CN114776997B - Thermal control instrument mounting device for thermal control of power plant - Google Patents

Abstract

The application discloses a thermal control instrument mounting device for thermal control of a power plant, which comprises a fixing plate, wherein the fixing plate is fixedly arranged on a wall surface through bolts and comprises two fixing blocks arranged on one side of the fixing plate far away from the wall surface and a sliding rail arranged on the fixing blocks; the base comprises a lifting plate parallel to the fixed plate, pin shafts arranged on two sides of the lifting plate and a base vertically connected with one end of the lifting plate; the pin shaft is matched with the sliding rail; the clamping assembly is arranged on one side of the fixed plate far away from the wall surface; and the fastening part is connected with the fixed plate in a sliding way. The application has the advantages of convenient installation and use, convenient adjustment of the clamping range according to different temperature control instruments, convenient adjustment of the distance between the instruments and the wall body, and improvement of the operation flexibility and the heat dissipation effect.

Description

Thermal control instrument mounting device for thermal control of power plant

Technical Field

The application relates to the technical field of thermal control instruments, in particular to a thermal control instrument mounting device for thermal control of a power plant.

Background

The temperature is one of the parameters which are common and very important in the factory production process, the temperature is measured and controlled by the thermal control instrument, and normal production operation of production work can be ensured, so that the thermal control instrument has important positions in various industries such as electric power, chemical industry, metallurgy and the like, and a thermal control instrument mounting device for thermal control of a power plant is often adopted in the mounting of the thermal control instrument in order to improve the use effect of the thermal control instrument.

The original equipment is complex in installation process when in use, and is inconvenient to use due to the fact that the equipment is slowly assembled and disassembled and is very troublesome to maintain and replace in the later period; the universal performance of the installation mechanism which cannot be changed according to the clamping range of different instruments in installation is low; and the temperature control instrument and the wall body are too close to be adjusted and maintained, so that the installation is difficult, and the heat dissipation effect is low to influence the use.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

The present application has been made in view of the above-described problems.

Therefore, the application aims to provide the thermal control instrument mounting device for the thermal control of the power plant, which has the characteristics of being convenient to mount and use, being convenient to adjust the clamping range according to different temperature control instruments, being convenient to adjust the distance between the instruments and the wall body, and improving the operation flexibility and the heat dissipation effect.

In order to solve the technical problems, the application provides the following technical scheme: the utility model provides a thermal control instrument installation device for thermal control of power plant, its includes a thermal control instrument installation device for thermal control of power plant, its characterized in that: comprising the steps of (a) a step of,

the fixing plate is fixedly arranged on the wall surface through bolts and comprises two fixing blocks arranged on one side of the fixing plate far away from the wall surface and a sliding rail arranged on the fixing blocks;

the base comprises a lifting plate parallel to the fixed plate, pin shafts arranged on two sides of the lifting plate and a base vertically connected with one end of the lifting plate; the pin shaft is matched with the sliding rail;

the clamping assembly is arranged on one side, far away from the wall surface, of the fixing plate;

and the fastening part is connected with the fixed plate in a sliding way.

As a preferable scheme of the thermal control instrument mounting device for thermal control of the power plant, the application comprises the following steps: the fixed plate further comprises a fixed rod arranged on one side of the fixed plate away from the wall surface, a mounting plate arranged on one side of the fixed plate, a first sliding groove arranged on the fixed plate, and a first spring arranged in the first sliding groove.

As a preferable scheme of the thermal control instrument mounting device for thermal control of the power plant, the application comprises the following steps: the clamping component is hinged with the fixed plate through the fixed rod; the fastening part further comprises a first sliding block arranged near one end of the fixing plate, and the first sliding block vertically moves in the first sliding groove.

As a preferable scheme of the thermal control instrument mounting device for thermal control of the power plant, the application comprises the following steps: the base is kept away from the one end of fixed plate sets up to the arc limit.

As a preferable scheme of the thermal control instrument mounting device for thermal control of the power plant, the application comprises the following steps: the fastening component comprises a moving plate, two groups of moving assemblies arranged above the moving plate, six buffer assemblies arranged on the moving assemblies, a supporting assembly arranged on the moving plate, a second sliding chute arranged on the moving plate and a second spring arranged in the second sliding chute.

