JP2018024053A - Torque control wrench - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a torque control wrench having no leakage of hydraulic fluid causing a failure of the torque control wrench and excellent in durability.SOLUTION: A diaphragm member 11 for blocking distribution of hydraulic fluid is disposed at a position in which a passage 52 of the hydraulic fluid formed on a liner top cover 52 opens, to pick up pressure of the hydraulic fluid through the diaphragm member 11.SELECTED DRAWING: Figure 1

Description

  The present invention detects that the tightening force of the torque control wrench has reached a set value by a relief valve that is released by the hydraulic oil pressure of the hydraulic striking torque generator, and determines the pressure of the hydraulic oil passing through the relief valve. The present invention relates to a torque control wrench that is taken out from a downstream side of a relief valve through a hydraulic oil passage formed in a liner upper lid and operates a motor ON / OFF mechanism by the pressure of the hydraulic oil.

  Torque control wrench shutoff valve that detects when the torque control wrench tightening force has reached the set value and activates a shutoff valve that shuts off the supply of high-pressure air to the air motor. A mechanism is employed (see, for example, Patent Documents 1 and 2).

An example of the shut-off valve mechanism will be described based on the torque control wrench 1 shown in FIGS.
The torque control wrench 1 has a main valve 2 for supplying and stopping high-pressure air and a forward / reverse rotation switching valve 3 for selectively generating a forward / reverse rotation impact torque. The air motor 4 that generates rotational torque is driven by the high-pressure air that is discharged.
A hydraulic striking torque generator 5 that converts the rotational torque of the air motor 4 into striking torque is provided in the front case 6.
The hydraulic striking torque generator 5 includes a liner 50 including a liner main body 51, a liner upper lid 52, and a liner lower lid 53. The liner 50 is filled with hydraulic oil and hermetically sealed. One or a plurality (two in this example) of blade insertion grooves are provided on the main shaft 7 that is coaxially inserted therein. Then, the blades 54 are fitted into the blade insertion grooves, and the blades 54 are urged by the springs 55 so as to be in sliding contact with the inner peripheral surface of the liner main body 51, and one or more are provided on the outer peripheral surface of the main shaft 7. Individual sealing surfaces are formed.
In addition, a plurality of (four in this example) seal surfaces are formed on the inner peripheral surface of the liner body 51, and an output adjustment mechanism 8 for adjusting the magnitude of the impact torque is provided.
Then, by rotating the liner 50 by the air motor 4, a plurality of seal surfaces formed on the inner peripheral surface of the liner main body 51 of the liner 50 and seal surfaces and blades 54 and 54 formed on the outer peripheral surface of the main shaft 7 are formed. When they match, a striking torque is generated on the main shaft 7.

The torque control wrench 1 is configured to shut off the supply of high-pressure air to the air motor 4 by the shut-off valve mechanism 9 when the tightening force reaches a set value.
This shut-off valve mechanism 9 uses a relief valve 83 of the output adjustment mechanism 8 that is opened by the hydraulic oil pressure of the hydraulic striking torque generator 5 to confirm that the tightening force of the torque control wrench 1 has reached the set value. The pressure of the hydraulic oil that is detected and passes through the relief valve 83 is applied to the piston 91 disposed on the liner upper lid 52, and the pilot valve is passed through the rod 92 disposed through the air motor 4 at the back of the piston 91. 93 is operated to operate a shut-off valve 95 that shuts off the supply of high-pressure air to the air motor.

  As shown in detail in FIG. 7, the shut-off valve mechanism 9 has an air port 11a into which high-pressure air supplied to the air motor 4 is introduced at one end side of the shut-off valve 95 and a communication hole 95a at the other end side. The air ports 11c through which high-pressure air is introduced are formed, and a spring 96 that biases the shut-off valve 95 in the opening direction is disposed, and is formed on the other end side of the shut-off valve 95. The air port 11c and the air port 11d on the front side (rod 92 side) of the pilot valve 93 are communicated with each other through the communication hole 13 so that the pressure of the high pressure air is applied to the front surface of the pilot valve 93. The air port 11e on the side (the opposite side of the rod 92) communicates with the outside through the communication hole 13, and further, the air port 11e Has a pilot valve 93 direction of the air port 11d, that is, so as to arrange the spring 94 for urging in a direction to close the pilot valve 93.

