the sliding piece 70 to the right in Fig.2 via the link 68. The more the "knee" formed by the lever 62 and the link 68 is stretched, the greater the force component falling in the longitudinal direction of the torque wrench. After the lever 62 gives way, the mechanical resistance of the toggle lever mechanism collapses. The handle part 52 is suddenly pivoted clockwise against the outer housing 50.

This is heard and felt by the user.

From a comparison of Figures 1 and 2 it can be seen that in the torque wrench of Fig.2, with the same overall length of the torque wrench, the "function lever", i.e. the distance between the bearing pin 56 and the point of contact of the lever 62 on the outer body 50 is greater than the functional lever in the known design according to Fig. 1. As a result, the preload of the spring 72 can be less than the preload of the spring 38 of Fig. 1. The transmitted forces are reduced. Furthermore, it can be seen that in the design according to Fig.2 the bearing pin 56 is moved closer to the screw pivot point than in the design according to Fig.1.

This is made possible by the tool 58 being inserted directly into the outer housing 50. The bearing pin 56 can then be arranged in close proximity to the tool in the outer housing. The bearing pin 56 is nevertheless sufficiently far away from the end of the outer housing 50 to ensure that the bearing pin 56 is held securely. The design of Fig.2 also allows the contact point between the part carrying the tool, namely the outer housing and the toggle lever mechanism to the right in Fig.2. This reduces the force and the toggle lever mechanism can be made smaller. The extension of the "function lever" does not lead to an increase in weight, since the existing Outer housing 50 is used. The inner part can be designed as a relatively light profile tube.

Fig.3 shows a structural design of the torque wrench. Corresponding parts in Fig.3 are provided with the same reference numerals as in Fig.2.

The inner part 54 is attached to the handle part 52 by two Screws 88 and 90. Screws 88 and 90

are in a nut block 92 on the inside of the

Inner part 54 is screwed in.

The sliding piece 70 is a sheet metal part that is bent into a U-shape and is slidably guided in the handle part 52. The two sides of the U-shaped sheet metal part spring back in the longitudinal direction so that edges 94 are formed. A pressure disk 96 rests on these edges 94. The spring 72 rests on the pressure disk 96. The spring 72 is pre-tensioned and is supported on the nut 74. As a result, the pressure disk 96 is always in contact with the edges 94 held.

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The adjusting spindle 76 has a hexagonal profile. The adjusting spindle 76 is guided in a bore 98 of a cross bolt 100 so that it can be moved longitudinally. The adjusting spindle 76 has a circumferential groove 102 into which a seated, spring-loaded locking ball engages. The adjusting spindle 76 is thus held in the axial position shown. However, the steep spindle 76 can be moved axially by overcoming the locking spring loading the locking ball.

to the right in Fig.3.
10

A threaded bushing 104 with an external thread is located on the adjusting spindle 76. In the right end of the threaded bushing 104 in Fig.3 there is an end piece 106 with a hexagon socket. The end piece 106 is connected to the The threaded bushing 104 is firmly connected and guided on the adjusting spindle 76. The nut 74 is guided on the threaded bushing 106, which in turn is guided non-rotatably in the handle part. Under the influence of the spring 72, the end piece 106 rests on the cross bolt 100. This means that the axial position of the threaded bushing 104 is fixed.

At the left end of the adjusting spindle in Fig.3 there is a Stop body 108 is attached, which controls the movement of the Adjusting spindle 76 to the right in Fig.3 is limited by

the stop body 108 comes to rest on the front face of the threaded bushing 104.

On the right end protruding from the handle part 52

An adjusting knob 110 is located on the adjusting spindle 76. 30

A scale carrier 112, which carries a scale, is connected to the nut 74. The scale can be read through a hole 114 in the handle part 52.

A handle 116 is located on the handle part 52. The handle 116 has openings 118,120 for the screws 88 and 90. The heads of the screws 88.30 are located in the openings 118,120. This secures the handle 116 in the longitudinal direction. The handle also has an opening 122 which is aligned with the opening 114 of the handle part 52.

