CN116067797B

CN116067797B - Intensity detection device is used in ceramic tube production

Info

Publication number: CN116067797B
Application number: CN202310353922.XA
Authority: CN
Inventors: 孔永勤; 储敏
Original assignee: Lianyungang Baibo New Material Co ltd
Current assignee: Lianyungang Baibo New Material Co ltd
Priority date: 2023-04-06
Filing date: 2023-04-06
Publication date: 2023-06-23
Anticipated expiration: 2043-04-06
Also published as: CN116067797A

Abstract

The invention relates to the technical field of ceramic tube strength detection devices, in particular to a strength detection device for ceramic tube production, which comprises a supporting seat, a detection structure, a supporting structure, a counterweight structure, a moving structure, a clamping structure, a supporting structure and a baffle plate.

Description

Intensity detection device is used in ceramic tube production

Technical Field

The invention relates to the technical field of ceramic tube strength detection devices, in particular to a strength detection device for ceramic tube production.

Background

The ceramic tube is mainly formed by sintering zirconia ceramic or alumina ceramic materials, has excellent wear resistance, heat resistance, mechanical resistance and thermal shock resistance, is easy to weld and install, is particularly suitable for material conveying occasions with serious wear and scouring, and needs to carry out compression resistance detection in the ceramic tube production process to ensure that the compression resistance of the ceramic tube reaches the qualified standard.

However, because the ceramic tube has a larger volume, a lifting tool is required to lift the ceramic tube to the detection device in the detection process, and the ceramic tube is required to be placed to a specified position, so that the position is required to be adjusted in the lifting process, and the ceramic tube and the detection device are easily collided due to misoperation in the lifting process, so that the ceramic tube is damaged, the compression resistance performance of one direction can only be detected after the ceramic tube is placed in the compression resistance detection process, the detection of different directions of the ceramic tube is inconvenient, the detection result is single, and the detection accuracy is reduced.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a strength detection device for ceramic tube production.

The technical scheme adopted for solving the technical problems is as follows: the utility model provides a intensity detection device is used in ceramic tube production, includes the supporting seat, be equipped with detection structure on the supporting seat, be equipped with on the detection structure and hold up the structure, be equipped with the counter weight structure on the detection structure, be equipped with the moving structure on the supporting seat, be equipped with the screens structure on the moving structure, be equipped with bearing structure on the moving structure, fixedly connected with two baffles on the supporting seat;

specifically, hold up the structure and include the layer board, detect structural two layer boards of being connected with, install the motor on the layer board, fixedly connected with first belt pulley on the output shaft of motor, rotate on the layer board and be connected with the runner, fixedly connected with second belt pulley on the runner, the winding has the belt on the second belt pulley, two the one end winding of belt is in same first belt pulley.

Specifically, the two rotating wheels are symmetrically distributed about the middle of the first belt pulley, and a V-shaped structure is formed between the two second belt pulleys and the first belt pulley.

Specifically, the detection structure includes the balladeur train, sliding connection has the balladeur train on the supporting seat, install two pneumatic cylinders on the supporting seat, two fixedly connected with layer boards on the balladeur train, two the one end fixed connection of pneumatic cylinder in the balladeur train, the block has the briquetting on the balladeur train, the internally mounted of balladeur train has pressure sensor, contradict between pressure sensor and the briquetting, the bottom of briquetting is equipped with the ceramic tube.

Specifically, the counter weight structure includes the connecting block, fixedly connected with connecting block on the balladeur train, it is connected with two leading wheels to rotate on the supporting seat, two the winding has same stay cord on the leading wheel, the one end fixedly connected with connecting block of stay cord, the other end fixedly connected with balancing weight of stay cord, balancing weight sliding connection is in the supporting seat.

Specifically, the movable structure comprises a movable frame, the movable frame is abutted to the supporting seat, four movable wheels are mounted at the bottom end of the movable frame, the bottom end of each movable wheel is abutted to the supporting seat, and a handle is fixedly connected to the movable frame.

