CN116989907A - Wireless temperature measurement sensor protection structure for mining temperature measurement - Google Patents

Abstract

The invention relates to the technical field of protective structures, in particular to a wireless temperature measurement sensor protective structure for mining temperature measurement, which comprises a substrate and a baffle ring fixed on the side wall of the substrate, wherein the axis of the baffle ring is horizontal, the side wall of the baffle ring is provided with a passage opening, the passage opening and the axis of the baffle ring are positioned on the same horizontal plane, a turntable is rotationally arranged in the baffle ring, the side wall of the turntable is provided with a sleeve, one end of the sleeve is sealed, the other end of the sleeve is open, and an inserting structure is slidably arranged in the sleeve; the plug-in structure and the wireless temperature sensor are quickly installed and fixed in a rotary limiting mode by adopting the baffle ring and the sleeve, so that the risk that the wireless temperature sensor falls off due to vibration of a mine hole is effectively avoided, the installation firmness of the wireless temperature sensor is improved, the wireless temperature sensor is effectively protected conveniently, the wireless temperature sensor is prevented from being damaged, and meanwhile, the quick assembly work of the wireless temperature sensor can be realized in the structural mode.

Description

Wireless temperature measurement sensor protection structure for mining temperature measurement

Technical Field

The invention relates to the technical field of protective structures, in particular to a wireless temperature measurement sensor protective structure for mine temperature measurement.

Background

In the mining operation process, a large amount of gas can be generated in the mine cavity, the gas can burn and explode at a certain temperature, so that the explosion-proof work of the mine cavity is one of important works of safe mining, for monitoring the temperature in the mine cavity in real time, a wireless temperature sensor is generally additionally arranged in the mine cavity, and the temperature of the mine cavity is transmitted to a ground monitoring room in real time through the wireless temperature sensor, so that the wireless temperature sensor is an essential explosion-proof device in the mining industry.

When the wireless temperature measuring sensor is used, the wireless temperature measuring sensor is fixed on the inner wall of the mine hole in a direct hanging or bolt fastening mode, and vibration is generated in the mine hole during mining, so that the wireless temperature measuring sensor is easy to fall off due to the vibration, the wireless temperature measuring sensor is damaged, and the temperature in the mine hole cannot be effectively monitored by the monitoring room at the moment.

Disclosure of Invention

In order to solve the technical problems, the invention provides a wireless temperature measurement sensor protection structure for mining temperature measurement.

In order to achieve the above purpose, the technical scheme adopted by the invention is as follows:

the utility model provides a wireless temperature measurement sensor protective structure of mining temperature measurement, includes base plate and the baffle ring of fixing on the base plate lateral wall, and baffle ring axis level has seted up the passway on the lateral wall of baffle ring, and the passway is located same horizontal plane with baffle ring axis, and baffle ring rotation is equipped with the carousel, is equipped with the sleeve pipe on the lateral wall of carousel, and one end of sleeve pipe is sealed, and its other end opening, the intraductal slip of sleeve is equipped with grafting structure, installs wireless temperature measurement sensor on the grafting structure;

the sleeve is provided with a notch on the side wall, the cross section of the inner wall of the sleeve is T-shaped, the plug-in structure extends to the outer side of the sleeve through the notch, the wireless temperature sensor is located on the outer side of the sleeve, and the length direction of the sleeve is along the radial direction of the turntable.

Preferably, a top plate is arranged in the sleeve in a sliding manner, the end face of the top plate extends out of the sleeve through a notch on the sleeve, and the top plate is elastically connected with the sleeve through a clamping groove;

the roof is towards offer the fixed slot on the lateral wall of grafting structure, be equipped with the contact inductor in the fixed slot, grafting structure passes through contact inductor and roof contact connection.

Preferably, the bottom of the baffle ring is provided with a clamping groove, an opening of the clamping groove faces to the axis of the baffle ring, and the clamping groove is used for enabling the plug-in structure to be inserted into the clamping groove through the opening of the sleeve so as to achieve the effect of clamping the sleeve and the plug-in structure.

Preferably, a lock plate is rotatably arranged at the top of the baffle ring, the lock plate is elastically connected with the baffle ring through a first plate spring, and a handle is arranged on the side wall of the lock plate;

when the locking plate is vertical, the bottom of the locking plate can be in contact with the upper surface of the top plate outside the sleeve, and therefore the position of the top plate is limited and locked through the locking plate.

