Bendable torque wrench

Abstract

A bendable torque wrench includes: a shank; a tubular body whose front end is angularly displaceable with respect to the shank about an axis defined by a first pivotal connection end of the shank; an abutting block located on one side of the tubular body, a the front end of the abutting block has a convexly curved abutting surface; and a detent member whose front end is pivotally connected to a second pivotal connection end of the shank and whose rear end forms a convexly curved contact surface in elastic contact with the curved abutting surface of the abutting block. The torque wrench bends, or collapses, rapidly when the torque applied to the torque wrench reaches a preset torque value.

Claims

1. A bendable torque wrench, comprising: a shank, a driving head provided at a front end of the shank; a first pivotal connection end and a second pivotal connection end both provided at a rear end of the shank, the first pivotal connection end and the second pivotal connection end are spaced apart; a tubular body provided at a rear side of the shank, a front end of the tubular body angularly displaceable with respect to the shank about an axis defined by the first pivotal connection end of the shank; an abutting block provided on one side of the tubular body, the abutting block has a front end provided with a convexly curved abutting surface; an elastic element disposed in the tubular body; and a detent member having a front end pivotally connected to the second pivotal connection end of the shank such that the detent member is angularly displaceable about an axis defined by the second pivotal connection end, the detent member having a rear end provided with a convexly curved contact surface in contact with the convexly curved abutting surface of the abutting block; the abutting block and the detent member are brought into elastic contact with each other by an elastic force of the elastic element; the detent member is angularly displaceable with respect to the abutting block, and the shank and the tubular body are bendable with respect to each other; wherein the convexly curved contact surface is a curved surface extending in an opposite direction from a curved surface of the convexly curved abutting surface.

2. The bendable torque wrench of claim 1, wherein the curved surfaces of the convexly curved contact surface and the convexly curved abutting surface having a same curvature or having different curvatures.

3. The bendable torque wrench of claim 1, wherein the torque wrench has a preset torque value, and the preset torque value is reached when an apex of the curved contact surface contacts an apex of the curved abutting surface.

4. The bendable torque wrench of claim 1, wherein the detent member has a positioning groove; a position limiting member extends into the positioning groove of the detent member, and the detent member is limited in position by the position limiting member when rotated.

5. The bendable torque wrench of claim 4, wherein the positioning groove of the detent member has a first end, a second end, and a transition between the first end and the second end, and the position limiting member is at the transition when the convexly curved contact surface of the detent member is at an apex of the convexly curved abutting surface of the abutting block.

6. The bendable torque wrench of claim 1, further comprising a stop block located on one side of the convexly curved abutting surface and adjacent to the tubular body, in order for the detent member to be stopped at a lateral side of the stop block when the detent member is rotated.

7. The bendable torque wrench of claim 6, wherein the stop block is protrudingly provided on one side of the abutting block.

8. The bendable torque wrench of claim 1, wherein the detent member has two sides defined respectively as a first side and a second side, the first side is adjacent to the tubular body, the second side is away from the tubular body; the convexly curved contact surface of the detent member and the convexly curved abutting surface of the abutting block contact each other at an initial contact point when no force is applied to the torque wrench, and the farther the distance between the initial contact point and the second side of the detent member, the bigger the bending angle of the torque wrench.

9. The bendable torque wrench of claim 1, wherein the curved surface of the convexly curved abutting surface of the abutting block is a curved surface that has a single or non-single curvature or is a curved surface with continuous or non-continuous curvatures.

10. The bendable torque wrench of claim 1, wherein the curved surface of the convexly curved contact surface of the detent member is a curved surface that has a single or non-single curvature or is a curved surface with continuous or non-continuous curvatures.