Specifically, the screens structure includes the connecting axle, it is connected with the connecting axle to remove to rotate on the frame, the one end fixedly connected with crank of connecting axle, the other end fixedly connected with first gear of connecting axle, the meshing between first gear and the second gear, second gear fixed connection is in the lead screw, the lead screw rotates to be connected in the frame that removes, threaded connection has two slide on the lead screw, be equipped with the guide way on the slide.

Specifically, the directions of threads at two ends of the screw rod are opposite, the first gear and the second gear are perpendicular, and the diameter of the first gear is smaller than that of the second gear.

Specifically, block between slide and the supporting seat, the one end of slide cross-section is trapezium structure.

Specifically, bearing structure includes the slipframe, sliding connection has two slipframes on the movable frame, it is connected with the guiding axle to rotate on the slipframe, the guiding axle runs through in the guide way and with the slide between roll connection, fixedly connected with backup pad on the slipframe, fixedly connected with bracing piece in the backup pad, fixedly connected with two deflector on the movable frame, sliding connection has the backup pad on the deflector.

Specifically, the cross section of guiding axle is circular structure, the cross section of bracing piece is V-arrangement structure.

The beneficial effects of the invention are as follows:

(1) According to the strength detection device for ceramic tube production, when the ceramic tube is required to be detected, the moving structure is pushed and moved to the placement position of the ceramic tube, the ceramic tube can be placed on the supporting structure, the moving structure is located inside the supporting seat by pushing the moving structure after the ceramic tube is placed on the supporting structure, at the moment, the moving structure and the supporting seat are prevented from moving between the moving structure and the supporting seat in the detection process by being clamped between the clamping structure and the supporting seat, so that the stability is improved, the clamping structure can drive the supporting structure to move towards the supporting seat in the movement process, so that the supporting structure is not contacted with the ceramic tube, the ceramic tube is prevented from rolling on the supporting seat by the two baffles after the ceramic tube is contacted with the supporting seat, the ceramic tube is placed before detection, and the ceramic tube is prevented from being bumped when the ceramic tube is placed due to the fact that the space around the moving structure is larger after the moving structure is separated from the supporting seat, and the safety and convenience in use are improved.

(2) According to the strength detection device for ceramic tube production, the compression resistance of the ceramic tube can be detected through the detection structure after the ceramic tube is placed, the detection structure can be moved after the compression resistance of one direction of the ceramic tube is detected, the detection structure can drive the supporting structure to move towards the ceramic tube in the moving process, the detection structure can further deviate from the ceramic tube for a certain distance, the supporting structure can support the ceramic tube to enable the ceramic tube to have a certain distance from the supporting seat, the ceramic tube can be rotated through the supporting structure, so that the direction of the ceramic tube is changed, the detection structure can be moved reversely after the direction of the ceramic tube is changed, the supporting structure can be separated from the ceramic tube at the moment, the ceramic tube can be contacted with the supporting seat, the compression resistance of the other direction of the ceramic tube can be detected along with the continuous movement of the detection structure, the compression resistance detection of the ceramic tube can be carried out in different directions of the ceramic tube, the detection is more comprehensive, and the detection accuracy is improved.

(3) According to the strength detection device for ceramic tube production, provided by the invention, part of gravity of the detection structure can be counteracted by the counterweight structure in the process of detecting the movement of the structure, so that the effect of saving power can be achieved, the output of energy is saved, and the device is more energy-saving and environment-friendly.

Drawings

The invention will be further described with reference to the drawings and examples.

FIG. 1 is a schematic diagram showing the overall structure of a strength detecting device for ceramic tube production according to a preferred embodiment of the present invention;

FIG. 2 is an enlarged schematic view of the portion A shown in FIG. 1;

FIG. 3 is an enlarged schematic view of the B-section structure shown in FIG. 1;

FIG. 4 is a schematic diagram of a connection structure of the carriage and the press block according to the present invention;

FIG. 5 is an enlarged schematic view of the structure of the portion C shown in FIG. 4;

FIG. 6 is an enlarged schematic view of the structure of the portion D shown in FIG. 4;

FIG. 7 is a schematic view of the connection structure of the carriage and the pallet of the present invention;

FIG. 8 is an enlarged schematic view of the E-section structure shown in FIG. 7;

fig. 9 is an enlarged schematic view of the F-section structure shown in fig. 7;

fig. 10 is a schematic view of a connection structure of a support plate and a support rod according to the present invention.

