CN217966177U - Torque type monitoring knife handle - Google Patents

Abstract

The utility model discloses a moment of torsion formula monitoring handle of a knife, include: handle of a knife body, moment of torsion detection subassembly and cutter fixed subassembly. The tool handle comprises a tool handle body, a tool fixing component and a torque detection component, wherein the tool handle body is fixedly connected with the tool fixing component, the torque detection component is arranged in the tool handle body and is used for detecting the torque of the tool, outputting a corresponding torque signal and sending the torque signal to an external receiving terminal so as to judge the wear state of the tool according to the torque signal through the receiving terminal. This application is through setting up the moment of torsion determine module on the cutter body to obtain the torque signal in the cutter course of working through the moment of torsion determine module, receiving terminal judges the wearing and tearing state of cutter according to the torque signal, thereby realizes the monitoring to the cutter. Compare in current processing cutter monitoring mode, the moment of torsion formula monitoring handle of a knife of this application monitors through the moment of torsion mode that acquires the cutter, can be suitable for with the cutter of different diameter sizes.

Description

Torque type monitoring knife handle

Technical Field

The utility model relates to a machine tooling monitoring technology field especially relates to a moment of torsion formula monitoring handle of a knife.

Background

Most machine tool tools monitoring methods at present collect current signals of a machine tool spindle in a machining process, and compare the current signals with a set tipping threshold and a set breakage threshold of a machining tool; during cutting, when the set threshold is reached, a warning signal is sent out. However, when a small-diameter machining tool is used, the current signal of the machine tool spindle cannot be changed significantly when the machining tool is in an abnormal state such as wear, and therefore, the current machining tool monitoring method cannot be applied to a small-diameter machining tool.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that: the utility model provides a moment of torsion formula detects handle of a knife to solve the unable problem that is suitable for the processing cutter of monitoring minor diameter of present processing cutter monitoring mode.

In order to solve the technical problem, the utility model discloses a technical scheme be:

a torque-type monitoring tool shank, comprising: the tool holder comprises a tool holder body, a torque detection assembly and a tool fixing assembly;

the tool handle comprises a tool handle body, a tool fixing component and a torque detection component, wherein the tool handle body is fixedly connected with the tool fixing component, the torque detection component is arranged in the tool handle body and is used for detecting the torque of the tool, outputting a corresponding torque signal and sending the torque signal to an external receiving terminal so as to judge the wear state of the tool according to the torque signal through the receiving terminal.

Further, the handle body includes:

the upper split body is used for connecting a main shaft of the machine tool, and an end cover is arranged at the bottom of the upper split body;

the torque force measuring carrier is of a cylinder-like structure, and a first accommodating cavity for accommodating part of the torque detection assembly is arranged in the torque force measuring carrier;

the pre-tightening block is eccentrically arranged with the axis of the outer circumference of the torque force measuring carrier and is positioned in the first containing cavity, and the pre-tightening block is fixedly connected with the end cover of the upper split body and the torque force measuring carrier respectively;

the lower split body is provided with a second containing cavity for containing the rest part of the torque detection assembly, the second containing cavity is communicated with the first containing cavity, the top of the lower split body is fixedly connected with the torque force measurement carrier, and the bottom of the lower split body is fixedly connected with the cutter fixing assembly;

the torque detection assembly comprises a piezoelectric sensor accommodated in the first accommodating cavity, the piezoelectric sensor and the axis of the outer circumference of the torque force measurement carrier are eccentrically arranged, the detection surface of the piezoelectric sensor is abutted to the pre-tightening block, the pre-tightening block is used for applying positive pressure to the piezoelectric sensor when the upper split body rotates, and the sensor is used for responding to the positive pressure and outputting a corresponding torque signal.

Further, the torque detection assembly further includes:

the battery is accommodated in the first accommodating cavity; and

the circuit board is respectively electrically connected with the battery and the piezoelectric sensor and used for receiving the torque signal and sending the torque signal to an external receiving terminal, and the circuit board is contained in the second containing cavity of the lower split body.

Furthermore, the pre-tightening block is provided with a first threaded hole in the vertical direction, and the end cover is provided with a T-shaped sliding groove corresponding to the first threaded hole;

and the T-shaped sliding groove is provided with a first screw in a penetrating way and is fixedly matched with the first threaded hole.