11. The bendable torque wrench of claim 1, further comprising: a connecting member having a front end pivotally connected to the first pivotal connection end of the shank, the connecting member having a rear end extending into the tubular body; and an adjusting member threadedly connected to the rear end of the connecting member; the elastic element has one end abutting against the tubular body and an opposite end abutting against the adjusting member.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

(1) The objectives, technical features, and effects of the present invention can be better understood by referring to the following detailed description of a preferred embodiment in conjunction with the accompanying drawings, in which:

(2) FIG. 1 is a perspective view of a conventional bendable torque wrench;

(3) FIG. 2 is a sectional view of the conventional bendable torque wrench in FIG. 1;

(4) FIG. 3 is an exploded perspective view of the bendable torque wrench according to a preferred embodiment of the invention;

(5) FIG. 4 is an assembled sectional view of the bendable torque wrench in FIG. 3;

(6) FIG. 5 is a partial enlarged view of FIG. 4, showing the positions of the detent member and the abutting lock before a force is applied to the torque wrench;

(7) FIG. 6 is similar to FIG. 5 except that the torque wrench has bent;

(8) FIG. 7 is similar to FIG. 6 except that the torque wrench has reached the bending endpoint;

(9) FIG. 8A shows a curve representing the relationship between the torque and the bending angle of the conventional bendable torque wrench in FIG. 1;

(10) FIG. 8B shows a curve representing the relationship between the torque and the bending angle of the bendable torque wrench in FIG. 3;

(11) FIG. 9A is a sectional view in which the detent member and the abutting block of the invention use point A as their initial contact point; and

(12) FIG. 9B is a sectional view in which the detent member and the abutting block of the invention use point B as their initial contact point.

DETAILED DESCRIPTION OF THE INVENTION

(13) Please refer to FIG. 3 and FIG. 4 for the bendable torque wrench 30 according to a preferred embodiment of the present invention. The bendable torque wrench 30 includes a shank 40, a connecting member 50, a housing, a torque adjustment mechanism 80, and a detent member 90.

(14) The shank 40 is provided with a driving head 41 at the front end and can be used to rotate a threaded fastener (e.g., a nut or a bolt) through the driving head 41. The configuration of the driving head may vary as needed. A first pivotal connection end 42 and a second pivotal connection end 43 are provided at the rear end of the shank 40. A diverging member 44 is provided between the first pivotal connection end 42 and the second pivotal connection end 43 to keep a proper distance between the two pivotal connection ends.

(15) The connecting member 50 is pivotally connected at the front end to the first pivotal connection end 42 of the shank 40 and can therefore be angularly displaced with respect to the shank 40 about an axis defined by the first pivotal connection end 40. The rear end of the connecting member 50 is a threaded slender portion 52.

(16) The housing includes a tubular body 60 and a casing 70 fixedly provided on one side of the tubular body 60. The tubular body 60 is fixedly provided therein with a fixed block 61. The connecting member 50 is inserted into the tubular body 60, extends through the fixed block 61, and can be moved along the axial direction of the tubular body 60. The slender portion 52 of the connecting member 50 is inserted into the tubular body 60 too. The casing 70 defines a receiving space 71 therein. An abutting block 72 and a position limiting member 73 are fixedly provided in the receiving space 71. The abutting block 72 is provided with a convexly curved abutting surface 721 at the front end. The curved abutting surface 721 is formed by a curved surface, which may have a single curvature or multiple continuous curvatures; alternatively, the curved abutting surface is a curved surface with non-single curvature or multiple non-continuous curvatures. One side of the abutting block 72 is integrally formed with a stop block 722. The stop block 722 is protrudingly provided on one side of the curved abutting surface 721 and is adjacent to the tubular body 60.

(17) The torque adjustment mechanism 80 has an elastic element 81 and an adjusting member 82. The front end of the adjusting member 82 is threadedly connected to the thread of the slender portion 52 at the rear end of the connecting member 50. The elastic element 81 is disposed in the tubular body 60, with its two (i.e., front and rear) ends abutting against the fixed block 61 and the adjusting member 82 respectively.