In the figure: 1. a support base; 2. a detection structure; 201. a hydraulic cylinder; 202. a carriage; 203. briquetting; 204. a pressure sensor; 3. a supporting structure; 301. a supporting plate; 302. a motor; 303. a first pulley; 304. a belt; 305. a second pulley; 306. a rotating wheel; 4. a counterweight structure; 401. a connecting block; 402. a pull rope; 403. balancing weight; 404. a guide wheel; 5. a moving structure; 501. a handle; 502. a moving rack; 503. a moving wheel; 6. a clamping structure; 601. a crank; 602. a connecting shaft; 603. a first gear; 604. a second gear; 605. a screw rod; 606. a slide plate; 607. a guide groove; 7. a support structure; 701. a guide shaft; 702. a sliding frame; 703. a support plate; 704. a support rod; 705. a guide plate; 8. and a baffle.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1-10, the strength detection device for ceramic tube production of the invention comprises a support seat 1, wherein a detection structure 2 is arranged on the support seat 1, a supporting structure 3 is arranged on the detection structure 2, a counterweight structure 4 is arranged on the detection structure 2, a moving structure 5 is arranged on the support seat 1, a clamping structure 6 is arranged on the moving structure 5, a support structure 7 is arranged on the moving structure 5, and two baffles 8 are fixedly connected on the support seat 1;

specifically, the lifting structure 3 includes a supporting plate 301, two supporting plates 301 are connected to the detecting structure 2, a motor 302 is installed on the supporting plate 301, a first belt pulley 303 is fixedly connected to an output shaft of the motor 302, a rotating wheel 306 is rotatably connected to the supporting plate 301, a second belt pulley 305 is fixedly connected to the rotating wheel 306, a belt 304 is wound on the second belt pulley 305, one ends of the two belts 304 are wound on the same first belt pulley 303, the two rotating wheels 306 are symmetrically distributed about the middle of the first belt pulley 303, a V-shaped structure is formed between the two second belt pulleys 305 and the first belt pulley 303, the detecting structure 2 includes a carriage 202, a carriage 202 is slidably connected to the supporting seat 1, two supporting plates 301 are fixedly connected to the carriage 202, two hydraulic cylinders 201 are installed on the supporting seat 1, one ends of the two hydraulic cylinders 201 are fixedly connected to the carriage 202, a pressing block 203 is clamped on the carriage 202, a pressing block 204 is installed inside the carriage 202, the pressing block 204 is abutted against the pressing block 204, and a bottom end 203 of the pressing block 203 is provided with a ceramic tube, namely, the pressing block 203 is arranged inside the carriage. When the compressive property of the ceramic tube needs to be detected, the two hydraulic cylinders 201 are synchronously extended to drive the sliding frame 202 to move, the sliding frame 202 drives the pressing block 203 to move towards the ceramic tube, when the pressing block 203 is contacted with the ceramic tube, the hydraulic cylinder 201 can apply a pressure to the ceramic tube through the pressing block 203, the pressure value can be detected through the pressure sensor 204, when the pressure value reaches a specified value, if the ceramic tube is not deformed, the quality is qualified, if the ceramic tube is deformed or damaged, the quality is disqualified, thereby realizing the detection of the compressive property of the ceramic tube in one direction, when the compressive property of the ceramic tube in different directions needs to be detected, the sliding frame 202 is driven to move by the synchronous shrinkage of the two hydraulic cylinders 201, the sliding frame 202 can drive the pressing block 203 to be separated from the top end of the ceramic tube, meanwhile, the sliding frame 202 can drive the two supporting plates 301 to move towards the ceramic tube, the two rotating wheels 306 on the supporting plate 301 are contacted with the ceramic tube in the moving process, and the bottom end of the ceramic tube is separated from the supporting seat 1 along with the continuous movement of the supporting plate 301, the hydraulic cylinder 201 stops shrinking at the moment, then the output shaft of the motor 302 rotates to drive the first belt pulley 303 to rotate, the first belt pulley 303 rotates to drive the second belt pulley 305 to rotate through the two belts 304, the second belt pulley 305 drives the two rotating wheels 306 to rotate, the rotating wheels 306 rotate the ceramic tube, so that the orientation of the ceramic tube is changed, after the orientation of the ceramic tube is changed, the two rotating wheels 306 synchronously extend through the two hydraulic cylinders 201, at the moment, the two rotating wheels 306 move into the supporting seat 1, the bottom end of the ceramic tube is contacted with the supporting seat 1, the pressing block 203 is contacted with the ceramic tube again, therefore, the detection of the compressive properties of the ceramic tube in different directions is realized, the compressive detection can be more comprehensive by detecting the compressive properties of the ceramic tube in different directions, the result is more reliable, and the detection accuracy is improved.