As a result, when the tightening force of the torque control wrench 1 reaches a set value, the relief valve 83 of the output adjustment mechanism 8 is opened by the pressure of the hydraulic oil of the hydraulic striking torque generator 5, and the operation passes through the relief valve 83. The oil pressure acts on the piston 91 disposed on the liner upper lid 52, and the pilot valve 93 is operated and opened via the rod 92 disposed through the air motor 4 on the back of the piston 91.
When the pilot valve 93 is opened, the high-pressure air in the air port 11c is discharged to the outside through the communication hole 13, the air port 11d, the air port 11e, and the communication hole 13, and the pressure in the air port 11c decreases. As a result, the shutoff valve 95 moves from the right side position shown in FIGS. 6 to 7 to the left side position, and the air port 11b through which high-pressure air is introduced and the air port 11b communicating with the air motor 4 The supply of high-pressure air to the air motor 4 is stopped, and bolts and the like can be tightened with a predetermined tightening force set in advance.

Japanese Utility Model Publication No. 3-40076 Japanese Patent Laid-Open No. 11-165274

  By the way, in this shut-off valve mechanism 9, the pressure of the hydraulic oil is applied to the piston 91, the pilot valve 93 is operated via the piston 91 and the rod 92, and the shut-off valve 95 is operated. As shown in FIG. 6, the hydraulic oil directly acts on the piston 91.

  In order to prevent the hydraulic oil from flowing into the rod 92 side, an O-ring 91a is provided on the outer periphery of the piston 91 disposed in the cylinder 52b formed in the liner upper lid 52 to seal the hydraulic oil. .

  However, the O-ring 91a provided on the outer peripheral portion of the piston 91 has poor durability, and there is a problem that hydraulic oil leaks to the rod 92 side and causes a failure of the torque control wrench.

  In view of the problem of a torque control wrench that operates a shut-off valve as a motor ON / OFF mechanism by the pressure of the above-described conventional hydraulic oil, the present invention provides a hydraulic fluid that causes a failure of the torque control wrench. The object is to provide a torque control wrench that is leak-proof and has excellent durability.

  In order to achieve the above object, the torque control wrench of the present invention detects that the tightening force of the torque control wrench has reached a set value by a relief valve that is opened by the hydraulic oil pressure of the hydraulic striking torque generator. The pressure of the hydraulic oil passing through the relief valve is taken out from the downstream side of the relief valve through the hydraulic oil passage formed in the liner upper lid, and the ON / OFF mechanism of the motor is operated by the pressure of the hydraulic oil. In the torque control wrench, a diaphragm member for blocking the flow of the hydraulic oil is disposed at a position where the hydraulic oil passage formed in the liner upper lid is opened, and the pressure of the hydraulic oil is taken out through the diaphragm member. It is characterized by that.

  In this case, the ball can be disposed on the back surface of the diaphragm member, and the pressure of the hydraulic oil can be applied to the ball from the diaphragm member to operate the motor ON / OFF mechanism.

  In this torque control wrench, a diaphragm member that blocks the flow of hydraulic oil is disposed at a position where the hydraulic oil passage formed in the liner upper lid is opened, and the pressure of the hydraulic oil is taken out through the diaphragm member. By sealing the hydraulic fluid with the diaphragm member, it is possible to eliminate leakage of hydraulic fluid that causes a failure of the torque control wrench, and at the same time, an O provided on the outer peripheral portion of the piston having poor durability. By omitting the ring, a torque control wrench having excellent durability can be provided.

  Further, a ball is disposed on the back surface of the diaphragm member, and the hydraulic oil pressure is applied to the ball from the diaphragm member to operate the motor ON / OFF mechanism, thereby reducing the hydraulic oil pressure. It can be smoothly transmitted to the ON / OFF mechanism of the motor.

