CN220647681U - Mounting structure of thermal control instrument of power plant - Google Patents

Abstract

The utility model relates to a mounting structure of thermal control instrument of power plant, this mounting structure includes base, slewing mechanism, fixed case and elevating system, and fixed case is used for placing thermal control instrument, and elevating system is connected and can drive fixed case and remove along first direction with fixed case, and slewing mechanism sets up in the base and is connected with elevating system, and slewing mechanism can drive elevating system and fixed case and rotate around the axis that extends along first direction. Because the rotating mechanism can drive the lifting mechanism and the fixed box to rotate around the axis extending along the first direction, the rotating mechanism can adjust the placement direction of the thermal control instrument in the fixed box, and the use requirements of the thermal control instrument in different directions are met. The setting of elevating system can drive thermal control instrument and remove in first direction to adjust thermal control instrument in the ascending different heights of placing of first direction, in order to adapt to the user demand of different height operating personnel or not high apparatus.

Description

Mounting structure of thermal control instrument of power plant

Technical Field

The disclosure relates to the technical field of thermal control instrument installation, in particular to an installation structure of a thermal control instrument of a power plant.

Background

In the document of patent publication No. CN217329138U, a mounting structure of a thermal control instrument of a thermal power plant is disclosed, which proposes that, in the mounting process of the existing thermal control instrument, since most of the existing thermal control instrument is fixedly mounted beside a large instrument, and the large instrument needs to be inspected around in the use process, the direction of the thermal control instrument cannot be rotationally adjusted during inspection, which results in that the numerical value on the thermal control instrument cannot be observed in time and the thermal control instrument is operated to control the large instrument, but the following defects still exist in the practical application process:

in the above-mentioned patent, through the setting of carousel, pivot and bracing piece for the casing can be to the rotatory regulation direction use of thermal control instrument main part, when the inspection work, the staff of being convenient for adjusts the position of thermal control instrument main part and controls and use and observe the numerical value, but this a high fixed for thermal control instrument main part strutting arrangement, it can not carry out corresponding high regulation according to the operating personnel of different heights or not high apparatus, so that operating personnel need carry out operations such as bending over or bending over of great degree when watching the numerical value of thermal control instrument main part department, influences the convenience of watching.

Disclosure of Invention

The utility model aims at providing a mounting structure of thermal control instrument of power plant, this mounting structure of thermal control instrument of power plant can solve the technical problem that exists among the related art.

In order to achieve the above-mentioned purpose, the present disclosure provides a mounting structure of thermal control instrument of power plant, mounting structure includes base, slewing mechanism, fixed case and elevating system, fixed case is used for placing thermal control instrument, elevating system with fixed case is connected and can drive fixed case moves along first direction, slewing mechanism set up in the base and with elevating system connects, just slewing mechanism can drive elevating system with fixed case rotates around following the axis that first direction extends.

Optionally, the lifting mechanism includes a sleeve, a moving rod and a first driving part, the sleeve extends along the first direction and is connected to the rotating mechanism, the moving rod is connected to the fixed box and is movably arranged in the sleeve along the first direction, and the first driving part is used for driving the moving rod to move along the first direction.

Optionally, the sleeve is formed with a avoidance groove along the first direction, the moving rod includes a moving rod body and a connecting part that are connected with each other, the moving rod body extends along the first direction and is movably arranged on the sleeve, and the moving rod body is connected with the fixed box; the connecting portion passes through the avoidance groove and penetrates out of the sleeve to be connected with the first driving portion, and the connecting portion movably penetrates through the avoidance groove along the first direction.

Optionally, the first driving portion includes two fixing plates and a driving screw, the two fixing plates are connected to the sleeve and are respectively disposed at two ends of the avoidance groove along the first direction, the driving screw extends along the first direction and is disposed opposite to the avoidance groove, and the driving screw is axially locked and circumferentially rotatably disposed between the two fixing plates;

the connecting portion is constructed as the connecting plate, be formed with the screw hole on the connecting plate, drive screw wears to establish the screw hole and forms screw-thread fit.

Optionally, the mounting structure further includes a plurality of telescopic rods, a plurality of telescopic rods are all arranged in the rotating mechanism in a telescopic manner along the first direction, and the telescopic rods are connected with the fixed box.

Optionally, a positioning box with an opening is arranged in the fixing box, and the positioning box is used for inserting a heat supply control instrument;

the installation structure of the power plant thermal control instrument further comprises a locking piece, wherein the locking piece is movably arranged in the positioning box and provided with a first position and a second position, and the locking piece can be used for limiting the thermal control instrument in the positioning box in the first position; in the second position, the locking member can be used to release the thermal control instrument from its limit.