As a preferable scheme of the thermal control instrument mounting device for thermal control of the power plant, the application comprises the following steps: the movable assembly comprises a support arm, a movable arm forming an acute angle with the support arm, an arc-shaped protruding block arranged at one end of the support arm far away from the movable arm, a second sliding block arranged on the movable arm and matched with the second sliding groove, and a support block arranged at one end of the movable arm far away from the support arm; the second sliding block is fixedly connected with the moving plate through a second spring; the acute angle between the movable arm and the supporting arm is matched with the arc-shaped edge; the support block is close to the one end of supporting component sets up to the arc.

As a preferable scheme of the thermal control instrument mounting device for thermal control of the power plant, the application comprises the following steps: the buffer assembly comprises a buffer sheet arranged on the movable arm, a third spring connected with the buffer sheet, and salient points arranged on the buffer sheet; the buffer sheet is arranged in an arc shape, and the height of the buffer sheet is slightly higher than that of the supporting block.

As a preferable scheme of the thermal control instrument mounting device for thermal control of the power plant, the application comprises the following steps: the support assembly comprises a connecting block fixedly arranged on the movable plate, a support plate hinged with the connecting block, and six groups of grooves arranged on one side of the support plate, which is close to the movable plate; the groove comprises an inclined edge and an arc edge.

As a preferable scheme of the thermal control instrument mounting device for thermal control of the power plant, the application comprises the following steps: the clamping component comprises a fourth spring arranged above the mounting plate, a floating block connected with the fourth spring, a connecting column arranged at one end, close to the moving plate, of the floating block, and a lever hinged with the fixing plate.

As a preferable scheme of the thermal control instrument mounting device for thermal control of the power plant, the application comprises the following steps: the lever comprises a contact in sliding contact with the floating block and a pressing plate arranged at one end of the lever far away from the floating block.

The application has the beneficial effects that: according to the application, the sliding rail is arranged on the fixed block, the base and the clamping assembly are arranged on the fixed plate, and the fastening component has the functions of being convenient to install and use, being convenient to adjust the clamping range according to different temperature control meters, being convenient to adjust the distance between the meters and the wall body, and improving the operation flexibility and the heat dissipation effect.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

FIG. 1 is a perspective view of a thermal control instrument mounting device for thermal control of a power plant.

FIG. 2 is a side view of a thermal control instrument mounting device for thermal control of a power plant.

Fig. 3 is a front view of a thermal control instrument mounting device for thermal control of a power plant.

Fig. 4 is a front view of the first chute of the thermal control instrument mounting device for thermal control of a power plant.

Fig. 5 is a perspective view of a moving assembly of a thermal control instrument mounting device for thermal control of a power plant.

FIG. 6 is a side view of a mobile assembly of a thermal control instrument mounting device for thermal control of a power plant.

FIG. 7 is a perspective view of a buffer assembly of a thermal control instrument mounting device for thermal control of a power plant.

FIG. 8 is a perspective view of a support assembly of a thermal control instrument mounting device for thermal control of a power plant.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, but the present application may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present application is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the application. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 to 3, in a first embodiment of the present application, a thermal control instrument installation apparatus for thermal control of a power plant is provided, which includes a fixing plate installed on a wall, and a base, a clamping assembly and a fastening member installed on the fixing plate, so that the thermal control instrument is more convenient to install and detach, stability is increased, a flowing space of air is increased, a heat dissipation effect is improved, and a service life of a device is prolonged.

Specifically, the fixing plate 100 is fixedly arranged on the wall surface through bolts, and the fixing plate 100 comprises a fixing block 101 arranged on one side of the fixing plate far away from the wall surface and a sliding rail 102 arranged on the fixing block 101;

the base 200 comprises a lifting plate 201 parallel to the fixed plate 100, pin shafts 202 arranged on two sides of the lifting plate 201, and a base 203 vertically connected with one end of the lifting plate 201; the pin 202 is matched with the sliding rail 102;

the clamping assembly 300 is arranged on one side of the fixed plate 100 away from the wall surface;

the fastening member 400 is slidably coupled to the fixing plate 100.