1 shows a first embodiment of a torque control wrench according to the present invention, in which (a) is a front longitudinal sectional view, (b) is a front longitudinal sectional view of an essential part, and (c) is an explanatory view of a diaphragm member. It is sectional drawing which shows the hydraulic type impact torque generator. The output adjustment mechanism is shown, (a) is a front longitudinal sectional view of the entire relief valve shaft, (b) is a front longitudinal sectional view of the relief valve shaft, and (c) is a sectional view taken along the line CC of (b). . The shut-off valve mechanism provided with the detection mechanism is shown, (a) is a front longitudinal sectional view, and (b) is an axial orthogonal sectional view. The 2nd Example of the torque control wrench of this invention is shown, (a) is a front longitudinal cross-sectional view, (b) is a front longitudinal cross-sectional view of the principal part, (c) is explanatory drawing of a diaphragm member. A conventional torque control wrench is shown, (a) is a front longitudinal sectional view, (b) is an AA sectional view of (a), and (c) is an explanatory view of a piston. It is a front longitudinal cross-sectional view which shows the principal part of the same shut-off valve mechanism.

  Hereinafter, embodiments of a torque control wrench of the present invention will be described with reference to the drawings.

1 to 4 show a first embodiment of a torque control wrench of the present invention.
The torque control wrench 1 has a main valve 2 for supplying and stopping high-pressure air and a forward / reverse rotation switching valve 3 for selectively generating a forward / reverse rotation impact torque. The air motor 4 that generates rotational torque is driven by the high-pressure air that is discharged.
A hydraulic striking torque generator 5 that converts the rotational torque of the air motor 4 into striking torque is provided in the front case 6.

The hydraulic striking torque generator 5 includes a liner 50 including a liner main body 51, a liner upper lid 52, and a liner lower lid 53. The liner 50 is filled with hydraulic oil and hermetically sealed. One or a plurality (two in this example) of blade insertion grooves are provided on the main shaft 7 that is coaxially inserted therein.
The blade 54 is inserted into the blade insertion groove, and the blade 54 is urged by a spring 55 so as to be in sliding contact with the inner peripheral surface of the liner main body 51, and one or more ( In this example, two seal surfaces 7a and 7a are formed. In addition, a plurality (four in this example) of seal surfaces 5a, 5a, 5b, and 5b are formed on the inner peripheral surface of the liner body 51, and an output adjustment mechanism 8 that adjusts the magnitude of the impact torque is provided. .
Then, by rotating the liner 50 by the air motor 4, a plurality of seal surfaces 5a, 5a, 5b, 5b formed on the inner peripheral surface of the liner 50 and seal surfaces 7a, 7a formed on the outer peripheral surface of the main shaft 7 and When the blades 54 and 54 are matched, an impact torque is generated in the main shaft 7.

Here, the seal surfaces 7 a and 7 a formed on the outer peripheral surface of the main shaft 7 of the hydraulic impact torque generating device 5 are formed eccentric so that the straight line connecting the seal surfaces 7 a and 7 a does not pass through the center of the main shaft 7. I am doing so.
As a result, the liner 50 of the hydraulic impact torque generator 5 is rotated by operating the main valve 2 and the switching valve 3 to rotate the air motor 4 by supplying high-pressure air to the air motor 4. The seal surfaces 5a, 5a, 5b, 5b formed on the inner peripheral surface of the liner main body 51 of the liner 50 and the seal surfaces 7a, 7a and the blades 54, 54 formed on the outer peripheral surface of the main shaft 7 are matched once per rotation. At this time, the cavity formed in the liner 50 is divided into two high-pressure chambers H and two low-pressure chambers L, and the blades 54 and 54 are pushed to the low-pressure chamber L side. An intermittent impact torque is generated on the main shaft 7 once per rotation.

