CN116482166B - High temperature cable high temperature resistant detection device - Google Patents

Abstract

The utility model discloses a high-temperature-resistant detection device for a high-temperature cable, which relates to the technical field of cable detection and comprises a bracket, a fixing plate, a safety component and a detection component; by arranging the safety component, the contact switch can be automatically disconnected when the cable is detected, so that the possible electric shock is prevented, and the safety of operators is ensured; by arranging the safety component, the power supply is automatically switched on during testing, so that the power on of the cable is realized, the state of the cable in actual work is simulated, and the accuracy and high efficiency of a test result are ensured; by arranging the detection assembly, the temperature cycle detection and the high-temperature impact detection can be carried out on the cable at the same time, the detection modes are various, and the performance of the cable in different environments is detected in all directions; one-key starting is simple and convenient to operate, and the detection efficiency is improved.

Description

High temperature cable high temperature resistant detection device

Technical Field

The utility model relates to the technical field of cable detection, in particular to a high-temperature-resistant detection device for a high-temperature cable.

Background

A high temperature cable is a cable specifically designed to operate in a high temperature environment. It employs special materials and structures to ensure stable electrical performance and mechanical strength under high temperature conditions. High temperature cables are commonly used in applications requiring the transmission of electricity or signals in high temperature environments, such as in the high temperature furnace, electric furnace, petrochemical industry, automotive engines, and aerospace, among others.

The Chinese patent publication No. CN218470140U discloses a high temperature resistant detection device for an optical fiber cable, which can connect the optical fiber cable to be tested to a working state so as to improve the detection accuracy; the device comprises a heating box, a box cover, a lock catch, a clamping block, a heating pipe and a connecting mechanism. The heating box is provided with a rotatable box cover, the front side of the box cover is connected with two rotatable lock catches, the front side of the heating box is connected with two clamping blocks, the interior of the box cover is provided with a heating pipe, and the heating box is provided with a connecting mechanism; the device is connected with external equipment through a signal transmission line, and the optical fiber cable to be tested is fixedly clamped through the clamp, so that the device can perform performance detection in the working process.

The defects of the prior art scheme are that: the prior art can not simulate the temperature cycle detection and the high-temperature impact detection of the cable under the condition of electrifying the cable, can not detect the influence of the cable in an extreme environment, has a single detection mode and has a limited application range; in addition, the prior art is not provided with a related protection structure, so that safety accidents are easily caused by electric leakage in the detection process; the prior art has complex operation and low efficiency.

Disclosure of Invention

Aiming at the technical problems, the utility model adopts the following technical scheme: the high-temperature cable high-temperature-resistant detection device comprises a bracket, a fixing plate, a safety component and a detection component, wherein the safety component is rotatably arranged on the bracket; the detection component is arranged on the bracket in a sliding way; the safety assembly comprises a safety rotating disc which is rotatably arranged on the support, a safety cam and a safety handle are fixedly arranged on the safety rotating disc, a safety rotating column is rotatably arranged on the safety cam, a safety energy storage spring is movably arranged on the other side of the safety rotating column, and the other end of the safety energy storage spring is fixedly arranged on the support; the safety rotating disc is in sliding fit with a safety limiting block I movably arranged on the support, the safety limiting block I is in sliding fit with a safety clamping block I movably arranged on the support, the safety clamping block I is in sliding fit with a safety sliding block movably arranged on the support, the safety sliding block is rotationally arranged on the safety push rod, the safety push rod is slidingly arranged on the support, the safety sliding block is in sliding fit with a safety rotating piece rotationally arranged on the support, and the safety rotating piece is in sliding fit with a safety limiting block II movably arranged on the support.

Further, the second safety limiting block is in sliding fit with a safety contact block movably arranged on the bracket, the safety contact block is in sliding fit with a first safety binding post fixedly arranged on the second safety locking nut, the safety contact block is in sliding fit with a second safety binding post slidingly arranged on the first safety locking nut, and a safety binding spring is arranged between the second safety binding post and the first safety locking nut; the safety lock nut I is fixedly provided with a safety wire II, the safety lock nut II is fixedly provided with a safety wire I, and the safety wire I is fixedly arranged on the safety power supply; the other end of the second safety wire is fixedly arranged on the first cable fixing screw, and the other end of the first safety wire is fixedly arranged on the second cable fixing screw.

Further, the safety cam is in sliding fit with the safety toggle piece, the safety toggle piece is fixedly provided with a safety arc piece, the safety arc piece is in sliding fit with the safety limiting block II, the safety toggle piece is movably provided with a safety cylinder, the other side of the safety cylinder is rotatably arranged on the support, and the safety toggle piece is slidably provided with a safety compression bar.