Preferably, the sleeve is far away from be provided with the arc deflector on the lateral wall of base plate, at the sleeve by the in-process of horizontality rotation to vertical state, the lock plate can slide overlap joint on the arc deflector to carry out slip screens effect to the lock plate through the arc deflector.

Preferably, the plug-in structure comprises a T-shaped column, a buckle plate and a fixed table, wherein the T-shaped column is hollow, the bottom of the T-shaped column is provided with an opening, the cross section of the T-shaped column is of a T shape, the T-shaped column is slidably arranged in a sleeve, the side wall of the T-shaped column far away from a base plate is provided with a notch of the same structure, the buckle plate is packaged on the notch of the T-shaped column, the buckle plate slides on the T-shaped column along the length direction of the T-shaped column, the buckle plate is of a U shape, the fixed table is arranged in the buckle plate, and the wireless temperature sensor is fixed at the bottom of the fixed table;

the pinch plate is positioned at the outer side of the baffle ring, and the T-shaped column is elastically connected with the pinch plate through a second spring.

Preferably, the fixing table is slidably mounted on the inner wall of the buckle plate along the length direction of the buckle plate, a telescopic rod is obliquely connected between the fixing table and the T-shaped column, two ends of the telescopic rod are respectively and rotatably connected with the T-shaped column and the fixing table, and the extending end of the telescopic rod is elastically connected with the T-shaped column through a second plate spring;

wherein the fixed table slides in a prescribed stroke on the buckle plate.

Preferably, the end part of the buckle plate, which is close to the opening of the T-shaped column, is rotationally provided with a sealing plate, and the sealing plate is elastically connected with the buckle plate through a third plate spring.

Compared with the prior art, the invention has the beneficial effects that: the plug-in structure and the wireless temperature sensor are quickly installed and fixed in a rotary limiting mode by adopting the baffle ring and the sleeve, so that the risk that the wireless temperature sensor falls off due to vibration of a mine hole is effectively avoided, the installation firmness of the wireless temperature sensor is improved, the wireless temperature sensor is effectively protected conveniently, the wireless temperature sensor is prevented from being damaged, and meanwhile, the quick assembly work of the wireless temperature sensor can be realized in the structural mode.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings may be obtained according to the drawings without inventive effort to those skilled in the art.

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is an enlarged schematic view of the base plate, the retainer ring and the turntable of FIG. 1;

FIG. 3 is a schematic view of the explosive structure of FIG. 1;

FIG. 4 is an enlarged schematic view of the rotor in FIG. 3;

FIG. 5 is an enlarged schematic view of the plugging structure in FIG. 3;

FIG. 6 is a schematic cross-sectional view of the T-post and buckle of FIG. 5;

FIG. 7 is an enlarged schematic view of the T-pillar of FIG. 5;

the reference numerals in the drawings: 1. a substrate; 2. a baffle ring; 3. a passage opening; 4. a turntable; 5. a sleeve; 6. a plug-in structure; 7. a wireless temperature measurement sensor; 8. a first spring; 9. a top plate; 10. a clamping groove; 11. a lock plate; 12. a first leaf spring; 13. a handle; 14. an arc-shaped guide plate; 15. a T-shaped column; 16. a buckle plate; 17. a fixed table; 18. a second spring; 19. a telescopic rod; 20. a second leaf spring; 21. a sealing plate; 22. and a third leaf spring.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

In the description of the present invention, it should be noted that the directions or positional relationships indicated as being "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are directions or positional relationships based on the drawings are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements to be referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; the connection may be direct or indirect via an intermediate medium, or may be internal communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art. This example was written in a progressive manner.

As shown in fig. 1 to 5, the protection structure of the wireless temperature sensor for mining temperature measurement comprises a base plate 1 and a baffle ring 2 fixed on the side wall of the base plate 1, wherein the axis of the baffle ring 2 is horizontal, a passage opening 3 is formed in the side wall of the baffle ring 2, the passage opening 3 and the axis of the baffle ring 2 are positioned on the same horizontal plane, a rotary table 4 is rotationally arranged in the baffle ring 2, a sleeve 5 is arranged on the side wall of the rotary table 4, one end of the sleeve 5 is sealed, the other end of the sleeve is open, an inserting structure 6 is slidably arranged in the sleeve 5, and a wireless temperature sensor 7 is arranged on the inserting structure 6;

wherein, set up the opening on the lateral wall of sleeve pipe 5, the inner wall cross-section shape of sleeve pipe 5 is the T type from this, and grafting structure 6 extends to the outside of sleeve pipe 5 through the opening, and wireless temperature sensor 7 is located the outside of sleeve pipe 5, and the length direction of sleeve pipe 5 is along the radial line direction of carousel 4.

