CN220568695U - Heat-resistant temperature measuring device for nano ceramic coating - Google Patents

Abstract

The utility model provides a heat-resistant temperature measuring device for a nano ceramic coating. The device comprises a base, wherein an installation groove is formed in the middle of the base, a bidirectional screw rod is rotationally connected to the installation groove, two moving blocks are connected to the bidirectional screw rod in a threaded manner, clamping plates are fixedly connected to the top surfaces of the two moving blocks, a fixing frame is fixedly connected to the top of the base, a sliding groove is formed in the inner side of the fixing frame, a support plate is inserted into the sliding groove, sliding blocks are fixedly connected to the two ends of the support plate, and balls are embedded into the top surface and the bottom surface of each sliding block; the middle part of extension board is provided with electric putter, the terminal fixedly connected with regulation and control box of piston rod of electric putter, regulation and control box swivelling joint has the gear, the top surface and the bottom surface of gear all are provided with the installation pole, the bottom of installation pole is provided with the hot plate. The utility model has the advantages that: the two mounting rods synchronously move on the coating, so that the operation process is simpler and more convenient, and the detection efficiency is greatly improved.

Description

Heat-resistant temperature measuring device for nano ceramic coating

Technical Field

The utility model relates to the technical field of nano ceramic coatings, in particular to a heat-resistant temperature measuring device for a nano ceramic coating.

Background

The nano ceramic powder coating has excellent heat insulation effect in a high-temperature environment, does not fall off or burn, is waterproof and dampproof, and has no toxicity and no pollution to the environment. The nano ceramic coating is a coating prepared by using nano ceramic powder coating, and has the advantages of the nano ceramic coating.

If authorize a ceramic coating's high temperature resistant wear-resisting check out test set of bulletin number CN215953267U, through setting up adjusting part, can pass through second spout adjustment side pipe position when detecting, through promoting the sliding sleeve adjustment and detect the subassembly position, and then can adjust the horizontal plane position that detects the subassembly, be convenient for detect the different positions on work piece surface, guaranteed the thoroughness of detection. But the device needs to stir the detection component repeatedly and remove on the coating when the test to carry out comprehensive detection to the coating, it is comparatively loaded down with trivial details to use, and detection efficiency is lower. Therefore, a nano ceramic coating heat-resistant temperature measuring device is provided for improvement.

Disclosure of Invention

The object of the present utility model is to solve at least one of the technical drawbacks.

Therefore, an object of the present utility model is to provide a heat-resistant temperature measuring device with a nano ceramic coating, so as to solve the problems mentioned in the background art and overcome the defects existing in the prior art.

In order to achieve the above purpose, an embodiment of an aspect of the present utility model provides a heat-resistant temperature measurement device with a nano ceramic coating, which comprises a base, wherein a mounting groove is provided in the middle of the base, a bidirectional screw rod is rotationally connected to the mounting groove, two moving blocks are connected to the bidirectional screw rod in a threaded manner, clamping plates are fixedly connected to the top surfaces of the two moving blocks, a fixing frame is fixedly connected to the top of the base, a sliding groove is provided on the inner side of the fixing frame, a support plate is inserted into the sliding groove, sliding blocks are fixedly connected to the two ends of the support plate, and balls are respectively embedded in the top surfaces and the bottom surfaces of the sliding blocks;

the middle part of extension board is provided with the electricity push rod, the terminal fixedly connected with regulation and control box of piston rod of electricity push rod, regulation and control box internal rotation is connected with the gear, the top surface and the bottom surface of gear all are provided with the installation pole, one side that the installation pole is close to the gear all is provided with the rack, the bottom of installation pole is provided with the hot plate.

By any of the above schemes, it is preferable that threads with opposite directions are formed at two ends of the bidirectional screw rod, and the two ends of the bidirectional screw rod are rotatably connected with the base through bearings.

By any of the above schemes, preferably, one end of the bidirectional screw rod penetrates out of the base and is provided with a hand wheel.

The technical scheme is adopted: the base provides support for the superstructure, and the mounting groove of seting up in its middle part provides the installation space for two-way lead screw, provides the removal space for the movable block. The two-way screw rod can drive the two moving blocks to synchronously move in opposite directions or in opposite directions along the length direction of the two-way screw rod when rotating through threads with opposite directions formed at the two ends of the two-way screw rod. A hand wheel arranged at one end of the bidirectional screw rod can facilitate the rotation of the bidirectional screw rod by a worker. The clamping plate is used for clamping the nano ceramic coating to be detected from two sides.

By any of the above schemes, preferably, the fixing frame is composed of four upright posts and two transverse plates, and the sliding groove is formed in the inner sides of the two transverse plates of the fixing frame.

