JP2006078358A - Bend tester - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bend tester dispensing with a holder for maintaining an inter-fulcrum distance of a bending tool or a motor with high holding torque, and having an inter-fulcrum distance adjustment mechanism to simply limit backlash and maintain the inter-fulcrum distance thereby suppressing an influence on measurement data. <P>SOLUTION: This bend tester comprises a dual lead worm 13 provided with its attachment position axially adjustable, worm wheels 11 and 12 provided on both sides of the lead worm 13, drive screws 14 and 15 firmly installed on the center axes of the worm wheels 11 and 12, and support bodies 1 and 2 displaced by the drive screws 14 and 15. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a bending test apparatus having a fulcrum distance adjusting mechanism for adjusting a distance between fulcrums of a pair of bending jigs.

  When performing a bending test with this type of bending test apparatus, it is one of the important requirements to adjust the distance between the supporting points of the bending jig and maintain the distance. In particular, in a bending test apparatus that performs a bending test automatically, it is necessary to adjust and maintain the distance between fulcrums in accordance with the type of test piece and the test conditions during a continuous test.

  Conventionally, as a mechanism for adjusting the distance between fulcrums, as shown in FIGS. 5 and 6, two same-direction ball screws 33, 34, spur gears 31, 32 provided at one end of the ball screws 33, 34, A fulcrum distance adjusting mechanism including a motor 30 that drives ball screws 33 and 34 via gears 31 and 32 is known. This inter-fulcrum distance adjusting mechanism has ball screws 33 and 34 screwed to moving nuts 4 and 5 integrally provided on supports 1 and 2 which are bending jigs, and the rotation of the motor 30 is spur geared. 31 is transmitted to the spur gear 32, and the spur gear 31 and the spur gear 32 are rotated in opposite directions, and the distance between the fulcrums of the supports 1 and 2 is adjusted by rotating the motor 30 forward and backward. Like to do.

  Further, as shown in FIGS. 7 and 8, a motor 30 is provided on one ball screw 35 having screw portions 36, 37 in different directions, and a moving nut 4, which is provided integrally with the supports 1, 2. 5 is screwed into the screw portions 36 and 37 in different directions, and the distance between the fulcrums is adjusted by rotating the ball screw 35 forward and backward by the motor 30 to adjust the distance between the fulcrums of the supports 1 and 2. Are known.

  However, in the structure using a spur gear as shown in FIGS. 5 and 6, not only the distance between the fulcrums of the supports 1 and 2 becomes unstable due to the backlash of the gear, but it becomes difficult to adjust the distance between the fulcrums. When the bending force is applied to the test piece S with the indenter 3, each fulcrum of the supports 1 and 2 receives a force in the direction in which it is widened. There was a problem of causing trouble. Therefore, a fulcrum distance adjustment mechanism that can limit backlash as much as possible is desired.

  7 and 8, even if the spur gear is not used, each fulcrum of the supports 1 and 2 is subjected to a force in a direction in which the fulcrum is expanded by the bending load. Receives rotational force in the direction of rotation Therefore, in order to keep the distance between the fulcrums constant, it is necessary to add a holding device or use a motor with a large holding torque, and the structure of the fulcrum distance adjusting mechanism becomes complicated and the cost is increased. was there.

  Therefore, the present invention does not require a holding device for maintaining the distance between the fulcrums of the bending jig or a motor having a large holding torque, and can easily limit the backlash and maintain the distance between the fulcrums. It is an object of the present invention to provide a bending test apparatus having a fulcrum distance adjusting mechanism capable of suppressing influence on data.

  In order to solve the above-mentioned problems, the present invention is a bending test apparatus having a fulcrum distance adjusting mechanism for adjusting the distance between fulcrums of a pair of bending jigs, wherein a mounting position is adjustable in the axial direction. Distance adjustment between fulcrums consisting of a lead worm, worm wheels provided on both sides of the multiple lead worm, a drive screw fixed to the central axis of these worm wheels, and a bending jig displaced by these drive screws A bending test apparatus having a mechanism is provided.

