CN112276591A

CN112276591A - Automatic processing device for placing cushion block of optical fiber temperature sensor

Info

Publication number: CN112276591A
Application number: CN202011199290.9A
Authority: CN
Inventors: 陈真生; 黄世付; 张家跃; 贵体仁
Original assignee: Changde Guoli Transformer Co ltd
Current assignee: Changde Guoli Transformer Co ltd
Priority date: 2020-11-01
Filing date: 2020-11-01
Publication date: 2021-01-29
Anticipated expiration: 2040-11-01
Also published as: CN112276591B

Abstract

The invention discloses an automatic processing device for placing a cushion block of an optical fiber temperature sensor, which comprises a cushion block conveying mechanism, a cushion block slotting positioning mechanism and a cushion block slotting mechanism, wherein the cushion block conveying mechanism is a conveying belt, a sliced cushion block is placed on the conveying belt for conveying, the cushion block slotting positioning mechanism is arranged on one side of the tail end of the conveying belt, and a transfer assembly is arranged between the tail end of the conveying belt and the cushion block slotting positioning mechanism; the gasket is grooved and processed in an automatic processing mode, and the fluorescent optical fiber sensor is implanted, so that the processing efficiency is improved, the labor intensity of workers is reduced, and meanwhile, the processing efficiency can be improved through continuous processing.

Description

Automatic processing device for placing cushion block of optical fiber temperature sensor

Technical Field

The invention relates to the field of monitoring equipment in a transformer, in particular to an automatic processing device provided with a cushion block of an optical fiber temperature sensor.

Background

Sensors for monitoring various data of the transformer are arranged in the existing transformer, but the coil temperature of the winding of the existing transformer is calculated out through the oil temperature in an oil tank, so that when the coil temperature is measured through an oil medium, a measurement error exists (the coil temperature is transmitted through cooling oil, then the coil data is obtained through measuring the oil temperature, so that heat is dissipated through the heat transmission of various media, the monitored temperature is different from the actual temperature of the coil), and the real-time temperature of the coil cannot be obtained in time because the heat needs to be transmitted through the cooling oil;

application No.: 201711473136.4A special cushion block and a fluorescent fiber temperature measurement transformer coil, wherein the temperature of the cushion block is directly detected by a fluorescent fiber temperature sensor arranged in the cushion block between the coils to realize the temperature cushion block of the cushion block (because the cushion block is directly contacted with the coils for a long time, the temperature of the cushion block is consistent with that of the coils), thus the temperature of the coils can be directly obtained by detecting the temperature of the cushion block; the special cushion block is tightly attached to and clamped between the upper common cushion block and the lower common cushion block, the cushion blocks in the scheme need to be divided into three blocks, a chute for placing the fluorescent optical fibers is formed in one of the cushion blocks, if the cushion blocks are grooved manually, the process is complex, the width of the chute cannot be guaranteed, the fixing degree of the fluorescent optical fibers and the cushion blocks after installation cannot be guaranteed when the fluorescent optical fibers are installed, meanwhile, the depth of a groove body is high in requirement (the chute is too deep, the fluorescent optical fibers are not in contact with the upper cushion block, the temperature sensing speed is low, if the chute is too shallow, the cushion blocks can extrude the fluorescent optical fibers when the cushion blocks are installed), meanwhile, the working efficiency is low, and the productivity of the transformer cannot be met.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides the automatic processing device for placing the cushion block of the optical fiber temperature sensor, which is used for automatically processing the chute convenient for placing the fluorescent optical fiber on the cushion block, so that the efficiency is ensured, and the labor intensity of workers is reduced.