By any of the above schemes, it is preferable that the top surface and the bottom surface of the chute are both provided with limit grooves, and the balls are arranged in the limit grooves in the chute.

The technical scheme is adopted: the fixing frame provides support for the support plate and the structure on the support plate, and a certain height is obtained, so that the nano ceramic coating on the base is subjected to heat-resistant detection from above. The sliding groove can be used for the support plate to move in the front and back directions so as to carry out heat resistance detection on different positions of the nano ceramic coating. The sliding block is matched with the ball which is embedded on the sliding block and can move in the sliding groove so as to drive the support plate to move forwards and backwards. The limiting groove arranged in the sliding groove can restrict the ball, limit the ball in the limiting groove and prevent the support plate from being separated from the sliding groove.

By any of the above schemes, preferably, the electric push rod is fixed on the support plate in a mode that a piston rod faces downwards, and the gear is rotationally connected with the regulating box through a rotating shaft.

By any of the above schemes, preferably, the rotating shaft of the gear penetrates out of the regulating box and is provided with a driving component.

By any of the above schemes, it is preferable that the mounting rod is composed of a horizontal rod and a vertical rod, and a rack is arranged on one side of the horizontal rod of the mounting rod, which is close to the gear.

In any of the above embodiments, preferably, a clamping block is provided at an end of the horizontal rod of the mounting rod.

By any of the above schemes, it is preferable that the horizontal rod of the mounting rod is provided in the regulating box, and the vertical rod of the mounting rod is provided outside the regulating box.

The technical scheme is adopted: the electric push rod can drive the regulating box to move up and down so as to drive the heating plate to contact the nano ceramic coating to be detected to heat the nano ceramic coating. The regulation and control box provides installation space for regulation and control subassembly, and the gear that sets up in the regulation and control box cooperates with the installation pole, can drive the hot plate and left and right movement, and the rack on gear and the two installation poles all meshes, makes it rotate and makes can drive two installation poles in opposite directions or the motion that leaves mutually in step. The driving component arranged at the outer end of the rotating shaft of the gear can be a motor or any other component capable of driving the rotating shaft to rotate. The fixture block that the installation pole end set up can prevent installation pole and gear break away from.

Compared with the prior art, the utility model has the following advantages and beneficial effects:

1. this heat-resisting temperature measuring device of nanometer ceramic coating, through setting up regulation and control box, gear and installation pole, at the during test operation, start electric push rod and drive the regulation and control box and move down and make the nanometer ceramic coating that the hot plate contact was waited to detect, then drive gear rotation through drive assembly, gear rotation drives two installation poles and moves to both sides in step, heats the different positions of coating left and right direction, then stirs the extension board and reciprocate again, drives the hot plate and moves on the coating, heats the different positions of coating front and back direction. The two mounting rods synchronously move on the coating, so that the operation process is simpler and more convenient, and the detection efficiency is greatly improved.

2. According to the heat-resistant temperature measuring device with the nano ceramic coating, the limiting grooves are formed in the top surface and the bottom surface of the sliding groove, the balls are embedded in the top surface and the bottom surface of the sliding block in a matched mode, when the supporting plate is stirred to move forwards and backwards in the sliding groove, the balls move in the limiting grooves, friction between the sliding block and the sliding groove is greatly reduced, and the supporting plate can move more smoothly. The limiting groove can also restrict the ball, so that the support plate is prevented from being separated from the sliding groove.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The foregoing and/or additional aspects and advantages of the utility model will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic view of the present utility model in a cut-away configuration;

FIG. 3 is a schematic view of a partial structure of the present utility model;

fig. 4 is an enlarged schematic view of the structure of fig. 2 a according to the present utility model.

In the figure: the device comprises a base, a 2-mounting groove, a 3-bidirectional screw rod, a 4-moving block, a 5-clamping plate, a 6-fixing frame, a 7-sliding groove, an 8-supporting plate, a 9-sliding block, a 10-ball, an 11-electric push rod, a 12-regulating box, a 13-gear, a 14-mounting rod and a 15-heating plate.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present utility model and should not be construed as limiting the utility model.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

As shown in fig. 1-4, the utility model comprises a base 1, wherein the middle part of the base 1 is provided with a mounting groove 2, a bidirectional screw rod 3 is rotationally connected in the mounting groove 2, two moving blocks are connected on the bidirectional screw rod 3 in a threaded manner, the top surfaces of the two moving blocks 4 are fixedly connected with a clamping plate 5, the top of the base 1 is fixedly connected with a fixing frame 6, the inner side of the fixing frame 6 is provided with a sliding groove 7, a support plate 8 is inserted into the sliding groove 7, two ends of the support plate 8 are fixedly connected with sliding blocks 9, and the top surface and the bottom surface of the sliding blocks 9 are embedded with balls 10;

the middle part of extension board 8 is provided with electric putter 11, and the terminal fixedly connected with regulation and control box 12 of piston rod of electric putter 11, regulation and control box 12 internal rotation is connected with gear 13, and the top surface and the bottom surface of gear 13 all are provided with installation pole 14, and one side that installation pole 14 is close to gear 13 all is provided with the rack, and the bottom of installation pole 14 is provided with hot plate 15.