(18) The detent member 90 is received in the receiving space 71 of the casing 70. The detent member 90 is pivotally connected at the front end to the second pivotal connection end 43 of the shank 40 by a pivot shaft 91 and can therefore be angularly displaced in the casing 70 about an axis defined by the second pivotal connection end 43. The detent member 90 is provided with a positioning groove 92. The positioning groove 92 forma a first end 921, a second end 922, and a transition 923 between the first end 921 and the second end 922. When angularly displaced, the detent member 90 is limited in position by the position limiting member 73. The rear end of the detent member 90 is formed with a convexly curved contact surface 93. The curved contact surface 93 abuts against the curved abutting surface 721 of the abutting block 72. The elastic force of the elastic element 81 is substantially applied to the abutting block 72 through the tubular body 60 such that the abutting block 72 and the detent member 90 remain in elastic contact. The curved contact surface 93 is a curved surface, which in practice may have a single curvature or multiple continuous curvatures; alternatively, the curved contact surface is a curved surface with non-single curvature or multiple non-continuous curvatures. The curvature(s) of the curved contact surface 93 may be the same as or different from the curvature(s) of the curved abutting surface 721.

(19) FIG. 5 to FIG. 7 and FIG. 8B show how the bending angle and the torque of the bendable torque wrench 30 are changed while the torque wrench is in operation.

(20) Referring to FIG. 4 and FIG. 5, a force F is applied to the torque wrench 30 in order to tighten a threaded fastener with the driving head 41 of the shank 40. Before the force applied reaches the preset torque value, the connecting member 50 is received in the tubular body 60 while subjected to the elastic force of the elastic element 81, and the shank 40 and the tubular body 60 are not bent with respect to each other. The detent member 90 in this state is at an initial angular position, where the position limiting member 73 is at the first end 921 of the positioning groove 92 of the detent member 90.

(21) When the force F reaches the preset torque value, referring to FIG. 6, the force F is large enough to overcome the elastic force of the elastic element 81 of the torque adjustment mechanism 80 and thus drives the fixed block 61 in the tubular body 60 to compress the elastic element 81 while the tubular body 60 and the casing 70 are displaced rearward. Consequently, the front end of the connecting member 50 is moved out of the tubular body 60, and the tubular body 60 is bent with respect to the shank 40, i.e., angularly displaced. Due to the relative bending (or angular displacement) of the tubular body 60, the detent member 90 is pivoted clockwise about the axis defined by the second pivotal connection end 43 (with reference to the direction shown in FIG. 6) such that not only is the position limiting member 73 moved from the first end 921 to the transition 923 of the positioning groove 92 of the detent member 90, but also the detent member 90 is brought closer to the tubular body 60. When the preset torque value is reached, the apex (i.e., the highest point) of the curved abutting surface 721 is in contact with the apex (i.e., the highest point) of the curved contact surface 93.

(22) When application of the force F continues, so does the relative bending of the tubular body 60. The tubular body 60 and the casing 70 keep moving away from the shank 40, and the detent member 90 keeps rotating clockwise, with the position limiting member 73 moving toward the second end 922 of the positioning groove 92. While the detent member 90 is rotating, the contact between its convexly curved contact surface 93 and the convexly curved abutting surface 721 of the abutting block 72 leads to a high rotation speed of the detent member 90; as a result, the tubular body 60 is angularly displaced (or relatively bent) faster than its prior art counterparts, and the position limiting member 73 reaches the second end 922 more rapidly than its prior counterparts too. Eventually, as shown in FIG. 7, the detent member 90 is rotated to a displacement endpoint, and the tubular body 60 arrives at an angular displacement endpoint, i.e., the point at which the tubular body 60 of the wrench 30 cannot be bent, or collapsed, with respect to the shank 40 any further.

(23) In the course in which the detent member 90 is rotated from the position in FIG. 6 to that in FIG. 7, the position of contact between the curved contact surface 93 and the curved abutting surface 721 of the abutting block 72 approaches the tubular body 60, and the fact that the curved abutting surface 721 is lowering at the same time causes the detent member 90 to rotate (or angularly displaced) rapidly, the shank 40 to bend with respect to the tubular body 60 rapidly, and the torque of the torque wrench 30 to vanish rapidly as a result. The cooperation between the curved abutting surface 721 and the curved contact surface 92 helps increase the rotation speed of the detent member 90 and hence the speed at which the tubular body 60 is bent with respect to the shank 40 after the preset torque value is exceeded. Now that the wrench 30 bends, or collapses, swiftly, the force applied by the wrench 30 vanishes rapidly, i.e., with little, if any, residual torque transmitted to the threaded fastener after the torque setting is reached, and this prevents torques larger than the setting from being applied to the threaded fastener. The rapid bending of the wrench can also be felt immediately by the user, allowing the user to know that the force applied by the wrench has reached the torque setting.