Furthermore, piezoelectric sensor is provided with the hole of dodging on the normal direction of detection face, the piece of pretension corresponds the hole of dodging is provided with the second screw hole, the moment of torsion dynamometry carrier corresponds the second screw hole is provided with the counter bore, the moment of torsion dynamometry carrier is provided with the second screw, the second screw is worn to locate in proper order the counter bore and dodge the hole, and with second screw hole fixed fit.

Furthermore, the number of the piezoelectric sensors is two, and the two piezoelectric sensors comprise a first piezoelectric sensor and a second piezoelectric sensor, wherein the first piezoelectric sensor and the second piezoelectric sensor are arranged at an angle of 180 degrees with the axis of the outer circumference of the torque force measuring carrier as the center;

the two pre-tightening blocks comprise a first pre-tightening block and a second pre-tightening block, the first pre-tightening block and the second pre-tightening block are arranged at a distance of 180 degrees by taking the axis of the outer circumference of the torque force measuring carrier as a center, the first pre-tightening block is abutted against the detection surface of the first piezoelectric sensor, and the second pre-tightening block is abutted against the detection surface of the second piezoelectric sensor.

Furthermore, the circuit board is an annular circuit board, and the battery is arranged at the center of the torque force measuring carrier and partially suspended in the second cavity.

Furthermore, the circuit board is provided with a wireless module, and the wireless module is in communication connection with an external receiving terminal and is used for sending the torque signal to the external receiving terminal in a wireless transmission mode.

Furthermore, a plurality of signal transmission windows for transmitting the torque signal to the outside are arranged on the outer circumference of the lower split body.

Further, the piezoelectric sensor is a piezoelectric sensor comprising a multi-layer piezoelectric ceramic sheet stacking structure.

The beneficial effects of the utility model reside in that: the torque detection assembly is arranged on the cutter body, the torque signal in the machining process of the cutter is acquired through the torque detection assembly, and the receiving terminal judges the working state of the cutter according to the torque signal, so that the cutter is monitored. Compare in current processing cutter monitoring mode, the moment of torsion formula monitoring handle of a knife of this application monitors through the moment of torsion mode that acquires the cutter, can be suitable for with the cutter of different diameter sizes.

Drawings

FIG. 1 is a schematic structural view of a torque type monitoring tool handle according to an embodiment of the present invention;

FIG. 2 isbase:Sub>A schematic sectional view taken along section A-A of FIG. 1;

FIG. 3 is a schematic sectional view taken along section B-B of FIG. 1;

FIG. 4 is an exploded view of the torque type monitoring tool handle according to the embodiment of the present invention;

fig. 5 is a schematic structural view of an upper split body according to an embodiment of the present invention;

fig. 6 is a schematic structural view of a torque force measuring carrier according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a pre-tightening block according to an embodiment of the present invention;

fig. 8 is a schematic structural view of a lower split body according to an embodiment of the present invention;

fig. 9 is a schematic structural diagram of a piezoelectric sensor according to an embodiment of the present invention.

Description of reference numerals:

100. a knife handle body; 110. an upper split body; 111. an end cap; 112. a T-shaped chute; 113. a first screw; 120. a torque force measurement carrier; 121. a first chamber; 122. a counter bore; 123. a second screw; 130. a lower split body; 131. a second cavity; 132. a signal transmission window; 140. a pre-tightening block; 141. a first threaded hole; 142. a second threaded hole; 210. a piezoelectric sensor; 211. avoiding holes; 220. a battery; 230. a circuit board; 240. a first piezoelectric sensor; 250. a second piezoelectric sensor; 150. a first pre-tightening block; 160. a second pre-tensioning block; 300. a tool holding assembly; 310. a clamping cylinder; 320. a nut; 400. provided is a milling cutter.

Detailed Description

In order to explain the technical content, the objects and the effects of the present invention in detail, the following description is made with reference to the accompanying drawings in combination with the embodiments.

Examples

Referring to fig. 1 to 9, an embodiment of the present invention is:

referring to fig. 1 to 4, a torque type monitoring tool shank includes: handle of a knife body 100, moment of torsion detection subassembly and cutter fixed subassembly 300. The tool holder comprises a tool holder body 100 and a tool fixing assembly 300, wherein the torque detection assembly is arranged inside the tool holder body 100 and used for detecting the torque of a tool, outputting a corresponding torque signal and sending the torque signal to an external receiving terminal so as to judge the wear state of the tool according to the torque signal through the receiving terminal. The receiving terminal can be an oscilloscope, a computer and the like, and can be adjusted according to actual needs.