It should be noted that, the fixing plate 100 is fixedly connected with the wall, the fixing plate 100 is close to the wall, the fixing plate 100 is arranged at a position close to the upper side of the fixing block 101, the fixing plate 100 and the fixing block 101 can be integrally formed or welded, the fixing block 101 is arranged into two blocks, the fixing block 101 is internally provided with the sliding rail 102, the sliding rail 102 is arc-shaped, and the path is that the sliding rail 102 is mutually matched with the pin shafts 202 at two sides of the lifting plate 201 from the outside to the lower side. The pin 202 extends through the sliding rail 102 and is movable within the sliding rail 102. The pin 202 serves as a fixed and guide to move the base 200 further outward and downward. The base 200 is used for placing the thermal control instrument, wherein the width of the lifting plate 201 is set to be smaller, so that when the base 200 moves outwards and downwards along with the sliding rail 102, the thermal control instrument is far away from the fixed plate 100 and the wall, thereby playing a role of heat dissipation and keeping a certain distance from the wall and the fixed plate 100, which is equal to increasing the operation space, so that later maintenance and detection are facilitated. The lifting plate 201 may be a hollowed plate, so that heat dissipation of the thermal control instrument is facilitated.

Preferably, the clamping component is mainly arranged on one side of the fixing plate 100 away from the wall body, and plays a role in clamping two sides of the thermal control instrument, so that the stability of the thermal control instrument is improved, and the clamping component is also arranged in the fastening component 400, so that the stability of the thermal control instrument is further improved due to the fact that the clamping component is used for clamping the bottom of the thermal control instrument.

When in use, when a worker slowly places the thermal control instrument on the base 203 of the base 200, the thermal control instrument is abutted against the lifting plate 201, the pins 202 on two sides of the lifting plate 201 slide in the sliding rails 102 on the fixed plate 100, and the whole base 200 slides outwards and downwards in the sliding process to a certain extent, so that the thermal control instrument is clamped by the fastening component 400 contacted with the lower part at the moment, and the clamping components 300 on two sides clamp the thermal control instrument, so that the fastening function on the thermal control instrument is realized.

In summary, through setting up fixed plate 100 and setting up fixed block 101 on fixed plate 100 for the round pin axle 202 on the base 200 cooperatees with the slide rail 102 on the fixed block 101 and leaves the space before messenger's thermal control instrument and the wall body and be convenient for install, dismantle, detect and maintain, and can play ventilation and heat dissipation's effect, improve thermal control instrument's life, set up clamping assembly 300 and fastening part 400 can make thermal control instrument more stable.

Example 2

Referring to fig. 1, a second embodiment of the present application is shown, which is different from the first embodiment in that: the thermal control instrument further comprises a supporting component 404, a buffering component 403, a moving component 402, a floating block 302 and a contact 304a, so that the clamping range of the thermal control instrument can be adjusted according to self gravity, the thermal control instrument can be adjusted according to instrument instruments with different sizes, and clamping and fastening of the thermal control instrument by utilizing the self gravity are realized. In the above embodiment, the thermal control instrument mounting device for thermal control of a power plant comprises a fixing plate 100, wherein the fixing plate 100 is fixedly arranged on a wall surface through bolts, and the fixing plate 100 comprises two fixing blocks 101 arranged on one side of the fixing plate far away from the wall surface, and a sliding rail 102 arranged on the fixing blocks 101; the base 200 comprises a lifting plate 201 parallel to the fixed plate 100, pin shafts 202 arranged on two sides of the lifting plate 201, and a base 203 vertically connected with one end of the lifting plate 201; the pin 202 is matched with the sliding rail 102; the clamping assembly 300 is arranged on one side of the fixed plate 100 away from the wall surface; the fastening member 400 is slidably coupled to the fixing plate 100.

Further, the fixing plate 100 further includes a fixing rod 103 disposed on a side thereof away from the wall surface, a mounting plate 104 disposed on a side of the fixing plate 100, a first sliding slot 105 disposed on the fixing plate 100, and a first spring 106 disposed in the first sliding slot 105.

Further, the clamping member 300 is hinged to the fixing plate 100 through the fixing lever 103; the fastening part 400 further includes a first slider disposed near one end of the fixing plate 100, and the first slider moves vertically in the first sliding groove 105.

Further, an end of the base 203 remote from the fixing plate 100 is provided as an arc-shaped edge 203a.

Further, the fastening part 400 includes a moving plate 401, two sets of moving components 402 disposed above the moving plate 401, six buffer components 403 disposed on the moving components 402, a support component 404 disposed on the moving plate 401, a second sliding slot 405 disposed on the moving plate 401, and a second spring 406 disposed in the second sliding slot 405.