By the way, the liner main body 51 of the liner 50 is provided with an output adjusting mechanism 8 for adjusting the magnitude of the impact torque.
This output adjustment mechanism 8 includes an output adjustment mechanism inserted between the two chambers divided by the output adjustment mechanism insertion hole 51a formed parallel to the axis of the liner body 51 and the seal surface 7a of the main shaft 7 across the seal surface 5b. Ports P1 and P2 communicating with the hole 51a, and a relief valve shaft 81 inserted into the output adjustment mechanism insertion hole 51a, an adjustment shaft 82, a relief valve 83, and a spring 84 that biases the relief valve 83 in a closing direction. It is made up of.
The relief valve shaft 81 is slid within the output adjustment mechanism insertion hole 51 a by rotating the adjustment shaft 82 screwed with the relief valve shaft 81, and on the outer peripheral surface of the relief valve shaft 81. A passage 81q made of a concave groove that connects the port P1 and the port P2 is formed, and further, a passage 81p that penetrates the relief valve shaft 81 in a direction perpendicular to the shaft and a middle of the passage 81p, and the relief valve shaft 81 is A passage 81r that penetrates in the axial direction and supplies hydraulic oil to the relief valve 83 side of the output adjustment mechanism insertion hole 51a is formed.

When the output adjusting mechanism 8 rotates the liner 50 of the hydraulic striking torque generator 5, a predetermined amount of hydraulic fluid flows from the high pressure chamber H to the low pressure chamber L side through the port P1, the passage 81q, and the port P2. At this time, until the tightening force of the torque control wrench 1 reaches the set value (the pressure of the hydraulic oil in the high pressure chamber H reaches the set pressure), the relief valve 83 is driven by the urging force of the spring 84 to release the relief valve shaft 81. The state where the hydraulic oil passage 81r opened at the end face is closed is maintained.
When the tightening force of the torque control wrench 1 reaches the set value (the pressure of the hydraulic oil in the high pressure chamber H reaches the set pressure), the relief valve 83 is opened, and a part of the hydraulic oil is transferred from the port P1. By passing through the relief valve 83 through the passage 81q and the passage 81r and flowing out through the passage 52a formed in the liner upper lid 52, the pressure of the hydraulic oil is disposed in the cylinder 52b formed in the liner upper lid 52. The piston 91 is configured to act.

  Specifically, as shown in FIG. 1B, the passage member 10 and the diaphragm member 11 are disposed in a cylinder 52b in which a hydraulic oil passage 52a formed in the liner upper lid 52 is opened.

The passage member 10 communicates with the opening of the passage 52a for the hydraulic oil, and has a structure for guiding the hydraulic oil flowing out from the passage 52a to a through hole formed at the center of the passage member 10, and the diaphragm member 11 and the check valve are provided on both sides thereof. 15 are arranged respectively.
In other words, the passage member 10 is disposed on the central axis of the torque control wrench 1, and the passage member 10 is formed of a through hole that opens to the air motor 4 side and the hydraulic impact torque generator 5 side, respectively. An oil passage is formed so that the pressure of the hydraulic oil acts on the piston 91 disposed in the cylinder 52b formed in the liner upper lid 52 via the diaphragm member 11, and between the liner upper lid 52 and the main shaft 7 It is formed so as to communicate with the liner 50 through a gap between the rear portion.