Specifically, the counterweight structure 4 includes a connection block 401, the connection block 401 is fixedly connected to the carriage 202, two guide wheels 404 are rotatably connected to the support base 1, two same pull ropes 402 are wound on the guide wheels 404, one end of each pull rope 402 is fixedly connected to the connection block 401, the other end of each pull rope 402 is fixedly connected to a counterweight 403, and the counterweight 403 is slidably connected to the support base 1, namely: the connecting block 401 can be driven to move in the moving process of the sliding frame 202, the connecting block 401 can drive the balancing weight 403 to slide on the supporting seat 1 through the pull rope 402, and the two guide wheels 404 synchronously rotate.

Specifically, the moving structure 5 comprises a moving frame 502, the supporting seat 1 is abutted against the moving frame 502, four moving wheels 503 are arranged at the bottom end of the moving frame 502, the bottom end of the moving wheels 503 is abutted against the supporting seat 1, a handle 501 is fixedly connected to the moving frame 502, the clamping structure 6 comprises a connecting shaft 602, a connecting shaft 602 is rotatably connected to the moving frame 502, one end of the connecting shaft 602 is fixedly connected with a crank 601, the other end of the connecting shaft 602 is fixedly connected with a first gear 603, the first gear 603 is meshed with a second gear 604, the second gear 604 is fixedly connected with a screw rod 605, the screw rod 605 is rotatably connected to the moving frame 502, two sliding plates 606 are connected to the screw rod 605 in a threaded manner, guide grooves 607 are formed in the sliding plates 606, the screw directions of the two ends of the screw rod 605 are opposite, perpendicular between first gear 603 and the second gear 604, the diameter of first gear 603 is less than the diameter of second gear 604, block between slide 606 and the supporting seat 1, slide 606 cross-section's one end is trapezium structure, supporting structure 7 includes slide frame 702, sliding connection has two slide frames 702 on the removal frame 502, it is connected with guiding axle 701 to rotate on the slide frame 702, guiding axle 701 runs through in guiding groove 607 and rolling connection between slide 606, fixedly connected with backup pad 703 on the slide frame 702, fixedly connected with bracing piece 704 on the backup pad 703, fixedly connected with two deflector 705 on the removal frame 502, sliding connection has the backup pad 703 on the deflector 705, the cross-section of guiding axle 701 is circular structure, the cross-section of bracing piece 704 is V-arrangement structure, namely: after the ceramic tube is detected, the crank 601 can be rotated to drive the connecting shaft 602 to rotate, the connecting shaft 602 is rotated to drive the first gear 603 to rotate, the first gear 603 is rotated to drive the second gear 604 to rotate, the first gear 603 and the second gear 604 are mutually perpendicular bevel gears, so that the transmission direction can be changed, and the diameter of the first gear 603 is smaller than that of the second gear 604, the effect of saving power can be achieved, the second gear 604 is rotated to drive the screw rod 605 to rotate, the screw rod 605 is rotated to drive the two sliding plates 606 to simultaneously move away from the supporting seat 1 due to the opposite screw thread directions at the two ends of the screw rod 605, at the moment, the guide shaft 701 rolls in the guide groove 607, when the guide shaft 701 moves to the inclined position in the middle of the guide groove 607, the guide shaft 701 is abutted against the sliding frame 702 along with the continued movement of the sliding plate 606, the sliding frame 702 can drive the supporting plate 703 to move, the supporting plate 703 can drive the supporting rod 704 to move, the guide plate 705 plays a role in guiding in the process of the movement of the supporting plate 703, the supporting rod 704 can support the ceramic tube in the process of the movement, the ceramic tube can be prevented from rotating on the supporting rod 704 after the ceramic tube is supported due to the V-shaped section of the supporting rod 704, so that the stability is improved, when the two supporting rods 704 support the ceramic tube, the two sliding plates 606 can not be clamped with the supporting seat 1, the movable frame 502 can be pulled out from the inside of the supporting seat 1 by holding the handle 501, the space around the ceramic tube can be enlarged after the movable frame 502 is pulled out from the supporting seat 1, and further, the ceramic tube can be