It should be noted that, the moving plate 401 is disposed in parallel below the base 203 of the base 200, two sets of moving assemblies 402 are disposed on two sides of the moving plate 401, six buffer assemblies 403 are disposed on each moving assembly 402, and two sets of supporting assemblies 404 are disposed on the moving plate 401, and the supporting assemblies 404 and the moving assemblies 403 are mutually matched. The movable assembly 402 is connected with the fixed plate 100 in a sliding manner, a first chute 105 is formed in the fixed plate 100, a first spring 106 is arranged in the first chute 105, and two ends of the first spring 106 are connected with the fixed plate 100 and the first sliding block. The first slider is disposed at one end of the moving plate 401 near the fixed plate 100. The movable plate 401 can slide freely on the fixed plate 100, because the base 200 moves downwards due to the gravity of the thermal control instrument, the movable plate 401 is pressed when the base 200 moves downwards, the first sliding block on the movable plate 401 slides downwards in the first sliding groove 105 on the fixed plate 100, at this time, the movable plate 401 moves vertically downwards, and when the thermal control instrument is taken down, the movable plate 401 slides upwards under the action of the first spring 106 until the thermal control instrument returns to the original position.

Further, the moving assembly 402 includes a supporting arm 402a, a moving arm 402b forming a acute angle with the supporting arm 402a, an arc-shaped projection 402c disposed at an end of the supporting arm 402a away from the moving arm 402b, a second sliding block 402d disposed at an end of the moving arm 402b away from the supporting arm 402a and matched with the second sliding groove 405, and a supporting block 402e disposed at an end of the moving arm 402b away from the supporting arm 402 a; the second sliding block is fixedly connected with the moving plate 402 through a second spring 406; the acute angle between the moving arm 402b and the support arm 402a is matched with the arc-shaped edge 203 a; the end of the support block 402e adjacent to the support assembly 404 is disposed in an arc shape.

It should be noted that, the angle formed between the supporting arm 402a and the moving arm 402b is an acute angle, and the supporting arm 402a is used for fastening the thermal control instrument, one end of the supporting arm 402a, which contacts the thermal control instrument, is provided with an arc-shaped protruding block 402c, the arc-shaped protruding block 402c is used for touching the edge of the arc-shaped protruding block 402c by the base 203 when the base 200 moves downward under the action of gravity, the arc-shaped protruding block 402c is extruded when the base 203 moves continuously, and the arc-shaped protruding block 402c is used for giving the moving arm 402b a certain distance. When the moving arm 402b moves outward, the second slider slides outward in the second chute 405, and the second spring 406 connected to the moving plate 402 of the second slider receives an outward pulling force. When the bottom surface of the base 203 of the base 200 contacts with the moving arm 402b during the downward movement, the moving arm 402b forms an acute angle with the supporting arm 402a to contact and adapt to the arc edge 203a of the base 203, at this time, one end of the arc-shaped protruding block 402c of the supporting arm 402a contacts with the thermal control instrument and makes the arc-shaped protruding block 402c fasten the thermal control instrument more under the action of the tension of the second spring.

Further, the buffer assembly 403 includes a buffer piece 403a disposed on the moving arm 402b, a third spring 403b connected to the buffer piece 403a, and a bump 403c disposed on the buffer piece 403 a; the buffer piece 403a is provided in an arc shape, and the height of the buffer piece 403a is slightly higher than the height of the supporting block 402 e.

Further, the support assembly 404 includes a connection block 404a fixedly disposed on the moving plate 401, a support plate 404b hinged to the connection block 404a, and six sets of grooves 404c disposed on one side of the support plate 404b close to the moving plate 401; the groove 404c includes a slanted edge and an arcuate edge.

It should be noted that, when the edge of the base 203 of the base 200 contacts the arc-shaped protrusion 402 of the supporting arm 402, the supporting arm 402 is pressed, so that the moving arm 402b moves outwards. In a normal state, the movable arm 402b is provided with the supporting block 402e, and the supporting plate 404b is placed on the supporting block 402e of the movable arm 402b, so when the movable arm 402b moves, the supporting block 402e will move outwards, because one end of the supporting plate 404b away from the movable arm 402b is hinged with the connecting block 404a, at this time, the movable arm 402b placed on the supporting block 402e will be affected by gravity, and one end close to the movable arm 402b tilts downwards and is blocked at the lower end of the supporting block 402 e. At this time, the moving arm 402b is stopped after moving outward, and is not rebounded by the tension of the second spring 406. The function is that when the base 203 descends, the arc-shaped projection 402 of the support arm 402 always presses the thermal control instrument under the influence of the tension of the second spring 406 when the movable arm 402b moves outwards, and finally descends to a proper position, the support arm 402 may damage the thermal control instrument in the pressing process, and the support plate 404b abuts against the bottom of the support block 402e, so that the movable arm 402b cannot rebound.