Specifically, when the direction of sleeve pipe 5 is vertical, the opening direction of sleeve pipe 5 is towards the inner wall that keeps off ring 2, the inner wall that keeps off ring 2 carries out the shutoff to the opening of sleeve pipe 5 this moment, from this with grafting structure 6 card in sleeve pipe 5, the position of wireless temperature sensor 7 obtains fixedly, this fixed mode can not lead to grafting structure 6 and wireless temperature sensor 7 to drop because of the vibration in ore tunnel, thereby play the guard action to wireless temperature sensor 7, and when wireless temperature sensor 7 installs, rotate sleeve pipe 5 to the horizontal direction, sleeve pipe 5 drives carousel 4 and rotates, carousel 4 supports sleeve pipe 5, the opening direction of sleeve pipe 5 is towards access port 3, insert grafting structure 6 level through access port 3 and sleeve pipe 5 opening in, rotate sleeve pipe 5 to vertical direction again, sleeve pipe 5 and keep off ring 2 limit grafting structure 6 on sleeve pipe 5 this moment, thereby accomplish the quick installation work of wireless temperature sensor 7, through adopting the rotatory spacing mode of keeping off ring 2 and sleeve pipe 5 to install fixedly fast grafting structure 6 and wireless temperature sensor 7, thereby the wireless temperature sensor 7 is avoided the quick installation of wireless temperature sensor 7 to take place, the effect of wireless temperature sensor 7 is avoided the wireless temperature sensor 7 to take place, the guard action is easy to realize wireless temperature sensor 7, the wireless temperature sensor is easy to be damaged because of installing the wireless temperature sensor 7.

Preferably, as shown in fig. 4, a top plate 9 is slidably arranged in the sleeve 5, the end surface of the top plate 9 extends out of the sleeve 5 through a notch on the sleeve 5, and the top plate 9 is elastically connected with the sleeve 5 through a clamping groove 10;

the roof 9 is towards offer the fixed slot on the lateral wall of grafting structure 6, be equipped with the contact inductor in the fixed slot, grafting structure 6 passes through contact inductor and roof 9 contact connection.

Specifically, the first spring 8 produces the extrusion force to the sleeve 5 through roof 9 to make sleeve 5 open position part grafting structure 6 paste tightly with the extrusion of baffle 2 inner wall, make grafting structure 6 be in fixed state on sleeve 5 from this, improve grafting structure 6 and the fastness that wireless temperature sensor 7 installed, thereby avoid carousel 4 to rotate at will, avoid wireless temperature sensor 7 to drop, improve the protection effect, simultaneously because mutual extrusion contact through the contact inductor between grafting structure 6 and roof 9 takes place for when grafting structure 6 and roof 9, the contact inductor can in time transmit the signal to the monitoring room on ground, make things convenient for the timely discovery of staff.

Preferably, as shown in fig. 3, a clamping groove 10 is formed at the bottom of the baffle ring 2, the opening of the clamping groove 10 faces the axis of the baffle ring 2, and the clamping groove 10 is used for enabling the plugging structure 6 to be inserted into the clamping groove 10 through the opening of the sleeve 5, so as to achieve the effect of clamping the sleeve 5 and the plugging structure 6.

Specifically, when the sleeve 5 is in a vertical state, due to the elastic pushing action of the first spring 8, the bottom of the plug structure 6 extends out of the opening of the sleeve 5 and is inserted into the clamping groove 10, and the clamping groove 10 can clamp the plug structure 6, so that the turntable 4 is prevented from rotating randomly, and the turntable 4, the sleeve 5, the plug structure 6 and the wireless temperature sensor 7 are locked, so that the sleeve 5 rotates randomly in the baffle ring 2 when the mine tunnel vibrates.