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Claims (20)

&bull; · · &bull; · ■ Protection claims 1. Torque wrench, containing (a) an elongated outer casing (50) (b) an inner part (54) extending into the outer housing (50) and pivotally connected thereto near a first end of the torque wrench, (c) a tool (58) arranged at the first end (d) a handle portion (52) disposed at the second end of the torque wrench and (e) a spring-loaded toggle mechanism (82) acting between the handle part (52) and the part carrying the tool (58), which, when a force applied over the handle part (52), the toggle mechanism (82) and the said part is exceeded 2S triggers the torque transmitted to the tool (58) and allows a pivoting movement between the outer housing (50) and the inner part (54), characterized in that (f) the tool (58) is attached to the outer housing (50) and (g) the inner part (54) is rigidly attached to the handle part (52). 2. Torque wrench according to claim 1, characterized in that the toggle lever mechanism (82) has a lever (62) which is pivotally mounted relative to the handle part (52), which rests at one end on the outer housing (50) carrying the tool (58) and at the other end of which a link (68) is articulated, which forms an angle with the longitudinal direction of the torque wrench and is loaded in this longitudinal direction by a prestressed spring (72). 3. Torque wrench according to claim 1 or 2, characterized in that the outer housing (50) is formed by a square tube. 4. Torque wrench according to claim 3, characterized in that the tool (58) is an insert tool which is inserted at the first end with a shaft into the outer housing (50). 5. Torque wrench according to one of claims 1 to 4, characterized in that 4aB the inner part (54) is formed by a tube which is firmly connected at the second end to the tubular handle part (52). 6. Torque wrench according to one of claims 1 to 5, characterized in that 30 (a) the outer housing (50) is cut off at an angle at the handle end and 35 (D) a lever (62) mounted in the handle part (52) of the knee lever mechanism (82) on the inside of the handle-side protruding wall part (66) of the outer housing (50). 7. Torque wrench according to claim 5, characterized in that (a) a sliding piece (70) is slidably guided in the handle part (52), (b) the handlebar (68) is hinged to the slider (70) at its end facing away from the lever (62) and (c) the slider (70) is loaded by the pre-tensioned spring (72). 8. Torque wrench according to claim 7, characterized in that (a) the sliding piece (70) is a U-shaped sheet metal part, (b) the two sides of the U-shaped sheet metal part are set back longitudinally so that two parallel edges (94) are formed which lie in a plane perpendicular to the longitudinal direction of the torque wrench, (c) a pressure disk (96) rests on the edges, against which in turn the pre-tensioned spring (72) rests. 9. Torque wrench according to claim 8, characterized in that (a) the spring (72) is supported on a nut (74), (b) the nut (74) is guided non-rotatably in the handle part (52), (c) the nut (74) is further guided on a threaded bush (104) whose axial position is fixed to the handle part (52), (d) an adjusting spindle (76) !5 is guided in the threaded bush (104) in a non-rotatable but axially displaceable manner, (e) the adjusting spindle (76) carries an adjusting knob (110) at an end protruding from the handle part (52). 10. Torque wrench according to claim 9, characterized in that the adjusting spindle (76) can be locked in the handle part (52) in a position in which the adjusting spindle is inserted into the handle part (52). 11. Torque wrench according to claim 10, characterized in that (a) a transverse bolt (100) extending transversely to the longitudinal direction of the torque wrench is provided in the handle part (52), (b) the adjusting spindle (76) is guided in a bore (98) of the cross bolt (100) and (c) the threaded bush (104) with its one end face under the influence of the spring (72) on the Cross bolt (100).
5 12. Torque wrench according to claim 11, characterized in that (a) the adjusting spindle (76) has a circumferential groove (102) and (b) in the inserted position of the adjusting spindle (76), a spring-loaded locking ball seated in the cross bolt (100) engages in the circumferential groove (102). 13. Torque wrench according to claim 11 or 12, characterized in that (a) a stop body (108) is attached to the inner end of the adjusting spindle (76), which limits the pulling out of the adjusting spindle (76) by the stop body (108) being on the other, inner end face of the threaded bush (104) comes into play. 14. Torque wrench according to one of claims 9 to 13, characterized in that (a) the adjusting spindle (76) has a hexagonal profile and (b) the threaded bushing (104) has an end piece (106) provided with a hexagon socket, which is guided on the adjusting spindle (76). t · · β « t. 15. torque .Must! according to claim 14,
characterized in that a scale carrier (112) is connected to the nut, which carries a scale which ⁵ can be read through an opening (114) in the handle part (5&iacgr;!). 16. Torque wrench according to one of claims 1 to 1ii, characterized in that (a) the inner part (54) is attached to the handle part (52) by two screws (88,90) which are screwed into a nut block (92) on the inside of the inner part (54), and (b) a handle (116) with openings (118,120) is seated on the handle part (52), whereby the heads of the screws (88,90) protrude into the openings (118,120) and thereby fix the handle (116) in the longitudinal direction 20 secure.