(24) Moreover, this embodiment is so designed that, referring to FIG. 7, the detent member 90 arrives at one side of, and is stopped by, the stop block 722 of the abutting block 72 when reaching its angular displacement endpoint. This is the second mechanism by which to prevent the detent member 90 from further rotation (the first being the position limiting member 73), the objective being to stop the detent member 90 and the shank 40 from rotating as soon as they reach their respective angular displacement endpoints. The stop block 722 not only keeps the diverging member 44 from contact with the tubular body 60 when the wrench is bent, thus protecting the tubular body 60 from damage by colliding with the diverging member 44, but also allows the shank 40 to be bent with respect to the tubular body 60 through a relatively small angle enabled by the fact that the stop block 722 projects from the exterior of the tubular body 60 and can therefore be rapidly brought into contact with the detent member 90.

(25) Referring to FIG. 8B, the foregoing structure of the bendable torque wrench 30 of the present invention allows the tubular body 60 to bend, or collapse, with respect to the shank 40 in a noticeable manner when the torque setting (i.e., the preset maximum torque value) is reached. In addition to producing a collapsed state that can be readily felt by the user, the bending, or collapse, taking place when the torque applied to the threaded fastener reaches the torque setting converts the force applied by the user into a wrench bending/collapsing force such that the force applied to the threaded fastener is rapidly reduced. The threaded fastener, therefore, is protected from torques larger than the torque setting.

(26) Furthermore, referring to FIG. 9A and FIG. 9B, the initial contact point between the detent member 90 and the abutting block 72 (which point is set when the detent member 90 is mounted with respect to the abutting block 72) will affect the bending, or collapsing, angle of the tubular body 60 with respect to the shank 40. To facilitate explanation, the detent member 90 is defined as having a first side 901 and a second side 902, wherein the first side 901 is adjacent to the tubular body 60 while the second side 902 is away from the tubular body 60. In FIG. 9A, the point of contact between the curved contact surface 93 of the detent member 90 and the curved abutting surface 721 of the abutting block 72 when no force is applied to the wrench, i.e., the initial contact point, is point A, and the distance between point A and the second side 902 is d1. In FIG. 9B, the initial contact point between the curved contact surface 93 of the detent member 90 and the curved abutting surface 721 of the abutting block 72 is point B, and the distance between point B and the second side 902 is d2, wherein d2 is greater than d1. When the torque wrench bends, or collapses, due to an operating force that exceeds the torque setting, the detent member 90 in FIG. 9A will be brought into abutment against, and thus stopped by, the stop block 722 more rapidly than the detent member 90 in FIG. 9B such that the bending angle of the wrench in FIG. 9A is smaller than that of the wrench in FIG. 9B. The initial contact point B in FIG. 9B requires a longer time to be taken to bring the detent member 90 into abutment against the stop block 722 than the initial contact point A in FIG. 9A, so the bending angle of the wrench in FIG. 9B is larger than that of the wrench in FIG. 9A.

(27) Referring to FIG. 8A, as the abutting block of the conventional bendable torque wrench in FIG. 1 and FIG. 2 has a flat surface for contact with the detent member, the detent member rotates relatively slow when the torque setting is reached; it follows that the wrench bends relatively slow, that the torque of the wrench vanishes relatively slow, and that the threaded fastener to which the wrench is applied will be subjected to the slowly reduced residual torque. The bendable torque wrench of the present invention, however, allows the detent member 90 to rotate faster than its prior art counterpart because of the contact between the curved abutting surface 721 of the abutting block 72 and the curved contact surface 93 of the detent member 90. Hence, once the force applied by the wrench of the invention reaches the torque setting, the wrench bends, or collapses, relatively fast as shown in FIG. 8B, and the torque of the wrench vanishes relatively fast as a result, lest the threaded fastener to which the wrench is applied be subjected to a slowly reduced residual torque. The wrench of the invention can bend, or collapse, rapidly and thereby allow its user to know immediately and clearly that the wrench has reached the preset torque value and that force application to the wrench should be stopped.