  According to the present invention, a rotating shaft is inserted through the multi-lead worm, and a non-rotating mechanism is provided between the multi-lead worm and the rotating shaft so as to be movable in the axial direction. The multi-lead worm is sandwiched and fixed. The bending test apparatus according to claim 1, wherein a pair of nuts is provided on the rotating shaft.

  The present invention also provides a bending test apparatus according to claim 1 or 2, wherein a motor for driving the multi-lead worm is provided.

  The bending test apparatus according to the present invention is a bending test apparatus having a fulcrum distance adjusting mechanism for adjusting the distance between fulcrums of a pair of bending jigs, wherein the multiple leads are provided so that the mounting position can be adjusted in the axial direction. A fulcrum distance adjusting mechanism comprising a worm, a worm wheel provided on both sides of the multi-lead worm, a drive screw fixed to the central axis of these worm wheels, and a bending jig displaced by these drive screws Because of the irreversible characteristics of the worm gear that transmits rotation only from the worm to the worm wheel, a holding device for maintaining the distance between the fulcrums of the bending jig and a large capacity motor with holding force are not required. Since the backlash can be easily limited by adjusting the mounting position of the multiple lead worm, the distance between the supporting points of the bending jig is maintained. Not only it is possible to suppress the influence of the over data, the effect of the adjustment of the distance between fulcrums of bending jig becomes easy.

  According to the present invention, a rotating shaft is inserted through the multi-lead worm, and a non-rotating mechanism is provided between the multi-lead worm and the rotating shaft so as to be movable in the axial direction. The multi-lead worm is sandwiched and fixed. By having the configuration according to claim 1, wherein the pair of nuts are provided on the rotating shaft, the multiple lead worms move along the axial direction of the rotating shaft by loosening or tightening the pair of nuts, There is an effect that the mounting position can be easily adjusted.

  In addition, the present invention has the configuration according to claim 1 or 2 provided with a motor for driving the multi-lead worm, whereby the distance between the supporting points of the bending jig can be automatically adjusted by the motor. is there.

Embodiments of the present invention will be described based on examples shown in the drawings.
The bending test apparatus according to the present invention includes a support 1, 2 and an indenter 3 that are a pair of bending jigs, and includes a fulcrum distance adjusting mechanism 10 that adjusts a distance between fulcrums of the supports 1, 2. Yes. This fulcrum distance adjusting mechanism 10 includes a multi-lead worm 13 provided so that its mounting position can be adjusted in the axial direction, worm wheels 11, 12 provided on both sides of the multi-lead worm 13, and these worm wheels 11, 12. Drive screws 14 and 15 fixed to the central axis of the motor, and supports 1 and 2 displaced by the drive screws 14 and 15.

  As shown in FIGS. 1 and 2, the supports 1 and 2 are provided facing the rail 6. Further, a moving nut 4 is fixed to the support 1, and a driving screw 14 is screwed onto the moving nut 4, and the driving screw 14 is rotated forward and reverse so that the supporting body 1 is attached to the rail 6. It can be moved along. Similarly, a moving nut 5 is fixed to the support 2, and a driving screw 15 is screwed to the moving nut 5, and the driving screw 15 is rotated forward and reverse to attach the supporting body 2 to the rail 6. It can be moved along.

  The drive screws 14 and 15 are ball screws having the same pitch and the same direction. As shown in FIGS. 1 and 2, the drive screw 14 is rotatably provided by a bearing 22, and a worm wheel 11 is fixed at one end and is driven by a multi-lead worm 13. Similarly, the drive screw 15 is rotatably provided by a bearing 23, and has a worm wheel 12 fixed at one end and is driven by a multi-lead worm 13.

  As shown in FIG. 4, the worm wheel 11 and the worm wheel 12 have the same shape and the same number of teeth, and are provided in front of and behind the multiple lead worm 13 at positions symmetrical to the worm axis. Since the worm wheel 11 and the worm wheel 12 provided on both sides of the multi-lead worm 13 rotate in opposite directions, the support body 1 and the support body 2 are moved in the opposite directions by the drive screws 14 and 15 in the same direction at the same pitch. Displace by the same distance. Therefore, the support 1 and the support 2 can adjust the fulcrum distance with the indenter 3 as the center.