Preferably, as shown in fig. 3, a lock plate 11 is rotatably arranged at the top of the baffle ring 2, the lock plate 11 is elastically connected with the baffle ring 2 through a first plate spring 12, and a handle 13 is arranged on the side wall of the lock plate 11;

when the locking plate 11 is vertical, the bottom of the locking plate 11 can be in contact with the upper surface of the top plate 9 outside the sleeve 5, so that the position of the top plate 9 is limited and locked through the locking plate 11.

Specifically, when sleeve pipe 5 rotates to vertical state, insert draw-in groove 10 in inserting structure 6 bottom, roof 9 synchronous downmovement this moment, lock plate 11 is through the elasticity promotion of first leaf spring 12 and overturn downwards to the top of roof 9, lock plate 11 can contact with sleeve pipe 5's lateral wall towards base plate 1's lateral wall, lock plate 11 stops moving, lock plate 11 can play the screens effect to roof 9 this moment, thereby avoid roof 9 to upwards slide in sleeve pipe 5, further lock the position of inserting structure 6, can pull lock plate 11 through handle 13 and rotate, make lock plate 11 and roof 9 separation, thereby make things convenient for dismouting grafting structure 6 and wireless temperature sensor 7.

Preferably, as shown in fig. 4, an arc-shaped guide plate 14 is disposed on a side wall of the sleeve 5 away from the base plate 1, and the lock plate 11 can be slidably lapped on the arc-shaped guide plate 14 in the process of rotating the sleeve 5 from a horizontal state to a vertical state, so that the lock plate 11 is slidably clamped by the arc-shaped guide plate 14.

Specifically, when the sleeve 5 is horizontal, the lock plate 11 is in an outward inclined state, at this time, due to the action of the first plate spring 12, the lock plate 11 is slidingly extruded on the arc-shaped guide plate 14, thereby limiting the lock plate 11 through the arc-shaped guide plate 14, in the process that the sleeve 5 is rotated from the horizontal state to the vertical state, the lock plate 11 is slid onto the top plate 9 from the arc-shaped guide plate 14, at this time, the arc-shaped guide plate 14 plays a guiding role on the lock plate 11, when the sleeve 5 is vertical, the top plate 9 moves towards the center position of the baffle ring 2, at this time, the lock plate 11 is gradually rotated to the vertical state from the inclined state, and the bottom of the lock plate 11 is contacted with the bottom of the top plate 9, and the lock plate 11 performs clamping locking operation on the top plate 9.

Preferably, as shown in fig. 5 to 7, the plugging structure 6 is composed of a T-shaped column 15, a buckle 16 and a fixing table 17, the T-shaped column 15 is hollow, the bottom of the T-shaped column 15 is open, the cross section of the T-shaped column 15 is T-shaped, the T-shaped column 15 is slidably mounted in the sleeve 5, the side wall of the T-shaped column 15 far away from the base plate 1 is provided with a notch with the same structure, the buckle 16 is sealed on the notch of the T-shaped column 15, the buckle 16 slides on the T-shaped column 15 along the length direction of the T-shaped column 15, the buckle 16 is U-shaped, the fixing table 17 is mounted in the buckle 16, and the wireless temperature sensor 7 is fixed at the bottom of the fixing table 17;

the pinch plate 16 is located at the outer side of the baffle ring 2, and the T-shaped column 15 is elastically connected with the pinch plate 16 through a second spring 18.

Specifically, in the natural state, due to the elastic action of the second spring 18, the pinch plate 16 and the T-shaped column 15 are in a packaging state, at this time, the fixed table 17 and the wireless temperature sensor 7 are located in the T-shaped column 15, so that the wireless temperature sensor 7 is protected by the T-shaped column 15 and the pinch plate 16 before assembly, a gap in the T-shaped column 15 provides a space for the fixed table 17 to move, when the T-shaped column 15 is assembled, the T-shaped column 15 is inserted into the sleeve 5 through the opening of the passage opening 3 and the sleeve 5, the end of the pinch plate 16 is in contact with the outer wall of the arc-shaped guide plate 14, the pinch plate 16 is subjected to clamping treatment through the arc-shaped guide plate 14, the T-shaped column 15 and the pinch plate 16 move relatively, the pinch plate 16 drives the fixed table 17 and the wireless temperature sensor 7 to move to the outer side of the T-shaped column 15 through the opening of the T-shaped column 15, at this time, the wireless temperature sensor 7 is exposed to facilitate subsequent monitoring, when the T-shaped column 15 moves to the inner side of the sleeve 5, the T-shaped column 15 and the passage opening 3 is far away from the passage opening 3, and the rotary table 4 and the sleeve 5 are rotated, so that the T-shaped column 15 is smoothly locked to the T-shaped column 15 is locked to the vertical position of the T-shaped column 15 and the wireless temperature sensor 7 is locked in the vertical state by the vertical position and the T-shaped column 15.