A check valve 15 is provided at the outlet of the hydraulic oil passage on the hydraulic striking torque generator 5 side of the passage member 10 and a spring that biases the check valve 15 in the direction of closing the passage member 10. 16 is disposed in a hole 72 formed in the rear portion 71 of the main shaft 7.
Thus, by arranging the check valve 15 at the outlet of the hydraulic striking torque generator side of the passage member 10, a small amount of hydraulic oil leaking from the relief valve 83 at the time of normal striking torque generation is It is possible to prevent the hydraulic oil from flowing out through the gap between the liner upper lid 52 and the rear portion of the main shaft 7, that is, leakage of the hydraulic oil from the relief valve 83, thereby improving the working efficiency of the tightening operation, A stable tightening force can be obtained.
Further, after the shut-off, the check valve 15 is opened against the urging force of the spring 16 together with the return of the piston 91, and the hydraulic oil in the cylinder 52b is allowed to flow between the liner upper lid 52 and the rear portion of the main shaft 7. It is possible to return to the hydraulic striking torque generator through the gap between the two.
Therefore, the biasing force obtained by adding the biasing force of the spring 94 biasing the pilot valve 93 and the biasing force of the spring 97 biasing the piston 91 is larger than the biasing force of the spring 16 biasing the check valve 15. The biasing force of the spring 16, the spring 94 and the spring 97 is set so as to increase.
The check valve 15 is opened against the biasing force of the spring 16 even when the relief valve 83 is opened and the hydraulic oil pressure is applied to the piston 91, but the liner upper lid 52 and the rear portion of the main shaft 7 are opened. Since the gap between them is narrow, the movement of the piston 91 performed through the diaphragm member 11 is not hindered.

On the other hand, the magnitude of the impact torque is adjusted by rotating the adjusting shaft 82 to slide the relief valve shaft 81 in the output adjusting mechanism insertion hole 51a and being urged by the spring 84. And the opening amount of the passage 81q communicating with the port P1 and the port P2 is adjusted.
In this case, when the relief valve shaft 81 rotates, the direction of the opening of the passage 81p changes, and it becomes difficult to accurately adjust the magnitude of the impact torque. Therefore, as shown in FIG. A long hole 81h is formed in the direction, and a knock pin 57 provided on the liner main body 51 of the liner 50 is fitted into the long hole 81h to prevent rotation.

The relief valve shaft 81 can also be provided in the liner upper lid 52 of the hydraulic striking torque generator 5.
By providing the relief valve shaft 81 in the liner upper lid 52, the outer diameter of the hydraulic impact torque generating device 5 can be reduced, and the liner main body 51, the liner upper lid 52, the liner lower lid 53, and the knock pin 57 constituting the liner 50 are provided. The tolerance of the accuracy can be increased, and the sealing performance between the liner main body 51 and the liner upper lid 52 is not affected by the output adjusting mechanism insertion hole 51a.

Further, by setting the opening amount of the passage 81p communicating with the port P1 and the port P2 to be small, the detection pressure is reduced, the adjustment of the urging force of the relief valve 83 by the spring 84 is facilitated, and the ports P1 and P2 Although the adjustment of the magnitude of the impact torque by adjusting the opening amount of the passage 81q communicating with each other can be made to function more effectively, if the opening amount of the passage 81p is set too small, The detection pressure for operating the shut-off valve mechanism 9 described later becomes too low, or the amount of hydraulic oil flowing into the passage 81r from the passage 81p is insufficient, so that the impact torque can be adjusted accurately. It may disappear.
In order to improve this, as shown in FIG. 3, the passage 81p is not formed as a through-hole, but is formed in an orifice shape having a large diameter on one side and a small diameter on the other side. The relief valve shaft 81 is arranged so that the diameter on the port P1 side is larger than the diameter on the port P2 side on the low pressure chamber L side.
As a result, the amount of oil flowing from the passage 81p into the passage 81r can be secured while the adjustment of the magnitude of the impact torque by adjusting the opening amount of the passage 81q communicating with the port P1 and the port P2 is made more effective. It is possible to accurately adjust the magnitude of the impact torque.

  Further, when adjusting the opening amount of the passage 81q that communicates the port P1 and the port P2, the passage 81p and the passage 81q are provided in order to prevent fluctuations in the pressure of the hydraulic fluid applied to the passage 81p that communicates the port P1 and the port P2. It is desirable to form a separation wall 81 s on the relief valve shaft 81.

  As described above, when the tightening force of the torque control wrench 1 reaches the set value (the pressure of the hydraulic oil in the high pressure chamber H reaches the set pressure), the relief valve 83 is opened, and a part of the hydraulic oil is The oil passes through the relief valve 83 and flows out through the passage 52a formed in the liner upper lid 52. This hydraulic oil is guided to the through hole formed in the center of the passage member 10 and reaches the diaphragm member 11. become.