In order to achieve the purpose, the scheme of the invention is as follows: an automatic processing device for placing an optical fiber temperature sensor cushion block, a cushion block conveying mechanism, a cushion block slotting positioning mechanism and a cushion block slotting mechanism, wherein the cushion block conveying mechanism is a conveying belt, the sliced cushion block is placed on the conveying belt for conveying, the cushion block slotting positioning mechanism is arranged on one side of the tail end of the conveying belt, a transferring component is arranged between the tail end of the conveying belt and the cushion block slotting positioning mechanism, the cushion block on the tail end of the conveying belt is transferred onto the cushion block slotting positioning mechanism through the transferring component, the cushion block slotting positioning mechanism comprises a plurality of push blocks, positioning cylinders and positioning platforms, each positioning platform is a plurality of positioning platforms which form a ring, each positioning platform is provided with a positioning groove with the same size as the cushion block, a positioning component capable of lifting is arranged above one of the positioning platforms, and each positioning component comprises a push block and a positioning cylinder, the positioning cylinders are fixed on the rectangular frame, the positioning cylinders are positioned in the rectangular frame, push blocks are fixed on piston rods of the positioning cylinders, the push blocks surround the rectangular frame, rubber strips are arranged on the edges of the push blocks, the rectangular frame is fixed on the ground through cantilevers, a positioning lifting assembly is arranged between the support and the cantilevers, and the lifting of the positioning assembly is controlled through the positioning lifting assembly; a plurality of negative pressure suction holes are formed in the bottom of the positioning groove, and the cushion block is sucked into the positioning groove through the negative pressure suction holes; a gasket slotting mechanism is arranged above two adjacent positioning platforms, the gasket slotting mechanism comprises a straight slot slotting component and a waist-shaped slot slotting component, wherein the straight-groove slotting component is positioned above one of the positioning platforms, the straight-groove slotting component comprises a groove-shaped cutter and a pushing cylinder, the groove-shaped cutter is in a channel steel shape, two side edges of the groove-shaped cutter incline inwards, the groove-shaped cutter is arranged obliquely, a pushing cylinder is arranged at the tail part of the groove-shaped cutter and is detachably connected with the groove-shaped cutter, a guide sleeve is sleeved on the groove-shaped cutter and is fixed with a cylinder body of the pushing cylinder, a vertical cutter is arranged at the top of the groove-shaped cutter, a lifting cylinder is arranged at the top of the vertical cutter, the cylinder body of the lifting cylinder is fixed on the cylinder body of the pushing cylinder through a support, and the vertical cutter is positioned above the tail end of the cutting action of the groove-shaped cutter; the positioning device is characterized in that a kidney-shaped groove slotting component is arranged above the positioning platform on one side of the straight groove slotting component, the kidney-shaped groove slotting component is arranged right above the positioning platform, a cutter lifting component is arranged on the kidney-shaped groove slotting component to enable the kidney-shaped groove slotting component to lift through the cutter lifting component to slot the cushion block, the kidney-shaped groove slotting component comprises bed knives and vertical kidney-shaped hole knives, the bed knives are arranged outwards from the blade surfaces of the two bed knives, a supporting plate is fixed on each bed knife, an extrusion component is arranged between the two supporting plates, kidney-shaped hole knives are arranged on the supporting plates, and the bottoms of the kidney-shaped hole knives are blade surfaces.

Preferably, location lifting unit includes the mount, spring and pressing component, wherein mount and rectangular frame set up from top to bottom, be equipped with many springs that are used for the return between mount and rectangular frame, be fixed with many vertical guide bars and the guide bar interlude on rectangular frame of being provided with at the mount, be fixed with pressing component and pressing component on the mount and be the pressure cylinder, the cylinder body of pressure cylinder is fixed on the mount, the piston rod of pressure cylinder passes the mount and presses on rectangular frame, through pressing the cylinder with rectangular frame pushing down and make rectangular frame and locating platform top contact.

Preferably, the extrusion assembly is arranged between the two support plates and comprises a wedge block, an extrusion cylinder and return springs, a plurality of return springs are arranged between the two support plates, a triangular wedge block is further arranged between the two support plates and two sides of the wedge block support plates, the extrusion cylinder is fixed at the tail of each wedge block, the two support plates are inserted into a rectangular sleeve, a plurality of transverse cross rods are fixed on each support plate, and the cross rods penetrate through the rectangular sleeve; the rectangular sleeve is fixed on the lifting assembly, and the slotted assembly of the kidney-shaped groove is lifted up and down through the lifting assembly; the rectangular sleeve is provided with a waist-shaped hole cutter, the inside of the waist-shaped hole cutter is hollow, the supporting plate penetrates through the hollow part inside the waist-shaped hole cutter, the inner wall of the rectangular sleeve is fixedly provided with an air cylinder, and a piston rod of the air cylinder is fixed with the waist-shaped hole cutter.