prevented from being damaged due to collision between the ceramic tube and the device when the ceramic tube is taken and placed, so that the use safety is improved, and the space is enlarged and the operation is also more simple and convenient when placing and taking, thereby the convenience of operation is improved, after the ceramic tube that the detection was accomplished is taken off from two bracing pieces 704, can place the ceramic tube that does not detect on bracing piece 704, then alright promote through handle 501 and remove frame 502 and make and remove the inside that frame 502 is located supporting seat 1, after removing the frame 502 and being located supporting seat 1's inside, can make the block between two slide 606 and the supporting seat 1 through reverse rotation crank 601, can avoid removing frame 502 at the inside motion of supporting seat 1 this moment, thereby stability is improved, and can make two bracing pieces 704 move to the inside of supporting seat 1 at the in-process of slide 606 motion, separation and contact between the top of supporting seat 1 between the bottom and the bracing piece 704 of ceramic tube this moment, realize the placing of ceramic tube this moment, can prevent through two baffles 8 that the ceramic tube from rolling on supporting seat 1 after the ceramic tube is placed, thereby the effect to ceramic tube location has been played, stability when detecting has been improved.

When the invention is used, when the compressive property of a ceramic tube is required to be detected, the two hydraulic cylinders 201 are simultaneously started, the two hydraulic cylinders 201 synchronously extend to drive the sliding frame 202 to move, the connecting block 401 is driven to move in the moving process of the sliding frame 202, the connecting block 401 drives the balancing weights 403 to slide on the supporting seat 1 through the pull ropes 402, the two guide wheels 404 synchronously rotate, and as the moving directions of the balancing weights 403 and the sliding frame 202 are opposite, part of gravity of the sliding frame 202 and the pressing block 203 can be offset through the balancing weights 403, thereby saving energy output of the hydraulic cylinders 201, being more energy-saving and environment-friendly, the sliding frame 202 moves to drive the pressing block 203 to move towards the ceramic tube, when the pressing block 203 contacts with the ceramic tube, the hydraulic cylinders 201 apply a pressure to the ceramic tube through the pressing block 203, and the pressure value can be detected through the pressure sensor 204, when the pressure value reaches a specified value, if the ceramic tube is not deformed, the quality is qualified, if the ceramic tube is deformed or damaged, the quality is unqualified, thereby realizing the detection of the compressive property of the ceramic tube in one direction, when the compressive property of the ceramic tube in different directions is required to be detected, the two hydraulic cylinders 201 are synchronously contracted, the sliding frame 202 is driven to move by the contraction of the hydraulic cylinders 201, the sliding frame 202 drives the pressing block 203 to be separated from the top end of the ceramic tube, the sliding frame 202 drives the two supporting plates 301 to move towards the ceramic tube, the two rotating wheels 306 positioned on the supporting plates 301 are firstly contacted with the ceramic tube in the moving process, and are separated from the supporting seat 1 along with the continuous movement of the bottom end of the ceramic tube of the supporting plates 301, the hydraulic cylinders 201 stop contracting at the moment, and then the first belt pulley 303 is driven to rotate by the rotation of the output shaft of the motor 302 through the starting motor 302, the first belt pulley 303 rotates to drive the second belt pulley 305 to rotate through the two belts 304, the second belt pulley 305 drives the two rotating wheels 306 to rotate, the rotating wheels 306 rotate to enable the ceramic tube to rotate, so that the direction of the ceramic tube is changed, after the direction of the ceramic tube is changed, the ceramic tube is synchronously stretched through the two hydraulic cylinders 201, at the moment, the two rotating wheels 306 move to the inside of the supporting seat 1, the bottom end of the ceramic tube is contacted with the supporting seat 1, and the pressing block 203 is contacted with the ceramic tube again, so that the compression resistance of the ceramic tube in different directions is detected, the compression resistance detection is more comprehensive, the result is more reliable, and the detection accuracy is improved;