  The diaphragm member 11 is made of an oil-resistant flexible material such as nitrile rubber (NBR) having a hemispherical diaphragm portion, and the protruding side of the hemispherical diaphragm portion receives the pressure of hydraulic oil. In this manner, the hydraulic oil is fixed in the cylinder 52b, and the flow of the hydraulic oil is blocked at the position of the diaphragm member 11 in the cylinder 52b, and the pressure of the hydraulic oil is transmitted to the back side.

Specifically, as shown in FIG. 1B, a piston 91 is disposed on the back surface of the diaphragm member 11 via a ball 12 having a shape that fits into a hemispherical diaphragm portion of the diaphragm member 11. When the hydraulic oil pressure is applied, the hemispherical diaphragm portion is deformed, specifically, deformed so as to protrude in the opposite direction, and the hydraulic oil pressure is changed from the diaphragm member 11 through the balls 12. The piston 91 is made to act.
As a result, it is possible to eliminate the leakage of the hydraulic oil that causes the failure of the torque control wrench 1, and at the same time, omit the O-ring 91a provided on the outer peripheral portion of the piston 91 having poor durability (and the piston 91 may be omitted, and the rod 92 may be directly operated by the ball 12.) The durability of the torque control wrench 1 can be improved.
In particular, the pressure of the hydraulic oil can be smoothly transmitted by disposing the ball 12 on the back surface of the diaphragm member 11 and causing the pressure of the hydraulic oil to act on the ball 12 from the diaphragm member 11.

  In this way, the pressure of the hydraulic oil acts on the piston 91 disposed in the cylinder 52b formed on the liner upper lid 52, but the air motor 4 is disposed through the back of the piston 91. Since the pilot valve 93 is disposed via the rod 92, when the piston 91 that has received the pressure of the hydraulic oil moves to the right in FIG. 1, the pilot valve 93 is operated via the rod 92. The shut-off valve mechanism 9 serving as the ON / OFF mechanism of the air motor 4 is configured by operating the shut-off valve 17 that shuts off the supply of high-pressure air to the air motor 4.

As shown in FIGS. 1 and 4, the shut-off valve mechanism 9 is formed with air ports 18a and 18b into which high-pressure air is introduced on both sides of a T-shaped shut-off valve 17, respectively. The air port 18a is formed so as to communicate with the air motor 4 through the passage 18c.
A communication hole 19 that communicates with the outside is formed in the rod insertion portion that communicates with the air port 18 a via the pilot valve 93.
The pilot valve 93 and the shut-off valve 17 are elastically supported with each other via a spring 94. The spring 94 biases the pilot valve 93 in a closing direction and opens the shut-off valve 17 in a direction. Energized.

In the shut-off valve mechanism 9, when the tightening force of the torque control wrench 1 reaches a set value (the pressure of the hydraulic oil in the high pressure chamber H reaches the set pressure), the pressure of the hydraulic oil in the hydraulic striking torque generator 5 As a result, the relief valve 83 of the output adjusting mechanism 8 is opened, and the pressure of the hydraulic oil passing through the relief valve 83 acts on the piston 91 disposed on the liner upper lid 52, and the air motor 4 is disposed through the back of the piston 91. The pilot valve 93 is operated against the spring 94 through the provided rod 92 and opened.
When the pilot valve 93 is opened, the air port 18a on the side communicating with the air motor 4 communicates with the outside through the communication hole 19, and the pressure is reduced. Therefore, the shutoff valve 17 is connected to the air port 18b on the opposite side. Is moved to the left in FIG. 1 and FIG. 4A, and the passage 18c leading to the air motor 4 is blocked.
Thereby, the supply of high-pressure air to the air motor 4 is stopped, and the bolts and the like can be tightened with a predetermined tightening force.