Preferably, when the base 203 of the base 200 continues to move downward, the other end of the supporting plate 404b is tilted up due to gravity to the bottom of the supporting block 402 e. Therefore, when the base 203 moves downward, it presses to the tilted end, the support plate 404b will be parallel to the support block 402e, and at this time, under the action of the second spring 406, the moving arm 402b will return, so that the support arm 402a locks the thermal control instrument, and the fastening effect is achieved. The support plate 404b is now placed in parallel above the support blocks 402 e.

Preferably, the moving arm 402b is further provided with a buffer assembly 403, the buffer plate 403a is provided with an arc shape, and the side of the support plate 404b, which is close to the moving plate 401, is provided with six groups of grooves 404c matched with the buffer plate 403 a. When the support plate 404b is pressed against the support block 402e, the buffer sheet 403a is in the groove 404c, and when the moving arm 402b moves, the groove 404c of the support plate 404b contacts the buffer sheet 403a, and the groove 404c is provided with a diagonal side and an arc side. One side close to the supporting arm 402 is set to be an oblique side, the other side is set to be an arc side, when the moving arm 402b moves outwards under the action of the base 200, the motion track of the supporting plate 404b is that the oblique side is contacted with the buffer plate 403a, and the moving arm 402b is easy to move outwards due to the fact that the oblique side is set to be the oblique side, when the moving arm 402b is parallel to the supporting plate 404b under the action of the base 200, the moving arm 402b is retracted under the action of the second spring 406, because the height of the buffer plate 403a is slightly higher than that of the supporting block 402e, the side of the buffer plate 403a firstly contacts the side of the supporting plate 404b to play a buffering role, then the salient point 403c of the buffer plate 403a contacts the side of the supporting plate 404b again to play a buffering role, and the side contacted by the groove 404c when the moving arm 402b retracts is set to be the arc side, then the buffer plate 403a enters the groove 404c again to buffer, and the friction force is increased. Therefore, the movable arm 402b can be retracted slowly when being retracted under the action of the second spring 406, so that the support arm 402a can be contacted with the thermal control instrument slowly without damaging the instrument.

Further, the holding member 300 includes a fourth spring 301 provided above the mounting plate 104, a slider 302 connected to the fourth spring 301, a connecting post 303 provided at an end of the slider 302 near the moving plate 401, and a lever 304 hinged to the fixed plate 100.

Further, the lever 304 includes a contact 304a in sliding contact with the slider 302, and a pressing plate 304b provided at an end of the lever 304 remote from the slider 302.

It should be noted that, the fourth spring 301 connects the mounting plate with the slider 302, the connecting post 303 is disposed above the slider 302, the moving plate 401 is disposed above the connecting post 303, levers 304 are disposed on two sides of the slider 302, one end of each lever 304, which is close to the slider 302, is provided with a contact 304a, the contact 304a is in sliding contact with the slider 302, the other end of each lever 304 is provided with a pressing plate 304b, when the moving plate 401 moves downward under the self gravity condition of the thermal control instrument, the slider 302 is pressed, the slider 302 moves downward, and the inclined edge of the slider 302 is pressed against the contact 304a, because the levers 304 are hinged with the fixed plate 100, two ends of the pressing plate 304b of each lever 304 are pressed against the thermal control instrument in the pressing process.

When the thermal control instrument is used, a worker places the thermal control instrument on the base 200, the thermal control instrument utilizes self gravity to enable the base 200 to firstly move outwards and downwards under the guide of the sliding rail, when the base 200 descends to the moving plate 401, the supporting arm 402a is extruded, the thermal control instrument falls into the fastening part 400, under the action of the second spring 406, the buffer component 403 and the supporting component 404, the supporting arm 402a slowly retracts, the thermal control instrument is clamped, at the moment, the thermal control instrument moves downwards by utilizing self gravity, the moving plate 401 is pressed to the connecting column 303 and the floating block 302, the floating block 302 extrudes the lever 304, the pressing plates 304b on the lever 304 compress two sides of the thermal control instrument, the fastening effect is achieved, and the clamping range can be adjusted according to the self size.