The principle of the torque type monitoring knife handle of this embodiment is: be provided with the moment of torsion detection subassembly on handle of a knife body 100, on the cutter was fixed in cutter fixed subassembly 300, when handle of a knife body 100 drove the cutter and rotates, the moment of torsion of cutter was acquireed to the moment of torsion detection subassembly to output corresponding torque signal to outside receiving terminal, judge the wearing and tearing state of current cutter through outside receiving terminal according to the torque signal. When the cutter is worn, the torque signal can be changed, so that the cutter is worn or damaged. Illustratively, the receiving terminal compares the torque signal with a preset threshold value, and when the torque signal exceeds the preset threshold value, the cutter is judged to be seriously worn, and a corresponding alarm is sent out.

It can be understood that the torque type monitoring handle of a knife of this embodiment compares in current processing cutter monitoring mode, judges the wearing and tearing condition of processing cutter through the moment of torsion that obtains the cutter, can be suitable for with the cutter of different diameter sizes.

Referring to fig. 2 to 9, in detail, the tool shank body 100 includes: the upper split body 110 is used for connecting a machine tool spindle, and an end cover 111 is arranged at the bottom of the upper split body 110. The torque force measuring carrier 120 is of a cylinder-like structure, and a first accommodating cavity 121 for accommodating part of the torque detection assembly is arranged in the torque force measuring carrier 120. The pre-tightening block 140 is eccentrically arranged with the axis of the outer circumference of the torque force-measuring carrier 120 and is located in the first accommodating cavity 121, and the pre-tightening block 140 is fixedly connected with the end cover 111 of the upper split body 110 and the torque force-measuring carrier 120 respectively. The lower split 130 is provided with a second cavity 131 for accommodating the remaining part of the torque detection assembly, the second cavity 131 is communicated with the first cavity 121, the top of the lower split 130 is fixedly connected with the torque force measurement carrier 120, and the bottom of the lower split 130 is fixedly connected with the cutter fixing assembly 300.

The torque detection assembly comprises a piezoelectric sensor 210 accommodated in the first accommodating cavity 121, the piezoelectric sensor 210 and the axis of the outer circumference of the torque force-measuring carrier 120 are eccentrically arranged, the detection surface of the piezoelectric sensor 210 is abutted to the pre-tightening block 140, the pre-tightening block 140 is used for applying positive pressure to the piezoelectric sensor 210 when the upper split body 110 rotates, and the sensor is used for responding to the positive pressure and outputting a corresponding torque signal.

In this embodiment, the upper split body 110, the torque force measuring carrier 120 and the lower split body 130 are sequentially connected to form a closed accommodating space for accommodating the torque detecting assembly. The upper split body 110 is provided with a structure for connecting a machine tool spindle, the end cover 111 of the upper split body 110 is a circular end cover 111, the upper split body 110 is fixedly connected with the pre-tightening block 140 through the end cover 111, the upper split body 110 serves as an input end of torque, the machine tool spindle drives the upper split body 110 to rotate, the pre-tightening block 140 is driven to rotate eccentrically in the rotating process of the upper split body 110, the pre-tightening block 140 applies positive pressure to the piezoelectric ceramic piece, the piezoelectric ceramic piece responds to the positive pressure to output a torque signal in the form of an electric signal, the natural reduction or sudden reduction of the electric signal is related to the abrasion condition or damage of a cutter, and therefore torque detection is achieved.

In addition, the tool holder body 100 of the embodiment is arranged in a split manner, so that the torque detection assembly can be conveniently installed, maintained and replaced. In this embodiment, the first cavity 121 is a cubic cavity, and the second cavity 131 is a cylindrical cavity. In other embodiments, the sensing element of the torque detection assembly may be other types of sensors, and is not limited herein.

Optionally, the piezoelectric sensor 210 is a piezoelectric sensor 210 including a multi-layer piezoelectric sheet ceramic stack structure. The piezoelectric sensor 210 including the multi-layer piezoelectric ceramic wafer stack structure is adopted in the embodiment, so that the cost is lower than that of a traditional quartz sensor in performance, and the structure is simpler.

Referring to fig. 2 to 4, in detail, the torque detection assembly further includes: the battery 220 is accommodated in the first accommodating cavity 121. The circuit board 230 is electrically connected to the battery 220 and the piezoelectric sensor 210, respectively, and is configured to receive the torque signal and send the torque signal to an external receiving terminal, and the circuit board 230 is accommodated in the second accommodating cavity 131 of the lower split body 130.