Further, a third safety spring is fixedly arranged between the first safety clamping block and the support, a second safety spring is fixedly arranged between the first safety limiting block and the support, and a first safety spring is fixedly arranged between the second safety limiting block and the support.

Further, the fixed detection component that is provided with of insurance depression bar other end, detection component is including the fixed detection slip post that sets up on insurance depression bar, it slides and sets up on the support to detect the slip post, it slides and sets up on detecting the friction disc to detect the slip post, it slides and sets up on detecting the rotation post to detect the friction disc, detects the rotation post and passes through spline connection with detecting the friction disc, detects the rotation post and rotates and set up on the support.

Further, the detection fixing pieces are fixedly arranged at the two ends of the detection rotating column, the detection U-shaped pieces are rotatably arranged on the detection fixing pieces, the detection U-shaped pieces are rotatably arranged on the detection rotating column I, and the detection rotating column is rotatably arranged on the support.

Further, the first detection rotating column is fixedly provided with a detection conical block, and the detection conical block is fixedly provided with a detection ring and a detection storage tank.

Further, detect friction disc and detect arc dish friction fit, detect the arc dish and slide and set up on detecting the output shaft of motor, detect the arc dish and detect the motor between the activity be provided with the detection spring, detect the arc dish and pass through spline connection on detecting the output shaft of motor.

Compared with the prior art, the utility model has the beneficial effects that: (1) According to the utility model, by arranging the safety component, when a cable is detected, the contact switch can be automatically disconnected to prevent possible electric shock, so that the safety of operators is ensured; (2) By arranging the safety component, the power supply is automatically switched on during testing, so that the power on of the cable is realized, the state of the cable in actual work is simulated, and the accuracy and high efficiency of a test result are ensured; (3) By arranging the detection assembly, the temperature cycle detection and the high-temperature impact detection can be carried out on the cable at the same time, the detection modes are various, and the performance of the cable in different environments is detected in all directions; (4) One-key starting is simple and convenient to operate, and the detection efficiency is improved.

Drawings

Fig. 1 is a schematic diagram of a partial structure of the present utility model.

Fig. 2 is a schematic diagram of the whole structure of the utility model in front view.

FIG. 3 is a schematic side view of the overall structure of the present utility model.

Fig. 4 is a schematic diagram of a partial structure of the present utility model.

Fig. 5 is a schematic diagram of a partial structure of the present utility model.

Fig. 6 is a schematic diagram of a part of a safety component according to the present utility model.

Fig. 7 is a schematic diagram of a part of a safety component according to the present utility model.

FIG. 8 is a schematic diagram of a part of the detecting unit according to the present utility model.

FIG. 9 is a schematic diagram showing a partial structure of a detecting component according to the present utility model.

Reference numerals: 1-a safety component; 2-a detection assembly; 3-a bracket; 4-a cable to be tested; 5-a fixing plate; 101-a safety push rod; 102-a safety slide block; 103-a safety rotating piece; 104-a first safety clamping block; 105-a first safety limiting block; 106-a first safety binding post; 107-a safety contact block; 108-a second safety limiting block; 109-a safety cylinder; 110-a safety driving piece; 111-a safety arc piece; 112-a safety rotating disc; 113-a safety cam; 114-a safety compression bar; 115-a safety rotating column; 116-a safety energy storage spring; 117-safety handle; 118-a second safety terminal; 119-a safety wire spring; 120-a first safety spring; 121-a second safety spring; 122-a third safety spring; 123-a first safety lock nut; 124-a second safety lock nut; 125-first fuse wire; 126-a safe power supply; 127-second fuse wire; 128-cable set screw one; 129-cable fixing screw two; 201-detecting a sliding column; 202-detecting a friction disc; 203-detecting an arc-shaped disc; 204-detecting the motor; 205-detecting a spring; 206-detecting a rotating column; 207-detecting the stator; 208-detecting the U-shaped piece; 209-detecting a first rotating column; 210-detecting a conical block; 211-detecting a storage tank; 212-a detection loop; 213-fixed wheels.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 9, a high temperature cable high temperature resistant detection device comprises a bracket 3, a fixing plate 5, a safety component 1 and a detection component 2, wherein the safety component 1 is rotatably arranged on the bracket 3, and the fixing plate 5 is fixedly arranged on the bracket 3; the detection component 2 is arranged on the bracket 3 in a sliding way; the safety assembly 1 comprises a safety rotating disc 112 which is rotatably arranged on the bracket 3, a safety cam 113 and a safety handle 117 are fixedly arranged on the safety rotating disc 112, a safety rotating column 115 is rotatably arranged on the safety cam 113, a safety energy storage spring 116 is movably arranged on the other side of the safety rotating column 115, and the other end of the safety energy storage spring 116 is fixedly arranged on the bracket 3; the safety rotating disc 112 is in sliding fit with the first safety limiting block 105 movably arranged on the support 3, the first safety limiting block 105 is in sliding fit with the first safety clamping block 104 movably arranged on the support 3, the first safety clamping block 104 is in sliding fit with the safety sliding block 102 movably arranged on the support 3, the safety sliding block 102 is rotatably arranged on the safety push rod 101, the safety push rod 101 is slidably arranged on the support 3, the safety sliding block 102 is in sliding fit with the second safety limiting block 108 rotatably arranged on the support 3, and the safety rotating plate 103 is in sliding fit with the second safety limiting block 103 movably arranged on the support 3.