Preferably, a plurality of negative pressure holes on each positioning platform are respectively connected with an air pump, a travel switch is fixed on the outer side surface of each positioning platform and connected with the air pump, a trigger block is arranged on the outer side of one positioning platform on the rear side of the slotted kidney-shaped groove assembly, when the travel switch moves to the position of the trigger block, the air pump blows air, and when the travel switch leaves the trigger block, the air pump sucks air.

Compared with the prior art, the invention has the advantages that: 1. the gasket is subjected to slotting processing in an automatic processing mode and the fluorescent optical fiber sensor is implanted, so that the processing efficiency is improved, the labor intensity of workers is reduced, and meanwhile, the processing efficiency can be improved through continuous processing; 2. the equipment is arranged to form a kidney-shaped groove on the cushion block, so that the fluorescent optical fiber sensor is conveniently clamped in the cushion block, and the cushion block is prevented from being separated from the fluorescent optical fiber in the use process; 3. the air suction and the air injection through the negative pressure hole realize the loading and the unloading of the cushion block, so that the operation is convenient and fast.

Drawings

FIG. 1 is a top view of the present invention.

FIG. 2 is a schematic view of the spacer slotting and positioning mechanism of the present invention.

Fig. 3 is a schematic view of the straight slot slotted assembly of the present invention.

Figure 4 is a top view of the slotted kidney assembly of the present invention.

Figure 5 is a cross-sectional view of the kidney slot slotting assembly of the present invention.

FIG. 6 is a schematic view of a positioning groove of the positioning platform according to the present invention.

Wherein, 1, cushion block conveying mechanism, 1.1, conveying belt, 1.2, transfer component, 1.3, negative pressure suction nozzle, 1.4, linear motor, 2, cushion block slotting positioning mechanism, 2.1, positioning component, 2.2, push block, 2.3, positioning cylinder, 2.4, rectangular frame, 2.5, rubber strip, 2.6, cantilever, 2.7, positioning lifting component, 2.8, fixing frame, 2.9, guide rod, 2.10, spring, 2.11, pressing component, 2.12, positioning platform, 2.13, positioning groove, 2.14, negative pressure suction hole, 2.15, air pump, 2.16, travel switch, 2.17, trigger block, 3, gasket slotting mechanism, 3.1, straight slot slotting component, 3.11, vertical cutter, 3.2, slot-shaped cutter, 3.3, guide sleeve, 3.4, push cylinder, 3.5, waist-shaped slot component, 3.6, slotting cutter component, 3.7, bottom hole, 3.11, wedge-shaped cutter, 3.12, wedge-shaped extrusion cylinder, 3.5, wedge-shaped extrusion support plate, 3.6, 3.13, a return spring, 3.14 and a rectangular sleeve.

Detailed Description

The invention will now be further elucidated with reference to the drawing.