In this embodiment, the circuit board 230 is provided with a related detection circuit required for the operation of the piezoelectric sensor 210, and the battery 220 is used for supplying power to the circuit board 230 and the piezoelectric sensor 210. Illustratively, the lower split body 130 is a similar-rotation body structure having a plurality of different outer circumferential diameters, and since the second cavity 131 is a cylindrical accommodating space, the circuit board 230 may be a circular circuit board 230 to be embedded into the second cavity 131.

Optionally, the circuit board 230 is an annular circuit board 230, and the battery 220 is disposed at a central position of the torque force measuring carrier 120 and is partially suspended in the second cavity 131. It can be understood that, in the present embodiment, the annular circuit board 230 is adopted, the center of the circuit board 230 is a blank area, and can be used for accommodating a partial volume of the battery 220, and in the present embodiment, the battery 220 is disposed at the center position of the torque force measuring carrier 120, so that the center of gravity of the tool holder is kept at the center position, which is beneficial to keeping the normal rotation of the tool holder, and meanwhile, the upper split body 110 is also convenient to detach so as to replace the battery 220 at any time. In other embodiments, the circuit board 230 may have a structure, and in this embodiment, an upper annular circuit board 230 and a lower annular circuit board 230 are used for electrical connection, for example, to provide sufficient arrangement space for the detection circuit. In this embodiment, the battery 220 is a polymer lithium battery 220 with model number 853759T.

Referring to fig. 7, optionally, the pre-tightening block 140 is provided with a first threaded hole 141 in the vertical direction, and the end cover 111 is provided with a T-shaped sliding groove 112 corresponding to the first threaded hole 141. The T-shaped sliding slot 112 is provided with a first screw 113 and is fixedly matched with the first threaded hole 141. It can be understood that, in this embodiment, the end cover 111 is provided with the T-shaped sliding groove 112, so that the connection position between the upper split body 110 and the pre-tightening block 140 can be adjusted, and is not affected by the pre-tightening force, which is beneficial to ensuring high-precision measurement of the torque.

Referring to fig. 3, fig. 4, fig. 6, fig. 7 and fig. 9, optionally, an avoiding hole 211 is formed in the piezoelectric sensor 210 in the normal direction of the detection surface, the pre-tightening block 140 is provided with a second threaded hole 142 corresponding to the avoiding hole 211, the torque force measurement carrier 120 is provided with a counter bore 122 corresponding to the second threaded hole 142, the torque force measurement carrier 120 is provided with a second screw 123, and the second screw 123 sequentially penetrates through the counter bore 122 and the avoiding hole 211 and is fixedly matched with the second threaded hole 142.

It can be understood that the second screw 123 sequentially penetrates through the counter bore 122 and the avoiding hole 211 and then is fixedly matched with the second threaded hole 142, so that the torque force measuring carrier 120, the pre-tightening block 140 and the piezoelectric sensor 210 are combined into a whole, the pre-tightening block 140 abuts against the piezoelectric sensor 210 to provide pre-tightening force, and the piezoelectric sensor 210 abuts against the inner side wall of the first accommodating cavity 121, so that the overall structure is more stable when the tool holder rotates, and the detection stability of a torque signal is improved. The pretension of the pretension block 140 can be adjusted by the second screw 123.

Referring to fig. 2 to 4, the two piezoelectric sensors 210 are provided, and include a first piezoelectric sensor 240 and a second piezoelectric sensor 250, and the first piezoelectric sensor 240 and the second piezoelectric sensor 250 are disposed at a distance of 180 ° with respect to the axial center of the outer circumference of the torque load cell 120. The pre-tightening blocks 140 are two, and include a first pre-tightening block 150 and a second pre-tightening block 160, the first pre-tightening block 150 and the second pre-tightening block 160 are arranged at a distance of 180 degrees with the axis of the outer circumference of the torque force measuring carrier 120 as the center, the first pre-tightening block 150 abuts against the detection surface of the first piezoelectric sensor 240, and the second pre-tightening block 160 abuts against the detection surface of the second piezoelectric sensor 250.

It can be understood that, in the present embodiment, two piezoelectric sensors 210 and two pre-tightening blocks 140 arranged at an interval of 180 ° are adopted, and one of them is used in a corresponding manner, so that the tool holder can be kept balanced and stable during rotation, and, for example, whether the central shaft is shifted or not during rotation of the tool holder can be determined by comparing torque signals of the two piezoelectric sensors 210. Illustratively, when a single piezoelectric transducer 210 is used, it is desirable to provide a ring array of weights equally spaced from the piezoelectric transducer 210, the weights of the weights being configured to equal the sum of the weights of the piezoelectric transducer 210 and the pre-load block 140, thereby ensuring that the tool shank is balanced when rotated.