  Further, as shown in FIG. 4, the number of actuations of the shut-off valve 17 is detected by detecting the pressure change of the air port 18b in the air port 18b on the back surface of the shut-off valve 17, and the number of tightening times of bolts or the like. Detection mechanism 20 (this detection mechanism 20 is configured such that a pipe line 20c connected to a control device is connected to a detection hole 20a communicating with an air port 18b. A spring 20d is provided in the detection hole 20a. An energized ball valve 20b may be connected to seal high pressure air) so that the tightening operation can be managed automatically.

FIG. 5 shows a second embodiment of the torque control wrench of the present invention.
The torque control wrench 21 has a main switch 22 for supplying and stopping electric power and a forward / reverse rotation changeover switch 23 for selectively generating a forward / reverse rotation impact torque, and is sent from the switches 22, 23. The electric motor 24 that generates rotational torque by electric power is driven.
A hydraulic hitting torque generator 5 that converts the rotational torque of the electric motor 24 into hitting torque is provided in the front case 6.

  The torque control wrench 21 has the other basic configuration similar to that of the torque control wrench 1 of the first embodiment shown in FIGS. 1 to 4, but the first ON / OFF mechanism of the electric motor 24 is the first. Instead of the shut-off valve mechanism 9 of the torque control wrench 1 of the embodiment, an electric switch 25 comprising a limit switch is used, and the electric switch 25 is operated via the rod 92 to cut off the supply of electric power to the electric motor 24. Thus, the electric motor 24 is turned on and off.

  The operation of the torque control wrench 21 of this embodiment is the same as that of the torque control wrench 1 of the first embodiment shown in FIGS. 1 to 4 except that the hydraulic striking torque generator 5 is driven by the electric motor 24. It is the same.

  As mentioned above, although the torque control wrench of the present invention has been described based on a plurality of embodiments, the present invention is not limited to the configurations described in the above embodiments, and the configurations thereof are appropriately set within the scope not departing from the gist thereof. It can be changed.

  The torque control wrench of the present invention has no leakage of hydraulic oil that causes a failure of the torque control wrench and can improve durability, so that the tightening force of the torque control wrench reaches the set value. This is detected by the relief valve released by the hydraulic oil pressure of the hydraulic striking torque generator, and the hydraulic oil passage passing through the relief valve is formed in the liner upper lid from the downstream side of the relief valve. It can be widely used for a torque control wrench which is taken out via the hydraulic oil and the motor ON / OFF mechanism is operated by the pressure of the hydraulic oil.

DESCRIPTION OF SYMBOLS 1 Torque control wrench 2 Main valve 3 Forward / reverse rotation switching valve 4 Air motor 5 Hydraulic impact torque generator 50 Liner 54 Blade 6 Front case 7 Spindle 71 Spindle rear part 72 Hole 8 Output adjustment mechanism 81 Relief valve shaft 82 Adjustment shaft 83 Relief Valve 84 Spring 9 Shut-off valve mechanism (motor ON / OFF mechanism)
91 Piston 92 Rod 93 Pilot valve 94 Spring 10 Passage member 11 Diaphragm member 12 Ball 15 Check valve 16 Spring 17 Shut-off valve 18a, 18b Air port 18c Passage 19 Communication hole 21 Torque control wrench 22 Main switch 23 Forward / reverse rotation switch 24 Electric motor 25 Electric switch (motor ON / OFF mechanism)

Claims (2)

  The fact that the tightening force of the torque control wrench has reached the set value is detected by the relief valve released by the hydraulic oil pressure of the hydraulic striking torque generator, and the pressure of the hydraulic oil passing through the relief valve is detected by the relief valve. In the torque control wrench which is taken out from the downstream side through the hydraulic oil passage formed in the liner upper lid and operates the motor ON / OFF mechanism by the pressure of the hydraulic oil, the hydraulic oil formed in the liner upper lid A torque control wrench characterized in that a diaphragm member for blocking the flow of hydraulic oil is arranged at a position where the passage opens, and the pressure of the hydraulic oil is taken out through the diaphragm member.   The ball is disposed on the back surface of the diaphragm member, and the ON / OFF mechanism of the motor is operated by operating the pressure of hydraulic oil on the ball from the diaphragm member. Torque control wrench.

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