As shown in fig. 1-6, an automatic processing device for placing a pad of an optical fiber temperature sensor comprises a pad conveying mechanism 1, a pad grooving positioning mechanism 2 and a pad grooving mechanism 3, wherein the pad conveying mechanism 1 is a conveying belt 1.1, the sliced pad is placed on the conveying belt 1.1 for conveying, the pad grooving positioning mechanism 2 is arranged on the front side of the right end of the conveying belt 1.1, a transfer assembly 1.2 is arranged between the tail end of the conveying belt 1.1 and the pad grooving positioning mechanism 2, the transfer assembly comprises a linear motor 1.4 and a negative pressure suction nozzle 1.3, the linear motor 1.4 is longitudinally fixed on the ground through a support (the support is fixed on the ground through a bolt), the negative pressure suction nozzle 1.3 is fixed on a moving block of the linear motor 1.4 in a welding manner, the pad is clamped and conveyed to the pad grooving positioning mechanism 2 through the negative pressure suction nozzle 1.3 (the pad is adsorbed on the negative pressure suction nozzle 1.3 through the negative pressure suction nozzle, the gasket is conveyed forwards through a linear motor 1.4, so that the gasket on the conveying belt 1.1 is transferred to a gasket slotting positioning mechanism 2 through a transfer assembly 1.2, the gasket on the tail end of the conveying belt 1.1 is transferred to the gasket slotting positioning mechanism 2 through the transfer assembly 1.2, the gasket slotting positioning mechanism 2 comprises a plurality of push blocks 2.2, positioning cylinders 2.3 and positioning platforms 2.12, the positioning platforms 2.12 are 6 and six positioning platforms 2.12 form a ring shape (six positioning platforms 2.12 are mutually fixed, a stepping motor is arranged between the six positioning platforms 2.12 and the bottom surface, the six positioning platforms 2.12 are driven to rotate through the stepping motor, so that continuous processing is completed), positioning grooves 2.13 with the sizes consistent with the sizes of the gaskets are arranged on each positioning platform 2.12, a lifting positioning assembly 2.1 is arranged above the positioning platform 2.12 close to the conveying belt 1.1, the positioning assembly 2.1 comprises push blocks 2.2 and positioning cylinders 2.3, the positioning cylinders 2.3 are four, four positioning cylinders 2.3 are fixed on the rectangular frame 2.4 in a welding mode, the positioning cylinders 2.3 are positioned in the rectangular frame 2.4, the push blocks 2.2 are fixed on the piston rods of the positioning cylinders 2.3, the push blocks 2.2 surround into a rectangle, the positions of the push blocks 2.2 correspond to the positioning grooves 2.13, rubber strips 2.5 are fixed on the edges of each push block 2.2 through glue (the push blocks 2.2 are placed to collide with each other to be damaged and make sound when in positioning, meanwhile, the sealing performance can be ensured, a gasket is conveniently placed into the positioning grooves 2.13 through negative pressure, the depth of the positioning grooves 2.13 is lower than that of the cushion, the thickness of the gasket protruding out of the positioning grooves is the depth of the chute), the rectangular frame 2.4 is fixed on the ground through the cantilever 2.6, the positioning lifting assembly 2.7 is arranged between the bracket and the cantilever 2.6, the lifting assembly 2.7 controls the lifting of the positioning assembly 2.1, the positioning component 2.1 is lifted through the positioning lifting component 2.1, so that the transfer component 1.2 is convenient to abdicate; a plurality of negative pressure suction holes 2.14 are formed in the bottom of the positioning groove 2.13, the cushion block is sucked into the positioning groove 2.13 through the negative pressure suction holes 2.14, and when the positioning groove 2.13 is under negative pressure, the cushion block is sucked into the positioning groove 2.13 to be fixed; a gasket slotting mechanism 3 is arranged above two adjacent positioning platforms 2.12, the gasket slotting mechanism 3 comprises a straight slot slotting component 3.1 and a kidney slot slotting component 3.5, wherein the straight slot slotting component 3.1 is arranged above one positioning platform 2.12, the straight slot slotting component 3.1 comprises a slot-shaped cutter 3.2 and a pushing cylinder 3.4, the slot-shaped cutter 3.2 is in a channel steel shape, two sides of the slot-shaped cutter 3.2 incline inwards, the shape obtained by cutting is narrow at the top and wide at the bottom, so that the fluorescent optical fiber can be prevented from falling out of a chute (prevented from coming out of an outlet at the top of the chute) during installation, the slot-shaped cutter 3.2 is obliquely arranged (convenient for cutting the chute, the oblique angle is changed according to the oblique angle of the chute on a cushion block), the pushing cylinder 3.4 is fixed at the tail part of the slot-shaped cutter 3.2 in a welding mode, and the pushing cylinder 3.4 is detachably connected with the slot-shaped cutter 3.2 (namely connected through bolts), a guide sleeve 3.3 is sleeved on the groove-shaped cutter 3.2, the guide sleeve 3.3 is fixed with the cylinder body of the pushing cylinder 3.4, a vertical cutter is arranged at the top of the groove-shaped cutter 3.2, a lifting cylinder is arranged at the top of the vertical cutter, the cylinder body of the lifting cylinder is fixed on the cylinder body of the pushing cylinder 3.4 through a bracket, the vertical cutter is positioned above the tail end of the groove-shaped cutter 3.2 for completing the cutting action, the pushing cylinder 3.4 is fixed on the ground through the bracket, when in grooving, the gasket is firstly cut by the vertical cutter because the cushion block protrudes out of the positioning groove 2.13, then the groove-shaped cutter 3.2 quickly ejects out to cut the cushion block, and the cut material is taken away by the groove-shaped cutter 3.2 (the cut material is clamped in the groove-shaped cutter 3.2, and the cut material in the groove-shaped cutter 3.2 is ejected out to complete unloading in the second cutting), so that the first procedure of the chute is completed; a kidney-shaped groove slotting component 3.5 is arranged above a positioning platform 2.12 at one side of a straight groove slotting component 3.1, the kidney-shaped groove slotting component 3.5 is arranged right above the positioning platform 2.12, a cutter lifting component 3.6 is arranged on the kidney-shaped groove slotting component 3.5, the kidney-shaped groove slotting component 3.5 lifts through the cutter lifting component 3.6 to slot a cushion block, the kidney-shaped groove slotting component 3.5 comprises bed knives 3.7 and vertical kidney-shaped hole knives 3.8, the bed knives 3.7 are two, the blade surfaces of the two bed knives 3.7 are arranged outwards, each bed knife 3.7 is fixed with a vertically upward supporting plate 3.9 in a welding mode, an extruding component 3.10 is arranged between the two supporting plates 3.9, the two supporting plates 3.9 are expanded towards two ends through the extrusion of the extruding component 3.10, thus the bottom of the chute is cut off, the kidney-shaped hole knives 3.8 are arranged on the supporting plates 3.9, the bottom of the kidney-shaped hole knives 3.8 is the chute edge, thus, the waist-shaped holes on the cushion block are processed.