Through the grafting structure 6 that adopts this structure, can accomodate and hide wireless temperature sensor 7 through T type post 15 and buckle 16 before wireless temperature sensor 7 assembles to shelter from the protection to wireless temperature sensor 7, even in the use simultaneously, keep off ring 2 damage leads to grafting structure 6 to break away from sleeve pipe 5, owing to the effect of second spring 18, still can make wireless temperature sensor 7 accomodate in T type post 15 voluntarily, thereby protects wireless temperature sensor 7.

Preferably, as shown in fig. 6, the fixing table 17 is slidably mounted on the inner wall of the buckle 16 along the length direction of the buckle 16, a telescopic rod 19 is obliquely connected between the fixing table 17 and the T-shaped column 15, two ends of the telescopic rod 19 are respectively rotatably connected with the T-shaped column 15 and the fixing table 17, and the extending end of the telescopic rod 19 is elastically connected with the T-shaped column 15 through a second leaf spring 20;

wherein the fixed table 17 slides within a prescribed stroke on the buckle 16.

Specifically, the second leaf spring 20 provides elastic thrust to the extension end of telescopic link 19, when wireless temperature sensor 7 is located T type post 15 inboard, telescopic link 19 is slope towards the direction of keeping away from fixed station 17, fixed station 17 and wireless temperature sensor 7 are hidden in the inboard of buckle 16 this moment equally, when buckle 16 slides on T type post 15 and when deviating gradually T type post 15, buckle 16 promotes telescopic link 19 by fixed station 17 and rotates gradually to the horizontality by the incline state, elastic deformation takes place for second leaf spring 20, when buckle 16 continues to slide, telescopic link 19 downward sloping, because the effort of second leaf spring 20, telescopic link 19 can promote fixed station 17 and slide on buckle 16, fixed station 17 gradually moves to the tip of buckle 16, and wireless temperature sensor 7 then moves to the outside of buckle 16, thereby through the purpose that wireless temperature sensor 7 synchronous motion simultaneously can make buckle 16 on T type post 15, conveniently increase the hidden degree of wireless temperature sensor 7 on T type post 15 and 16, the wireless temperature sensor 7 is accomodate to the protection that is convenient better.

Preferably, as shown in fig. 5 and 6, the end of the buckle plate 16 close to the opening of the T-shaped column 15 is rotatably provided with a sealing plate 21, and the sealing plate 21 is elastically connected with the buckle plate 16 through a third plate spring 22.

Specifically, when wireless temperature sensor 7 moves to the outside of buckle 16, wireless temperature sensor 7 can promote shrouding 21 to open, and the face that this moment shrouding 21 is located coincides with the length direction of buckle 16, and elastic deformation takes place for third leaf spring 22, and when wireless temperature sensor 7 received in T type post 15 and the buckle 16, third leaf spring 22 pulling shrouding 21 rotated, makes shrouding 21 be located the face and the length direction of buckle 16 perpendicular, and this moment shrouding 21 also seals the opening of T type post 15 to make T type post 15 and the inside constitution of buckle 16 seal the cavity and accomodate the protection to wireless temperature sensor 7.

The foregoing is merely a preferred embodiment of the present invention, and it should be noted that it will be apparent to those skilled in the art that modifications and variations can be made without departing from the technical principles of the present invention, and these modifications and variations should also be regarded as the scope of the invention.

Claims (8)

1. The utility model provides a wireless temperature measurement sensor protective structure of mining temperature measurement, a serial communication port, including base plate (1) and baffle ring (2) fixed on base plate (1) lateral wall, baffle ring (2) axis level, have offered on baffle ring (2) lateral wall access port (3), access port (3) are located same horizontal plane with baffle ring (2) axis, baffle ring (2) rotation is equipped with carousel (4), be equipped with sleeve pipe (5) on the lateral wall of carousel (4), the one end of sleeve pipe (5) is sealed, its other end opening, the intraductal grafting structure (6) that is equipped with of sleeve pipe (5), install wireless temperature measurement sensor (7) on grafting structure (6);

the side wall of the sleeve (5) is provided with a notch, the cross-section of the inner wall of the sleeve (5) is T-shaped, the plug-in structure (6) extends to the outer side of the sleeve (5) through the notch, the wireless temperature sensor (7) is located at the outer side of the sleeve (5), and the length direction of the sleeve (5) is along the radial direction of the rotary table (4).