Optionally, the locking piece includes end baffle, fixing bolt and fixation nut, the fixing bolt fixed set up in the locating box, just fixing bolt set up in the opening part of locating box, end baffle rotationally overlaps to locate fixing bolt, the fixation nut cover is located fixing bolt can be right end baffle's rotation position is fixed.

Optionally, the mounting structure further comprises an air charging tube and a plurality of buffer air bags, the outer wall of the positioning box and the inner wall of the fixing box define a buffer cavity, the buffer air bags are arranged in the buffer cavity, one end of the air charging tube is arranged in the buffer cavity and communicated with the buffer air bags, and the other end of the air charging tube penetrates out of the fixing box.

Optionally, the rotating mechanism includes a base and a rotating disc, the rotating disc is rotatably disposed on the base along an axis extending along the first direction, and the rotating disc is connected with the lifting mechanism.

Optionally, the rotating mechanism further comprises a driving motor, and the driving motor is arranged on the base and is used for driving the rotating disc to rotate.

In the above technical scheme, because the rotating mechanism can drive the lifting mechanism and the fixed box to rotate around the axis extending along the first direction, the rotating mechanism can adjust the placement direction of the thermal control instrument in the fixed box, and the use requirements of the thermal control instrument in different directions are met. The setting of elevating system can drive thermal control instrument and remove in first direction to adjust thermal control instrument in the ascending different heights of placing of first direction, in order to adapt to the user demand of different height operating personnel or not high apparatus.

Additional features and advantages of the present disclosure will be set forth in the detailed description which follows.

Drawings

The accompanying drawings are included to provide a further understanding of the disclosure, and are incorporated in and constitute a part of this specification, illustrate the disclosure and together with the description serve to explain, but do not limit the disclosure. In the drawings:

FIG. 1 is a schematic view of a mounting structure of a thermal control instrument of a power plant according to an embodiment of the present disclosure, and the thermal control instrument is illustrated in the figure.

Fig. 2 and 3 are partial structural schematic views of a mounting structure of a thermal control instrument of a power plant according to an embodiment of the present disclosure.

Fig. 4 is a partial enlarged view at H in fig. 1.

Description of the reference numerals

1. A base; 101. a rotating disc; 102. a sleeve; 103. a driving motor; 2. a fixed box; 201. a positioning box; 202. a buffer air bag; 203. an inflation tube; 3. a thermal control instrument; 4. a lifting mechanism; 401. a moving rod; 4011. a moving rod body; 402. a fixing plate; 403. driving a screw; 404. a connection part; 4041. a threaded hole; 405. an avoidance groove; 406. a lock nut; 5. a telescopic rod; 6. a locking member; 601. a stop plate; 602. a fixing nut; 603. and (5) fixing bolts.

Detailed Description

Specific embodiments of the present disclosure are described in detail below with reference to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating and illustrating the disclosure, are not intended to limit the disclosure.

Referring to fig. 1 to 4, the present disclosure provides a mounting structure of a thermal control instrument of a power plant, the mounting structure including a base 1, a rotating mechanism, a fixed box 2, and a lifting mechanism 4, the fixed box 2 is used for placing the thermal control instrument 3, the lifting mechanism 4 is connected with the fixed box 2 and can drive the fixed box 2 to move along a first direction a, the rotating mechanism is disposed on the base 1 and connected with the lifting mechanism 4, and the rotating mechanism can drive the lifting mechanism 4 and the fixed box 2 to rotate around an axis extending along the first direction a.

In the above technical scheme, because the rotating mechanism can drive the lifting mechanism 4 and the fixed box 2 to rotate around the axis extending along the first direction A, the rotating mechanism can adjust the placement direction of the thermal control instrument 3 in the fixed box 2, thereby meeting the use requirements of the thermal control instrument 3 in different directions. The setting of elevating system 4 can drive thermal control instrument 3 to remove in first direction A to adjust thermal control instrument 3 the different heights of placing in first direction A, in order to adapt to the user demand of different height operating personnel or different high apparatuses.

In one embodiment, referring to fig. 2 and 3, the lifting mechanism 4 includes a sleeve 102, a moving rod 401, and a first driving portion, where the sleeve 102 extends along a first direction a and is connected to the rotating mechanism, the moving rod 401 is connected to the fixed case 2 and is movably disposed in the sleeve 102 along the first direction a, and the first driving portion is used to drive the moving rod 401 to move along the first direction a, so as to drive the thermal control instrument 3 in the fixed case 2 to move in the first direction a, so as to achieve the purpose of height adjustment. The sleeve 102 may be provided to provide a good guide. In addition, the first driving portion may be configured as any suitable driving structure, which is not limited in this disclosure.