The positioning lifting assembly 2.7 comprises a fixed frame 2.8, springs 2.10 and a pressing assembly 2.11, wherein the fixed frame 2.8 and the rectangular frame 2.4 are arranged up and down, a plurality of springs 2.10 for returning are arranged between the fixed frame 2.8 and the rectangular frame 2.4, a plurality of guide rods 2.9 (the guide rods 2.9 are telescopic rods) are vertically arranged on the fixed frame 2.8 in a welding manner, the guide rods 2.9 are inserted in the rectangular frame 2.4, the pressing assembly 2.11 is fixed on the fixed frame 2.8 in a welding manner, the pressing assembly 2.11 is a pressing cylinder, a cylinder body of the pressing cylinder is fixed on the fixed frame 2.8, a piston rod of the pressing cylinder penetrates through the fixed frame 2.8 to press the rectangular frame 2.4, the rectangular frame 2.4 is pressed downwards through the pressing cylinder, the rectangular frame 2.4 is contacted with the top of the positioning platform 2.12, when the pressing cylinder is pressed, the rectangular frame 2.4 descends, and thus the positioning assembly 2.1 on the rectangular frame positions a gasket, when the pressing air cylinder does not work, the spring 2.10 pulls the rectangular frame 2.4 to ascend and return, so that the whole positioning assembly ascends and descends.