To sum up, this embodiment utilizes the self gravity of thermal control instrument to be applicable to not unidimensional instrument to can utilize self gravity to make thermal control instrument reach the effect of fastening and stability, and be convenient for adjust the interval between instrument and the wall body and improve the characteristics of flexibility of operation and radiating effect.

It is important to note that the construction and arrangement of the application as shown in the various exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present application. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present applications. Therefore, the application is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in order to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the application, or those not associated with practicing the application).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be noted that the above embodiments are only for illustrating the technical solution of the present application and not for limiting the same, and although the present application has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present application may be modified or substituted without departing from the spirit and scope of the technical solution of the present application, which is intended to be covered in the scope of the claims of the present application.

Claims (2)

1. The utility model provides a thermal control instrument installation device for thermal control of power plant which characterized in that: comprising the steps of (a) a step of,

the fixing plate (100), the fixing plate (100) is fixedly arranged on a wall surface through bolts, the fixing plate (100) comprises two fixing blocks (101) arranged on one side of the fixing block far away from the wall surface, and a sliding rail (102) arranged on the fixing blocks (101); the base (200) comprises a lifting plate (201) parallel to the fixed plate (100), pin shafts (202) arranged on two sides of the lifting plate (201), and a base (203) vertically connected with one end of the lifting plate (201); the pin shaft (202) is matched with the sliding rail (102);

the clamping assembly (300) is arranged on one side, far away from the wall surface, of the fixing plate (100);

a fastening member (400) slidably connected to the fixing plate (100);

the fixing plate (100) further comprises a fixing rod (103) arranged on one side of the fixing plate far away from the wall surface, a mounting plate (104) arranged on one side of the fixing plate (100), a first sliding groove (105) arranged on the fixing plate (100), and a first spring (106) arranged in the first sliding groove (105);

the clamping assembly (300) is hinged with the fixed plate (100) through the fixed rod (103); the fastening part (400) further comprises a first sliding block arranged near one end of the fixed plate (100), and the first sliding block vertically moves in the first sliding groove (105);

one end of the base (203) far away from the fixed plate (100) is provided with an arc-shaped edge (203 a);

the fastening component (400) comprises a moving plate (401), two groups of moving assemblies (402) arranged above the moving plate (401), six buffer assemblies (403) arranged on the moving assemblies (402), a supporting assembly (404) arranged on the moving plate (401), a second sliding chute (405) arranged on the moving plate (401), and a second spring (406) arranged in the second sliding chute (405);

the moving assembly (402) comprises a supporting arm (402 a), a moving arm (402 b) forming an acute angle with the supporting arm (402 a), an arc-shaped protruding block (402 c) arranged at one end of the supporting arm (402 a) far away from the moving arm (402 b), a second sliding block (402 d) arranged on the moving arm (402 b) and matched with the second sliding groove (405), and a supporting block (402 e) arranged at one end of the moving arm (402 b) far away from the supporting arm (402 a); the second sliding block (402 d) is fixedly connected with the moving plate (401) through a second spring (406); -the acute angle between the moving arm (402 b) and the supporting arm (402 a) is adapted to the arcuate edge (203 a); one end of the supporting block (402 e) close to the supporting component (404) is arranged in an arc shape;

the buffer assembly (403) comprises a buffer sheet (403 a) arranged on the moving arm (402 b), a third spring (403 b) connected with the buffer sheet (403 a), and a bump (403 c) arranged on the buffer sheet (403 a); the buffer sheet (403 a) is arranged in an arc shape, and the height of the buffer sheet (403 a) is slightly higher than the height of the supporting block (402 e);

the support assembly (404) comprises a connecting block (404 a) fixedly arranged on the movable plate (401), and a support plate (404 b) hinged with the connecting block (404 a), and six groups of grooves (404 c) arranged on one side, close to the movable plate (401), of the support plate (404 b); the groove (404 c) comprises an inclined edge and an arc edge and is matched with the buffer sheet (403 a);

the clamping assembly (300) comprises a fourth spring (301) arranged above the mounting plate (104), a floating block (302) connected with the fourth spring (301), a connecting column (303) arranged at one end of the floating block (302), and a lever (304) hinged with the fixing plate (100).

2. The thermal control instrument mounting apparatus for thermal control of a power plant according to claim 1, wherein: the lever (304) includes a contact (304 a) in sliding contact with the slider (302), and a pressing plate (304 b) provided at an end of the lever (304) remote from the slider (302).