after the ceramic tube is detected, the crank 601 can be rotated to drive the connecting shaft 602 to rotate, the connecting shaft 602 is rotated to drive the first gear 603 to rotate, the first gear 603 is rotated to drive the second gear 604 to rotate, the first gear 603 and the second gear 604 are bevel gears perpendicular to each other, so that the transmission direction can be changed, and the diameter of the first gear 603 is smaller than that of the second gear 604, so that the effect of saving power can be achieved, the second gear 604 is rotated to drive the screw rod 605 to rotate, the screw rod 605 is rotated to drive the two sliding plates 606 to move away from the supporting seat 1 by threads because the directions of threads at the two ends of the screw rod 605 are opposite, at the moment, the guide shaft 701 rolls in the guide groove 607, when the guide shaft 701 moves to the inclined position in the middle of the guide groove 607, the guide shaft 701 can collide with the sliding frame 702 along with the continued movement of the sliding plate 606, the sliding frame 702 can drive the supporting plate 703 to move, the support plate 703 can drive the support rod 704 to move, the guide plate 705 plays a role in guiding in the process of the movement of the support plate 703, the support rod 704 can support the ceramic tube in the process of the movement, the cross section of the support rod 704 is of a V-shaped structure, so that the ceramic tube can be prevented from rotating on the support rod 704 after the ceramic tube is supported, the stability is improved, when the two support rods 704 support the ceramic tube, the two sliding plates 606 can be not clamped with the support seat 1, the handle 501 can be held to pull the movable frame 502 out of the support seat 1, when the movable frame 502 is pulled out of the support seat 1, the space around the ceramic tube can be enlarged, and further, the ceramic tube can be prevented from being damaged due to collision between the ceramic tube and the device during the process of picking and placing the ceramic tube, the use safety is improved, the space is enlarged, the operation is simpler and more convenient during the process of placing and picking, therefore, the convenience of operation is improved, when the ceramic tube after detection is taken down from the two support rods 704, the undetected ceramic tube can be placed on the support rods 704, then the movable frame 502 can be pushed by the handle 501 to enable the movable frame 502 to be located in the support seat 1, after the movable frame 502 is located in the support seat 1, the two sliding plates 606 and the support seat 1 can be clamped by reversely rotating the crank 601, at the moment, the movable frame 502 can be prevented from moving in the support seat 1, so that the stability is improved, the two support rods 704 can be moved to the support seat 1 in the moving process of the sliding plates 606, at the moment, the bottom ends of the ceramic tube are separated from the support rods 704 and are contacted with the top ends of the support seat 1, at the moment, the placement of the ceramic tube is realized, and after the placement of the ceramic tube is finished, the ceramic tube can be prevented from rolling on the support seat 1 through the two baffles 8, so that the ceramic tube positioning effect is achieved, and the stability in the detection is improved.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims

1. The utility model provides a intensity detection device is used in ceramic tube production, its characterized in that, including supporting seat (1), be equipped with detection structure (2) on supporting seat (1), be equipped with on detection structure (2) and hold up structure (3), be equipped with counter weight structure (4) on detection structure (2), be equipped with on supporting seat (1) and remove structure (5), be equipped with screens structure (6) on removing structure (5), be equipped with supporting structure (7) on removing structure (5), fixedly connected with two baffles (8) on supporting seat (1);

the supporting structure (3) comprises a supporting plate (301), two supporting plates (301) are connected to the detecting structure (2), a motor (302) is installed on the supporting plate (301), a first belt pulley (303) is fixedly connected to an output shaft of the motor (302), a rotating wheel (306) is rotatably connected to the supporting plate (301), a second belt pulley (305) is fixedly connected to the rotating wheel (306), a belt (304) is wound on the second belt pulley (305), and one ends of the two belts (304) are wound on the same first belt pulley (303);

the detection structure (2) comprises a sliding frame (202), the sliding frame (202) is connected to the supporting seat (1) in a sliding manner, two supporting plates (301) are fixedly connected to the sliding frame (202), two hydraulic cylinders (201) are installed on the supporting seat (1), one ends of the two hydraulic cylinders (201) are fixedly connected to the sliding frame (202), pressing blocks (203) are clamped on the sliding frame (202), a pressure sensor (204) is installed in the sliding frame (202), the pressure sensor (204) is in contact with the pressing blocks (203), and ceramic tubes are arranged at the bottom ends of the pressing blocks (203);

the counterweight structure (4) comprises a connecting block (401), the connecting block (401) is fixedly connected to the carriage (202), two guide wheels (404) are rotationally connected to the supporting seat (1), the same pull rope (402) is wound on the two guide wheels (404), one end of the pull rope (402) is fixedly connected to the connecting block (401), the other end of the pull rope (402) is fixedly connected to the counterweight (403), and the counterweight (403) is slidably connected to the supporting seat (1);

the movable structure (5) comprises a movable frame (502), the movable frame (502) is abutted against the supporting seat (1), four movable wheels (503) are arranged at the bottom end of the movable frame (502), the bottom ends of the movable wheels (503) are abutted against the supporting seat (1), and a handle (501) is fixedly connected to the movable frame (502);

the clamping structure (6) comprises a connecting shaft (602), the connecting shaft (602) is rotationally connected to the movable frame (502), one end of the connecting shaft (602) is fixedly connected with a crank (601), the other end of the connecting shaft (602) is fixedly connected with a first gear (603), the first gear (603) is meshed with a second gear (604), the second gear (604) is fixedly connected to a screw rod (605), the screw rod (605) is rotationally connected to the movable frame (502), two sliding plates (606) are in threaded connection with the screw rod (605), and guide grooves (607) are formed in the sliding plates (606); the screw threads at two ends of the screw rod (605) are opposite in direction, the first gear (603) is perpendicular to the second gear (604), and the diameter of the first gear (603) is smaller than that of the second gear (604); the sliding plate (606) is clamped with the supporting seat (1), and one end of the section of the sliding plate (606) is in a trapezoid structure;

the supporting structure (7) comprises a sliding frame (702), two sliding frames (702) are connected to the moving frame (502) in a sliding mode, a guide shaft (701) is connected to the sliding frame (702) in a rotating mode, the guide shaft (701) penetrates through a guide groove (607) and is connected with a sliding plate (606) in a rolling mode, a supporting plate (703) is fixedly connected to the sliding frame (702), a supporting rod (704) is fixedly connected to the supporting plate (703), two guide plates (705) are fixedly connected to the moving frame (502), and a supporting plate (703) is connected to the guide plates (705) in a sliding mode.

2. The strength detecting device for ceramic tube production according to claim 1, wherein: the two rotating wheels (306) are symmetrically distributed about the middle of the first belt pulley (303), and a V-shaped structure is formed between the two second belt pulleys (305) and the first belt pulley (303).

3. The strength detecting device for ceramic tube production according to claim 1, wherein: the section of the guide shaft (701) is of a circular structure, and the section of the support rod (704) is of a V-shaped structure.