In the embodiment shown in FIGS. 1 to 4, the multi-lead worm 13 is a cylindrical worm having a lead and advance angle of the upper tooth surface 21b of the worm tooth portion 21a and a lead and advance angle of the lower tooth surface 21c. The tooth thickness is formed with a difference, and the tooth thickness is continuously changed by the lead difference. As shown in FIG. 4, the multi-lead worm 13 is provided with worm teeth 21a at a constant pitch P, and the width of the tooth groove 21d increases as the tooth thickness decreases as it goes downward (m ₁ > m ₂ ). As a result, when the multi-lead worm 13 is moved downward relative to the worm wheels 11 and 12, the width of the tooth groove 21d of the meshing portion is reduced, so that the backlash is reduced. Since the width of the groove 21d becomes wide, the backlash increases.

  As shown in FIG. 3, a rotating shaft 16 is inserted into the multi-lead worm 13, and a detent mechanism that can move in the axial direction is provided between the multi-lead worm 13 and the rotating shaft 16. In the illustrated embodiment, the detent mechanism includes a key groove 20 provided in the axial direction on the inner periphery of the multi-lead worm 13 and a key 19 provided in the axial direction on the outer periphery of the rotary shaft 16. The groove 20 can transmit the rotational force of the rotary shaft to the multi-lead worm 13, and the multi-lead worm 13 can move along the axial direction of the rotary shaft 16.

  The rotating shaft 16 is provided with screw parts 16a and 16b on the upper and lower sides, and a pair of nuts 17 and 18 for fixing the multi-lead worm 13 by being screwed to the screw parts 16a and 16b. is there. When the lower nut 18 is loosened and the upper nut 17 is tightened, the multi-lead worm 13 moves downward along the rotary shaft 13 and the backlash between the worm wheels 11 and 12 can be reduced. On the other hand, when the upper nut 18 is loosened and the lower nut 17 is tightened, the multi-lead worm 13 moves upward along the rotary shaft 13 and the backlash between the worm wheels 11 and 12 can be increased. Thus, the backlash can be easily adjusted without moving the worm wheels 11 and 12.

  The rotary shaft 16 is rotatably provided by a bearing 21 and is provided with a motor 23 at one end. The distance between the fulcrums of the supports 1 and 2 can be automatically adjusted by rotating the double lead worm 13 provided on the rotating shaft 16 by the motor 23 in the forward and reverse directions. The distance between fulcrums can be adjusted according to the type and test conditions.

The perspective view which shows the principal part of one Example of the bending test apparatus which concerns on this invention. The top view which shows the principal part of the one Example. The partial longitudinal cross-sectional front view which shows the principal part of the one Example. The right view which shows the principal part of the one Example. The front view which shows an example of the conventional fulcrum distance adjustment mechanism. The right view which shows an example of the conventional fulcrum distance adjustment mechanism. The front view which shows the other example of the conventional fulcrum distance adjustment mechanism. The right view which shows the other example of the conventional fulcrum distance adjustment mechanism.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 2 Support body 3 Indenter 4, 5 Moving nut 6 Rail 10 Support distance adjustment mechanism 11, 12 Worm wheel 13 Double lead worm 14, 15 Drive screw 16 Rotating shaft 16a, 16b Screw part 17, 18 Nut 19 Key 20 Key Groove 21, 22, 23 Bearing 24 Motor 30 Motor 31, 32 Spur gears 33, 34, 35 Ball screw 36, 37 Threaded part

Claims (3)

  A bending test apparatus having a fulcrum distance adjusting mechanism that adjusts a distance between fulcrums of a pair of bending jigs, and is provided on both sides of the multi-lead worm, the mounting position being adjustable in the axial direction. A bending test apparatus having a fulcrum distance adjusting mechanism comprising a worm wheel, a drive screw fixed to the central axis of the worm wheel, and a bending jig displaced by the drive screw.   A rotary shaft is inserted through the multi-lead worm, a rotation preventing mechanism is provided between the multi-lead worm and the rotary shaft, and a pair of nuts that clamp and fix the multi-lead worm are provided. The bending test apparatus according to claim 1 provided on a rotating shaft. The bending test apparatus according to claim 1, wherein a motor for driving the multi-lead worm is provided.

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