Example 1: threads with opposite directions are formed at two ends of the bidirectional screw rod 3, and two ends of the bidirectional screw rod 3 are rotationally connected with the base 1 through bearings. One end of the bidirectional screw rod 3 penetrates out of the base 1 and is provided with a hand wheel. The base 1 provides support for the superstructure, and the mounting groove 2 of seting up in its middle part provides installation space for two-way lead screw 3, provides the removal space for movable block 4. The bidirectional screw rod 3 can drive the two moving blocks 4 to synchronously move in opposite directions or in opposite directions along the length direction of the bidirectional screw rod 3 when rotating through threads with opposite directions formed at the two ends of the bidirectional screw rod 3. A hand wheel arranged at one end of the bidirectional screw rod 3 can facilitate the rotation of the bidirectional screw rod 3 by a worker. The clamping plate 5 is used for clamping the nano ceramic coating to be detected from two sides.

Example 2: the fixing frame 6 consists of four upright posts and two transverse plates, and the sliding chute 7 is arranged on the inner sides of the two transverse plates of the fixing frame 6. Limiting grooves are formed in the top surface and the bottom surface of the sliding groove 7, and the balls 10 are arranged in the limiting grooves in the sliding groove 7. The fixing frame 6 provides support for the support plate 8 and the structure on the support plate 8, and a certain height is obtained, so that the heat-resistant detection of the nano ceramic coating on the base 1 is carried out from above. The chute 7 can be used for the support plate 8 to move in the front and back directions so as to carry out heat resistance detection on different positions of the nano ceramic coating. The sliding block 9 can move in the sliding groove 7 in cooperation with the ball 10 embedded on the sliding block to drive the support plate 8 to move forwards and backwards. The limiting groove arranged in the chute 7 can restrict the ball 10, limit the ball 10 in the limiting groove and prevent the support plate 8 from being separated from the chute 7.

Example 3: the electric push rod 11 is fixed on the support plate 8 in a mode that a piston rod faces downwards, and the gear 13 is rotationally connected with the regulating box 12 through a rotating shaft. The rotating shaft of the gear 13 penetrates out of the regulating box 12 and is provided with a driving component. The mounting rod 14 consists of a horizontal rod and a vertical rod, and a rack is arranged on one side of the horizontal rod of the mounting rod 14, which is close to the gear 13. The end of the horizontal bar of the mounting bar 14 is provided with a clamping block. The horizontal bar of the mounting bar 14 is disposed within the regulating box 12, and the vertical bar of the mounting bar 14 is disposed outside the regulating box 12. The electric push rod 11 can drive the regulating box 12 to move up and down so as to drive the heating plate 15 to contact the nano ceramic coating to be detected to heat the nano ceramic coating. The regulation and control box 12 provides installation space for regulation and control subassembly, and the gear 13 that sets up in the regulation and control box 12 cooperates with installation pole 14, can drive the hot plate 15 and left and right movement, and the rack on gear 13 and two installation poles 14 all meshes, makes it rotate and makes can drive two installation poles 14 in opposite directions or the motion that leaves mutually in step. The driving component arranged at the outer end of the rotating shaft of the gear 13 can be a motor or any other component capable of driving the rotating shaft to rotate. The block provided at the end of the mounting lever 14 can prevent the mounting lever 14 from being separated from the gear 13.

The working principle of the utility model is as follows:

s1, placing a nano ceramic coating on a base 1, rotating a hand wheel to drive a bidirectional screw rod 3 to rotate, and driving two clamping plates 5 to move by the bidirectional screw rod 3 through a moving block 4 to clamp the coating;

s2, starting an electric push rod 11 to drive a regulating box 12 to move downwards so that a heating plate 15 contacts the nano ceramic coating to be detected, then driving a gear 13 to rotate through a driving assembly, and driving two mounting rods 14 to synchronously move to two sides by the rotation of the gear 13 to heat different positions of the coating in the left and right directions;

s3, poking the support plate 8 to move forwards and backwards, driving the heating plate 15 to move on the coating, and heating different positions in the front and rear directions of the coating.