The extrusion component 3.10 is arranged between the two support plates 3.9, the extrusion component 3.10 comprises a wedge-shaped block 3.11, an extrusion cylinder 3.12 and a return spring 3.13, a plurality of return springs 3.13 are fixed between the two supporting plates 3.9 in a welding mode (the supporting plates 3.9 are pulled to be close by the return springs 3.13), a triangular wedge-shaped block 3.11 is arranged between the two supporting plates 3.9, the wedge-shaped block 3.11 supports both sides of the plate 3.9, an extrusion cylinder 3.12 is fixed at the tail part of each wedge-shaped block 3.11, when the extrusion cylinder 3.12 is ejected out, the wedge-shaped block 3.11 pushes the two support plates 3.9 to be away from each other, thus, the two supporting plates 3.9 are opened by the wedge-shaped block 3.11, the two supporting plates 3.9 are inserted into a rectangular sleeve 3.14, a plurality of transverse cross rods are fixed on each supporting plate 3.9 and penetrate through the rectangular sleeves 3.14, and the cross rods penetrate through the rectangular sleeves 3.14 to play a role in guiding the supporting plates 3.9; the rectangular sleeve 3.14 is fixed on a lifting assembly (namely an air cylinder), the slotted kidney-shaped groove assembly 3.5 is lifted up and down through the lifting assembly, and the slotted kidney-shaped groove assembly 3.5 enters a chute of the cushion block for cutting processing through the lifting assembly; a waist-shaped hole cutter 3.8 is arranged in a rectangular sleeve 3.14, the inside of the waist-shaped hole cutter 3.8 is hollow, a supporting plate 3.9 penetrates through the hollow part in the waist-shaped hole cutter 3.8, an air cylinder is fixed on the inner wall of the rectangular sleeve 3.14, a piston rod of the air cylinder is fixed with the waist-shaped hole cutter 3.8, the air cylinder 3.8 drives the waist-shaped hole cutter 3.8 to descend to finish cutting to form a waist-shaped hole, therefore, when cutting is carried out, the bottom of a waist-shaped groove is cut off by outwards expanding a bed knife 3.8, and then the waist-shaped hole cutter 3.8 descends to cut off the edge to finish processing.

The plurality of negative pressure holes on each positioning platform 2.12 are respectively connected with an air pump 2.15 through pipelines, a travel switch 2.16 is fixed on the outer side surface of each positioning platform 2.12 through welding (the travel switch 2.16 is fixed on the outer peripheral side surface of each positioning platform 2.12 in an embedding mode, the travel switch 2.16 is arranged outwards), the travel switch 2.16 is connected with the air pump 2.15 through a lead (the air pump is forced to change the working state (namely changing the air suction into the air injection) through the triggering of the travel switch 2.16 so as to complete the automatic positioning and discharging function), the triggering block 2.17 is arranged on the outer side of one positioning platform 2.12 at the rear side of the kidney-shaped slotted groove component 3.5, when the travel switch 2.16 moves to the position of the triggering block 2.17, the air pump 2.15 injects air, so that the cushion block blown out from the positioning groove 2.13 is not discharged in the positioning groove 2.13, and when the travel switch 2.16 leaves the triggering block 2.17, the air pump 2, the positioning slot 2.13 is thus under negative pressure.