The second safety limiting block 108 is in sliding fit with the safety contact block 107 movably arranged on the bracket 3, the safety contact block 107 is in sliding fit with the first safety binding post 106 fixedly arranged on the second safety locking nut 124, the safety contact block 107 is in sliding fit with the second safety binding post 118 slidably arranged on the first safety locking nut 123, and a safety binding spring 119 is arranged between the second safety binding post 118 and the first safety locking nut 123; a second safety wire 127 is fixedly arranged on the first safety lock nut 123, a first safety wire 125 is fixedly arranged on the second safety lock nut 124, and the first safety wire 125 is fixedly arranged on the safety power supply 126; the other end of the second safety wire 127 is fixedly arranged on the first cable fixing screw 128, and the other end of the first safety wire 125 is fixedly arranged on the second cable fixing screw 129.

The safety cam 113 is in sliding fit with the safety driving piece 110, the safety arc piece 111 is fixedly arranged on the safety driving piece 110, the safety arc piece 111 is in sliding fit with the safety limiting block II 108, the safety driving piece 110 is movably provided with the safety cylinder 109, the other side of the safety cylinder 109 is rotatably arranged on the bracket 3, and the safety driving piece 110 is slidably provided with the safety compression bar 114.

A third safety spring 122 is fixedly arranged between the first safety clamping block 104 and the bracket 3, a second safety spring 121 is fixedly arranged between the first safety limiting block 105 and the bracket 3, and a first safety spring 120 is fixedly arranged between the second safety limiting block 108 and the bracket 3.

The fixed detection component 2 that is provided with of insurance depression bar 114 other end, detection component 2 is including the fixed detection slip post 201 that sets up on insurance depression bar 114, detects slip post 201 slip and sets up on support 3, detects slip post 201 slip and sets up on detecting friction disc 202, detects friction disc 202 slip and sets up on detecting rotation post 206, detects rotation post 206 and detects friction disc 202 and pass through spline connection, detects rotation post 206 rotation and sets up on support 3. The detection stationary blade 207 is all fixed to the both ends of detecting the rotation post 206, detects and rotates on the stationary blade 207 and is provided with detection U-shaped piece 208, detects U-shaped piece 208 rotation and sets up on detecting the rotation post one 209, detects the rotation post one 209 rotation and sets up on support 3. The first detection rotating column 209 is fixedly provided with a detection conical block 210, and the detection conical block 210 is fixedly provided with a detection ring 212 and a detection storage tank 211. The detection friction disc 202 is in friction fit with the detection arc disc 203, the detection arc disc 203 is arranged on an output shaft of the detection motor 204 in a sliding mode, a detection spring 205 is movably arranged between the detection arc disc 203 and the detection motor 204, and the detection arc disc 203 is connected to the output shaft of the detection motor 204 through a spline. The fixed sheave 213 is fixedly provided on the fixed plate 5.

The utility model discloses a high-temperature cable high-temperature-resistant detection device, which has the following working principle: taking fig. 3 as an example and combining with other drawings, the to-be-tested cable 4 is wound on the detection ring 212 and the fixing wheel 213, one end of the to-be-tested cable 4 is fixed on the first cable fixing screw 128, and the other end of the to-be-tested cable 4 is fixed on the second cable fixing screw 129.