In the process of monitoring the cutting parameters of the machine tool, a related dynamometer is usually installed on a tool shank or a workbench, a strain type, capacitance type, inductance type or piezoelectric type sensitive element and the like are used in the dynamometer to sense the measured information in the cutting process, and the sensing element converts the measured information into an electric signal according to a certain rule and outputs the electric signal. The output electric signal is connected to a signal processing instrument through a lead for processing, and the electric signal is subjected to processing such as filtering and amplification and can be connected to software of an electric meter, an oscilloscope or a computer for displaying. Therefore, monitoring equipment used in real-time monitoring is huge and complicated in connection, and if the monitored machine tool cutting parameters are more or the machine tool spindle is in a rotary motion state, the problem of difficulty in use is brought, and even the real-time monitoring of the machine tool cutting parameters is difficult to realize.

Therefore, in order to optimize the connection of each component in the monitoring system, in this embodiment, the circuit board 230 is provided with a wireless module, and the wireless module is in communication connection with an external receiving terminal and is used for sending the torque signal to the external receiving terminal in a wireless transmission manner. Correspondingly, a wireless signal receiver for receiving the torque signal format is arranged on the receiving terminal.

It can be understood that, in the present embodiment, the wireless module is disposed on the circuit board 230, and the torque signal is transmitted to the external receiving terminal in a wireless transmission manner in real time, so as to avoid a complicated installation and wiring operation, and simplify the line connection of the tool monitoring system. The wireless module is an existing module, and may be one of a bluetooth module, a Wi-Fi module, a ZigBee (ZigBee) module, a Long Range Radio (Long Range Radio) module, and the like.

Referring to fig. 8, further, a plurality of signal transmission windows 132 for transmitting the torque signal to the outside are disposed on an outer circumference of the lower sub-body 130. Specifically, the four signal transmission windows 132 are arranged in the outer circumferential annular array of the lower split body 130, so that the wireless signals are prevented from being shielded, and the torque signals are favorably transmitted to the outside of the tool holder in a wireless signal manner.

Referring to fig. 1, 2 and 4, for example, the torque type monitoring tool holder of the present embodiment is a milling tool 400, the tool fixing assembly 300 includes a clamping cylinder 310 and a nut 320, the clamping cylinder 310 is disposed at the bottom of the lower split body 130, the bottom of the lower split body 130 is further provided with an external thread engaged with the nut 320, the milling tool 400 is installed in the clamping cylinder 310, and the milling tool 400 is fixed on the tool holder by tightening the nut 320.

In addition, the components such as the torque detection assembly and the torque force measuring carrier 120 in the torque type monitoring tool holder of the embodiment may be applied to a machine tool, a spindle of a main shaft of a wind turbine generator, and the like, and are not limited herein.

To sum up, the utility model provides a moment of torsion formula monitoring handle of a knife is through setting up the moment of torsion determine module on the cutter body to acquire the torque signal in the cutter course of working through the moment of torsion determine module, receiving terminal judges the operating condition of cutter according to torque signal, thereby realizes the monitoring to the cutter. Compare in current processing cutter monitoring mode, the moment of torsion formula monitoring handle of a knife of this application monitors through the moment of torsion mode that acquires the cutter, can be suitable for with the cutter of different diameter sizes.

In addition, the cutter handle body is arranged in a split mode, and the torque detection assembly is convenient to install, maintain and replace. This application still adopts two piezoelectric sensor and two pretension pieces that 180 intervals set up to make one of them one-to-one cooperate the use, can be so that handle of a knife keep balance stable when rotating, and, through comparing two piezoelectric sensor's torque signal, can judge whether the handle of a knife rotates process center pin and whether shift etc. appear.

In this application, be provided with wireless module on the circuit board, send the torque signal to outside receiving terminal with wireless transmission mode to avoid complicated installation wiring operation, simplify cutter monitored control system's line connection.

The above mentioned is only the embodiment of the present invention, and not the limitation of the patent scope of the present invention, all the equivalent transformations made by the contents of the specification and the drawings, or the direct or indirect application in the related technical field, are included in the patent protection scope of the present invention.