Claims

1. An automatic processing device for placing an optical fiber temperature sensor cushion block, a cushion block conveying mechanism, a cushion block slotting positioning mechanism and a cushion block slotting mechanism, wherein the cushion block conveying mechanism is a conveying belt, the sliced cushion block is placed on the conveying belt for conveying, the cushion block slotting positioning mechanism is arranged on one side of the tail end of the conveying belt, a transferring component is arranged between the tail end of the conveying belt and the cushion block slotting positioning mechanism, and the cushion block on the tail end of the conveying belt is transferred to the cushion block slotting positioning mechanism through the transferring component, the automatic processing device is characterized in that the cushion block slotting positioning mechanism comprises a plurality of push blocks, positioning cylinders and positioning platforms, each positioning platform is an annular shape formed by a plurality of positioning platforms, each positioning platform is provided with a positioning groove with the same size as the cushion block, a positioning component capable of lifting is arranged above one of the positioning platforms, and each positioning component comprises a push, the positioning cylinders are fixed on the rectangular frame, the positioning cylinders are positioned in the rectangular frame, push blocks are fixed on piston rods of the positioning cylinders, the push blocks surround the rectangular frame, rubber strips are arranged on the edges of the push blocks, the rectangular frame is fixed on the ground through cantilevers, a positioning lifting assembly is arranged between the support and the cantilevers, and the lifting of the positioning assembly is controlled through the positioning lifting assembly; a plurality of negative pressure suction holes are formed in the bottom of the positioning groove, and the cushion block is sucked into the positioning groove through the negative pressure suction holes; a gasket slotting mechanism is arranged above two adjacent positioning platforms, the gasket slotting mechanism comprises a straight slot slotting component and a waist-shaped slot slotting component, wherein the straight-groove slotting component is positioned above one of the positioning platforms, the straight-groove slotting component comprises a groove-shaped cutter and a pushing cylinder, the groove-shaped cutter is in a channel steel shape, two side edges of the groove-shaped cutter incline inwards, the groove-shaped cutter is arranged obliquely, a pushing cylinder is arranged at the tail part of the groove-shaped cutter and is detachably connected with the groove-shaped cutter, a guide sleeve is sleeved on the groove-shaped cutter and is fixed with a cylinder body of the pushing cylinder, a vertical cutter is arranged at the top of the groove-shaped cutter, a lifting cylinder is arranged at the top of the vertical cutter, the cylinder body of the lifting cylinder is fixed on the cylinder body of the pushing cylinder through a support, and the vertical cutter is positioned above the tail end of the cutting action of the groove-shaped cutter; the positioning device is characterized in that a kidney-shaped groove slotting component is arranged above the positioning platform on one side of the straight groove slotting component, the kidney-shaped groove slotting component is arranged right above the positioning platform, a cutter lifting component is arranged on the kidney-shaped groove slotting component to enable the kidney-shaped groove slotting component to lift through the cutter lifting component to slot the cushion block, the kidney-shaped groove slotting component comprises bed knives and vertical kidney-shaped hole knives, the bed knives are arranged outwards from the blade surfaces of the two bed knives, a supporting plate is fixed on each bed knife, an extrusion component is arranged between the two supporting plates, kidney-shaped hole knives are arranged on the supporting plates, and the bottoms of the kidney-shaped hole knives are blade surfaces.

2. The automatic processing device with the optical fiber temperature sensor cushion block placed thereon according to claim 1, characterized in that the positioning and lifting assembly comprises a fixed frame, springs and a pressing assembly, wherein the fixed frame and a rectangular frame are arranged up and down, a plurality of springs for returning are arranged between the fixed frame and the rectangular frame, a plurality of guide rods are vertically arranged on the fixed frame and penetrate through the guide rods, the pressing assembly is fixed on the fixed frame and is a pressing cylinder, a cylinder body of the pressing cylinder is fixed on the fixed frame, a piston rod of the pressing cylinder penetrates through the fixed frame to press the rectangular frame, and the rectangular frame is pressed downwards by the pressing cylinder and is in contact with the top of the positioning platform.

3. The automatic processing device with the optical fiber temperature sensor cushion block placed on the basis of claim 2 is characterized in that an extrusion assembly is arranged between two support plates, the extrusion assembly comprises a wedge block, an extrusion cylinder and return springs, a plurality of return springs are arranged between the two support plates, a triangular wedge block is further arranged between the two support plates, two sides of the wedge block support plates are provided with the wedge block, the extrusion cylinder is fixed at the tail of each wedge block, the two support plates are inserted into a rectangular sleeve, a plurality of transverse cross rods are fixed on each support plate, and the cross rods penetrate through the rectangular sleeve; the rectangular sleeve is fixed on the lifting assembly, and the slotted assembly of the kidney-shaped groove is lifted up and down through the lifting assembly; the rectangular sleeve is provided with a waist-shaped hole cutter, the inside of the waist-shaped hole cutter is hollow, the supporting plate penetrates through the hollow part inside the waist-shaped hole cutter, the inner wall of the rectangular sleeve is fixedly provided with an air cylinder, and a piston rod of the air cylinder is fixed with the waist-shaped hole cutter.

4. The automatic processing device with the cushion block of the optical fiber temperature sensor placed thereon according to claim 3, wherein the plurality of negative pressure holes on each positioning platform are respectively connected with an air pump, a travel switch is fixed on the outer side surface of each positioning platform, the travel switch is connected with the air pump, a trigger block is arranged on the outer side of one of the positioning platforms on the rear side of the slotted kidney assembly, when the travel switch moves to the position of the trigger block, the air pump blows air, and when the travel switch leaves the trigger block, the air pump sucks air.