2. The mining wireless temperature measurement sensor protection structure according to claim 1, wherein a top plate (9) is slidably arranged in the sleeve (5), the end face of the top plate (9) extends out of the sleeve (5) through a notch on the sleeve (5), and the top plate (9) is elastically connected with the sleeve (5) through a clamping groove (10);

the roof (9) is towards offer the fixed slot on the lateral wall of grafting structure (6), be equipped with the contact inductor in the fixed slot, grafting structure (6) are connected with roof (9) contact through the contact inductor.

3. The mining wireless temperature measurement sensor protection structure of claim 2, wherein a clamping groove (10) is formed in the bottom of the baffle ring (2), an opening of the clamping groove (10) faces to the axis of the baffle ring (2), and the clamping groove (10) is used for enabling the plugging structure (6) to be inserted into the clamping groove (10) through an opening of the sleeve (5) so as to achieve the effect of clamping the sleeve (5) and the plugging structure (6).

4. A mining wireless temperature measurement sensor protection structure according to claim 3, characterized in that the top of the baffle ring (2) is rotatably provided with a locking plate (11), the locking plate (11) is elastically connected with the baffle ring (2) through a first plate spring (12), and the side wall of the locking plate (11) is provided with a handle (13);

when the lock plate (11) is vertical, the bottom of the lock plate (11) can be in contact with the upper surface of the top plate (9) on the outer side of the sleeve (5), and therefore the position of the top plate (9) is limited and locked through the lock plate (11).

5. The mining temperature measurement wireless temperature measurement sensor protection structure according to claim 4, wherein the side wall of the sleeve (5) far away from the base plate (1) is provided with an arc-shaped guide plate (14), and the lock plate (11) can be in sliding lap joint with the arc-shaped guide plate (14) in the process that the sleeve (5) rotates from a horizontal state to a vertical state, so that the lock plate (11) is subjected to sliding clamping action through the arc-shaped guide plate (14).

6. The mining wireless temperature measurement sensor protection structure according to claim 5, wherein the plug-in structure (6) is composed of a T-shaped column (15), a buckle plate (16) and a fixed table (17), the T-shaped column (15) is hollow, the bottom of the T-shaped column (15) is open, the cross section of the T-shaped column (15) is of a T shape, the T-shaped column (15) is slidably mounted in the sleeve (5), the side wall of the T-shaped column (15) far away from the base plate (1) is provided with a notch of the same structure, the buckle plate (16) is packaged on the notch of the T-shaped column (15), the buckle plate (16) slides on the T-shaped column (15) along the length direction of the T-shaped column (15), the shape of the buckle plate (16) is of a U shape, the fixed table (17) is mounted in the buckle plate (16), and the wireless temperature measurement sensor (7) is fixed at the bottom of the fixed table (17);

the pinch plate (16) is positioned at the outer side of the baffle ring (2), and the T-shaped column (15) is elastically connected with the pinch plate (16) through a second spring (18).

7. The mining wireless temperature measurement sensor protection structure according to claim 6, wherein the fixed table (17) is slidably mounted on the inner wall of the buckle plate (16) along the length direction of the buckle plate (16), a telescopic rod (19) is obliquely connected between the fixed table (17) and the T-shaped column (15), two ends of the telescopic rod (19) are respectively and rotatably connected with the T-shaped column (15) and the fixed table (17), and the extending end of the telescopic rod (19) is elastically connected with the T-shaped column (15) through a second leaf spring (20);

wherein the fixed table (17) slides in a prescribed stroke on the buckle plate (16).

8. The mining wireless temperature measurement sensor protection structure according to claim 7, wherein a sealing plate (21) is rotatably arranged at the end part of the pinch plate (16) close to the opening of the T-shaped column (15), and the sealing plate (21) is elastically connected with the pinch plate (16) through a third plate spring (22).