Referring to fig. 2 and 3, the sleeve 102 is formed with a relief groove 405 along a first direction a, the movable rod 401 includes a movable rod body 4011 and a connecting portion 404 that are connected to each other, the movable rod body 4011 extends along the first direction a and is movably provided to the sleeve 102, and the movable rod body 4011 is connected to the stationary box 2; the connection portion 404 is penetrated out of the sleeve 102 through the escape groove 405 to be connected with the first driving portion, and the connection portion 404 is movably penetrated through the escape groove 405 along the first direction a. The avoidance groove 405 is convenient for realizing connection between the first driving part and the moving rod 401, and in addition, the stability of the moving rod 401 moving along the second direction B can be better improved through the cooperation design of the connecting part 404 and the avoidance groove 405.

For example, referring to fig. 2 and 3, the first driving portion includes two fixing plates 402 and a driving screw 403, the two fixing plates 402 are connected to the sleeve 102 and are respectively disposed at two ends of the avoidance groove 405 along the first direction a, the driving screw 403 extends along the first direction a and is disposed opposite to the avoidance groove 405, and the driving screw 403 is axially locked and is circumferentially rotatably disposed between the two fixing plates 402; the connection portion 404 is configured as a connection plate on which a threaded hole 4041 is formed, and the drive screw 403 is threaded through the threaded hole 4041 and forms a threaded fit. By rotating the driving screw 403, the connecting plate can be driven to move along the first direction a, that is, the moving rod 401 can be driven to move in the first direction a, so that the thermal control instrument 3 in the fixed box 2 is driven to move in the first direction a. In addition, the first driving part may further include a locking nut 406 sleeved on the driving screw 403 to prevent the driving screw 403 from being separated from the fixing plate 402.

Alternatively, referring to fig. 1 and 2, the mounting structure further includes a plurality of telescopic rods 5, each of the plurality of telescopic rods 5 is telescopically disposed in the rotation mechanism along the first direction a, and the telescopic rods 5 are connected with the stationary box 2. Through setting up a plurality of telescopic links 5, can play good supporting role to fixed case 2, guarantee the stability of fixed case 2, avoid fixed case 2 to take place to rock.

In other embodiments, referring to fig. 1 and 4, a positioning box 201 with an opening is provided inside a fixed box 2, and the positioning box 201 is used for inserting a heat control instrument 3; the installation structure of the thermal control instrument of the power plant further comprises a locking piece 6, wherein the locking piece 6 is movably arranged in the positioning box 201 and provided with a first position and a second position, and the locking piece 6 can be used for limiting the thermal control instrument 3 in the positioning box 201 in the first position; in the second position, the locking element 6 can be used to release the limit of the thermal control instrument 3. By providing the locking member 6, the firmness of the thermal control instrument 3 in the positioning box 201 can be effectively ensured, and the thermal control instrument 3 is prevented from falling off from the positioning box 201. The locking member 6 may be configured in any suitable shape and configuration, which is not limited by the present disclosure.

For example, referring to fig. 4, the locking member 6 includes a stopper plate 601, a fixing nut 602, and a fixing bolt 603, the fixing bolt 603 is fixedly disposed on the positioning box 201, the fixing bolt 603 is disposed at an opening of the positioning box 201, the stopper plate 601 is rotatably sleeved on the fixing bolt 603, and the fixing nut 602 is sleeved on the fixing bolt 603 and can fix a rotation position of the stopper plate 601. After the thermal control instrument 3 is inserted into the positioning box 201, the stop plate 601 can be abutted against the thermal control instrument 3 by rotating the stop plate 601, and then the fixing nut 602 is rotated to fix the rotating position of the stop plate 601, so that the thermal control instrument 3 is limited to fall off through an opening at the positioning box 201. The locking member 6 is simple in structure and convenient for an operator to operate.

Referring to fig. 1, the mounting structure further includes an air tube 203 and a plurality of cushion air bags 202, the outer wall of the positioning box 201 and the inner wall of the fixing box 2 define a cushion chamber, the cushion air bags 202 are disposed in the cushion chamber, one end of the air tube 203 is disposed in the cushion chamber and is communicated with the cushion air bags 202, and the other end of the air tube 203 penetrates out of the fixing box 2. The cushion air bags 202 are filled with the protective gas through the gas filling pipe 203, so that the plurality of cushion air bags 202 can effectively protect the thermal control instrument 3 in the positioning box 201.