Compared with the prior art, the utility model has the following beneficial effects compared with the prior art:

1. this heat-resisting temperature measuring device of nanometer ceramic coating through setting up regulation and control box 12, gear 13 and installation pole 14, when carrying out test work, starts electric push rod 11 and drives regulation and control box 12 and move down and make hot plate 15 contact the nanometer ceramic coating that waits to detect, then drive gear 13 through drive assembly and rotate, gear 13 rotates and drives two installation poles 14 and move to both sides in step, heat the different positions of coating left and right direction, then dial extension board 8 back and forth again and remove, drive hot plate 15 and remove on the coating, heat the different positions of coating front and back direction. The two mounting rods 14 move synchronously on the coating, so that the operation process is simpler and more convenient, and the detection efficiency is greatly improved.

2. According to the nano ceramic coating heat-resistant temperature measuring device, the limit grooves are formed in the top surface and the bottom surface of the sliding groove 7, the balls 10 are embedded in the top surface and the bottom surface of the sliding block 9 in a matched mode, when the supporting plate 10 is shifted to move forwards and backwards in the sliding groove 7, the balls 10 move in the limit grooves, friction force between the sliding block 9 and the sliding groove 7 is greatly reduced, and the supporting plate 10 moves more smoothly. The limiting groove can also restrict the ball 10, so that the support plate 10 is prevented from being separated from the chute 7.

Claims (10)

1. A nano ceramic coating heat-resistant temperature measuring device comprises a base (1); the novel sliding block type movable base is characterized in that a mounting groove (2) is formed in the middle of the base (1), a bidirectional screw rod (3) is rotationally connected to the mounting groove (2), two movable blocks (4) are connected to the bidirectional screw rod (3) in a threaded mode, clamping plates (5) are fixedly connected to the top surfaces of the two movable blocks (4), a fixing frame (6) is fixedly connected to the top of the base (1), a sliding groove (7) is formed in the inner side of the fixing frame (6), a supporting plate (8) is inserted into the sliding groove (7), sliding blocks (9) are fixedly connected to the two ends of the supporting plate (8), and balls (10) are embedded in the top surfaces and the bottom surfaces of the sliding blocks (9);

the middle part of extension board (8) is provided with electric putter (11), the terminal fixedly connected with regulation and control box (12) of piston rod of electric putter (11), regulation and control box (12) internal rotation is connected with gear (13), top surface and the bottom surface of gear (13) all are provided with installation pole (14), one side that installation pole (14) is close to gear (13) all is provided with the rack, the bottom of installation pole (14) is provided with hot plate (15).

2. The nano ceramic coating heat-resistant temperature measuring device as set forth in claim 1, wherein: threads with opposite directions are formed at two ends of the bidirectional screw rod (3), and two ends of the bidirectional screw rod (3) are rotationally connected with the base (1) through bearings.

3. The nano ceramic coating heat-resistant temperature measuring device as set forth in claim 2, wherein: one end of the bidirectional screw rod (3) penetrates out of the base (1) and is provided with a hand wheel.

4. A nano ceramic coating heat resistant temperature measuring device as claimed in claim 3, wherein: the fixing frame (6) consists of four upright posts and two transverse plates, and the sliding chute (7) is formed in the inner sides of the two transverse plates of the fixing frame (6).

5. The nano ceramic coating heat-resistant temperature measuring device as set forth in claim 4, wherein: limiting grooves are formed in the top surface and the bottom surface of the sliding groove (7), and the balls (10) are arranged in the limiting grooves in the sliding groove (7).

6. The nano ceramic coating heat-resistant temperature measuring device as set forth in claim 5, wherein: the electric push rod (11) is fixed on the support plate (8) in a mode that a piston rod faces downwards, and the gear (13) is rotationally connected with the regulating box (12) through a rotating shaft.

7. The nano ceramic coating heat-resistant temperature measuring device as set forth in claim 6, wherein: the rotating shaft of the gear (13) penetrates out of the regulating box (12) and is provided with a driving component.

8. The nano ceramic coating heat-resistant temperature measuring device as set forth in claim 7, wherein: the mounting rod (14) consists of a horizontal rod and a vertical rod, and a rack is arranged on one side, close to the gear (13), of the horizontal rod of the mounting rod (14).

9. The nano ceramic coating heat-resistant temperature measuring device as set forth in claim 8, wherein: the tail end of the horizontal rod of the mounting rod (14) is provided with a clamping block.

10. The nano ceramic coating heat-resistant temperature measuring device as set forth in claim 8, wherein: the horizontal rod of the mounting rod (14) is arranged in the regulating box (12), and the vertical rod of the mounting rod (14) is arranged outside the regulating box (12).