Claims (10)

1. A torque-type monitoring tool shank, comprising: the tool holder comprises a tool holder body, a torque detection assembly and a tool fixing assembly;

the tool handle comprises a tool handle body, a tool fixing component and a torque detection component, wherein the tool handle body is fixedly connected with the tool fixing component, the torque detection component is arranged in the tool handle body and is used for detecting the torque of the tool, outputting a corresponding torque signal and sending the torque signal to an external receiving terminal so as to judge the wear state of the tool according to the torque signal through the receiving terminal.

2. The torqued monitoring tool shank of claim 1, wherein the tool shank body comprises:

the upper split body is used for connecting a main shaft of the machine tool, and an end cover is arranged at the bottom of the upper split body;

the torque force measuring carrier is of a cylinder-like structure, and a first accommodating cavity for accommodating part of the torque detection assembly is arranged in the torque force measuring carrier;

the pre-tightening block is eccentrically arranged with the axis of the outer circumference of the torque force measuring carrier and is positioned in the first accommodating cavity, and the pre-tightening block is fixedly connected with the end cover of the upper split body and the torque force measuring carrier respectively;

the lower split body is provided with a second containing cavity for containing the rest part of the torque detection assembly, the second containing cavity is communicated with the first containing cavity, the top of the lower split body is fixedly connected with the torque force measurement carrier, and the bottom of the lower split body is fixedly connected with the cutter fixing assembly;

the torque detection assembly comprises a piezoelectric sensor accommodated in the first accommodating cavity, the piezoelectric sensor and the axis of the outer circumference of the torque force measurement carrier are eccentrically arranged, the detection surface of the piezoelectric sensor is abutted to the pre-tightening block, the pre-tightening block is used for applying positive pressure to the piezoelectric sensor when the upper split body rotates, and the sensor is used for responding to the positive pressure and outputting a corresponding torque signal.

3. The torque-based monitoring tool shank of claim 2, wherein the torque detection assembly further comprises:

the battery is accommodated in the first accommodating cavity; and

the circuit board is respectively electrically connected with the battery and the piezoelectric sensor and used for receiving the torque signal and sending the torque signal to an external receiving terminal, and the circuit board is contained in the second containing cavity of the lower split body.

4. The torque type monitoring knife handle according to claim 2, wherein the pre-tightening block is provided with a first threaded hole in the vertical direction, and the end cover is provided with a T-shaped sliding groove corresponding to the first threaded hole;

and the T-shaped sliding groove is provided with a first screw in a penetrating way and is fixedly matched with the first threaded hole.

5. The torque type monitoring knife handle according to claim 2, wherein the piezoelectric sensor is provided with an avoidance hole in the normal direction of the detection surface, the pre-tightening block is provided with a second threaded hole corresponding to the avoidance hole, the torque force measurement carrier is provided with a counter bore corresponding to the second threaded hole, the torque force measurement carrier is provided with a second screw, and the second screw is sequentially arranged in the counter bore and the avoidance hole in a penetrating manner and is fixedly matched with the second threaded hole.

6. The torque type monitoring tool handle according to claim 2, wherein the number of the piezoelectric sensors is two, and the two piezoelectric sensors comprise a first piezoelectric sensor and a second piezoelectric sensor, and the first piezoelectric sensor and the second piezoelectric sensor are arranged at a distance of 180 degrees with respect to the axis of the outer circumference of the torque force measuring carrier;

the two pre-tightening blocks comprise a first pre-tightening block and a second pre-tightening block, the first pre-tightening block and the second pre-tightening block are arranged at a distance of 180 degrees by taking the axis of the outer circumference of the torque force measuring carrier as a center, the first pre-tightening block is abutted against the detection surface of the first piezoelectric sensor, and the second pre-tightening block is abutted against the detection surface of the second piezoelectric sensor.

7. The torque type monitoring knife handle according to claim 3, wherein the circuit board is an annular circuit board, and the battery is arranged in the center of the torque force measuring carrier and partially suspended in the second accommodating cavity.

8. The torque type monitoring knife handle according to claim 3, characterized in that the circuit board is provided with a wireless module, and the wireless module is in communication connection with an external receiving terminal and used for sending the torque signal to the external receiving terminal in a wireless transmission mode.

9. The torque type monitoring tool shank according to claim 8, wherein a plurality of signal transmission windows for transmitting the torque signal to the outside are arranged on the outer circumference of the lower split body.

10. The torqued monitoring tool shank of claim 2, wherein the piezoelectric sensor is a piezoelectric sensor comprising a stacked structure of multiple layers of piezoelectric ceramic wafers.

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