Alternatively, referring to fig. 3, the rotating mechanism includes a base 1 and a rotating disc 101, the rotating disc 101 is rotatably provided to the base 1 about an axis extending in a first direction a, and the rotating disc 101 is connected to the elevating mechanism 4. The rotating mechanism is simple in structure and convenient to process and manufacture. In addition, the rotating mechanism further comprises a driving motor 103, and the driving motor 103 is arranged on the base 1 and used for driving the rotating disc 101 to rotate, so that the degree of automation is improved.

The preferred embodiments of the present disclosure have been described in detail above with reference to the accompanying drawings, but the present disclosure is not limited to the specific details of the above embodiments, and various simple modifications may be made to the technical solutions of the present disclosure within the scope of the technical concept of the present disclosure, and all the simple modifications belong to the protection scope of the present disclosure.

In addition, the specific features described in the foregoing embodiments may be combined in any suitable manner, and in order to avoid unnecessary repetition, the present disclosure does not further describe various possible combinations.

Moreover, any combination between the various embodiments of the present disclosure is possible as long as it does not depart from the spirit of the present disclosure, which should also be construed as the disclosure of the present disclosure.

Claims (10)

1. The utility model provides a mounting structure of thermal control instrument of power plant, its characterized in that, mounting structure includes base, slewing mechanism, fixed case and elevating system, fixed case is used for placing thermal control instrument, elevating system with fixed case is connected and can drive fixed case removes along first direction, slewing mechanism set up in the base and with elevating system connects, just slewing mechanism can drive elevating system with fixed case is around following the axis rotation that first direction extends.

2. The mounting structure of a thermal control instrument of a power plant according to claim 1, wherein the lifting mechanism includes a sleeve extending in the first direction and connected to the rotating mechanism, a moving lever connected to the stationary box and movably disposed in the sleeve in the first direction, and a first driving portion for driving the moving lever to move in the first direction.

3. The mounting structure of a thermal control instrument of a power plant according to claim 2, wherein the sleeve is formed with a avoidance groove along the first direction, the moving rod includes a moving rod body and a connecting portion that are connected to each other, the moving rod body extends along the first direction and is movably provided to the sleeve, and the moving rod body is connected to the fixed box; the connecting portion passes through the avoidance groove and penetrates out of the sleeve to be connected with the first driving portion, and the connecting portion movably penetrates through the avoidance groove along the first direction.

4. The mounting structure of a thermal control instrument of a power plant according to claim 3, wherein the first driving part comprises two fixing plates and a driving screw, the two fixing plates are connected to the sleeve and are respectively arranged at two ends of the avoidance groove along the first direction, the driving screw extends along the first direction and is arranged opposite to the avoidance groove, and the driving screw is axially locked and circumferentially rotatably arranged between the two fixing plates;

the connecting portion is constructed as the connecting plate, be formed with the screw hole on the connecting plate, drive screw wears to establish the screw hole and forms screw-thread fit.

5. The mounting structure of a thermal control instrument of a power plant according to claim 2, further comprising a plurality of telescopic rods, wherein the plurality of telescopic rods are all telescopically arranged in the rotating mechanism along the first direction, and the telescopic rods are connected with the fixed box.

6. The installation structure of a thermal control instrument of a power plant according to claim 1, wherein a positioning box with an opening is arranged inside the fixed box, and the positioning box is used for inserting the thermal control instrument;

the installation structure of the power plant thermal control instrument further comprises a locking piece, wherein the locking piece is movably arranged in the positioning box and provided with a first position and a second position, and the locking piece can be used for limiting the thermal control instrument in the positioning box in the first position; in the second position, the locking member can be used to release the thermal control instrument from its limit.

7. The mounting structure of a thermal control instrument for a power plant according to claim 6, wherein the locking member comprises a stop plate, a fixing nut and a fixing bolt, the fixing bolt is fixedly arranged at the positioning box, the fixing bolt is arranged at an opening of the positioning box, the stop plate is rotatably sleeved on the fixing bolt, and the fixing nut is sleeved on the fixing bolt and can fix the rotating position of the stop plate.

8. The mounting structure of a thermal control instrument of a power plant according to claim 6, further comprising an air charging tube and a plurality of buffer air bags, wherein the outer wall of the positioning box and the inner wall of the fixing box define a buffer cavity, the buffer air bags are arranged in the buffer cavity, one end of the air charging tube is arranged in the buffer cavity and communicated with the buffer air bags, and the other end of the air charging tube penetrates out of the fixing box.

9. The mounting structure of a thermal control instrument of a power plant according to claim 1, wherein the rotating mechanism includes a base and a rotating disc rotatably provided to the base along an axis extending in the first direction, the rotating disc being connected to the elevating mechanism.

10. The mounting structure of a thermal control instrument for a power plant according to claim 9, wherein the rotating mechanism further comprises a driving motor provided to the base and configured to drive the rotating disk to rotate.