Taking fig. 7 as an example and combining with other figures, the safety push rod 101 is manually pushed, the safety push rod 101 drives the safety slide block 102 to move upwards, the safety slide block 102 pushes the safety first clamping block 104 to rotate clockwise, at the moment, the safety first clamping block 104 is separated from the safety first limiting block 105, the safety first limiting block 105 rotates clockwise under the action of the safety second spring 121, so that the safety first limiting block 105 is separated from the safety rotating disc 112, the safety energy storage spring 116 pulls the safety rotating post 115, the safety rotating post 115 pulls the safety cam 113, so that the safety cam 113 drives the safety rotating disc 112 to rotate anticlockwise, when the safety cam 113 rotates to a preset position, the safety cam 113 contacts with the safety moving plate 110, the safety moving plate 110 is pushed to rotate clockwise, at the moment, the safety arc-shaped piece 111 is separated from the safety first limiting block 108, the safety second limiting block 108 rotates anticlockwise under the action of the safety first spring 120, the safety moving plate 103 is driven to rotate clockwise, the safety moving plate 102 is separated from the safety moving plate 103, and the safety moving block 102 is driven to rotate anticlockwise to be separated from contact with the safety first clamping block 104 under the action of the safety energy storage spring 116, and operators are prevented from being injured by the safety push rod 101; meanwhile, when the second safety limiting block 108 rotates, the second safety limiting block 108 is separated from contact with the first safety contact block 107, and under the action of the safety wiring spring 119, the second safety wiring post 118 is pushed to contact with the first safety contact block 107, and the second safety contact block 107 rotates anticlockwise to contact with the first safety wiring post 106; at this time, the first safety lock nut 123, the second safety wire 127 connected to the second safety lock nut 124, and the first safety wire 125 form a path, so that the current in the safety power supply 126 returns to the safety power supply 126 through the first safety wire 125, the second cable fixing screw 129, the first cable 4 to be tested, and then passes through the first cable fixing screw 128, the second safety wire 127, the first safety lock nut 123, the second safety terminal 118, the safety contact block 107, the first safety terminal 106, the second safety lock nut 124, and the first safety wire 125, so as to simulate the power-on state of the cable 4 to be tested in actual operation.

Taking fig. 7 as an example and combining with other drawings, when the safety pulling piece 110 rotates clockwise, the safety pulling rod 114 is pushed to slide downwards, the safety pulling rod 114 pushes the detection sliding column 201 to drive the detection friction disc 202 to slide downwards, so that the arc surface on the detection friction disc 202 contacts with the arc surface on the detection arc disc 203, at this time, the detection motor 204 drives the detection arc disc 203, the detection arc disc 203 rotates to drive the detection friction disc 202, the detection friction disc 202 rotates to drive the detection rotating column 206, the detection rotating column 206 drives the detection fixing pieces 207 arranged at two ends of the detection rotating column 206 to rotate, the detection fixing pieces 207 rotate to drive the detection U-shaped piece 208, the detection U-shaped piece 208 drives the detection rotating column one 209 to swing, the detection rotating column one 209 swings to drive the detection conical block 210, the detection ring 212 and the detection storage tank 211 to detect the circle center reciprocating swing of the first 209, and the detection ring 212 heats the cable 4 to be tested when swinging, so as to realize the temperature cycle test of the cable 4 to be tested.

Taking fig. 3 as an example and combining with other figures, the detection ring 212 near the lower end intermittently heats and cools the cable 4 to be tested, and rapidly changes the temperature of the cable 4 to be tested near the detection ring 212, so as to realize a high-low temperature impact test of the cable 4 to be tested; the high-temperature detection of the cable to be tested 4 is realized by recording the current change of the testing process and the observation of the cable to be tested 4 by an operator through the safety power supply 126.

Taking fig. 7 as an example and combining with other drawings, on the contrary, when the test is finished, the safety cylinder 109 pushes the safety stirring plate 110 to rotate, so that the safety arc plate 111 contacts with the safety limiting block two 108 again, the safety limiting block two 108 resets, so that the safety contact block 107 is separated from the safety binding post one 106, the circuit is in an open circuit state, the cable 4 to be tested is not electrified, the safety stirring plate 110 pulls the safety pressing rod 114 to enable the detection sliding column 201 and the detection friction plate 202 to reset when rotating, the detection friction plate 202 is separated from contact with the detection arc plate 203, and the detection ring 212 stops working, so as to finish the detection of the cable 4 to be tested.

When the cable to be detected is required to be detected again, the safety handle 117 is manually rotated, so that the safety handle 117 drives the safety rotating disc 112 and the safety cam 113 to be positioned at the position shown in fig. 7, and the steps are repeated, and the cable to be detected is detected again.

Claims (1)

1. The utility model provides a high temperature cable high temperature resistant detection device, includes support (3), fixed plate (5), its characterized in that: the safety device further comprises a safety component (1) and a detection component (2), wherein the safety component (1) is rotatably arranged on the bracket (3), and the fixing plate (5) is fixedly arranged on the bracket (3); the detection component (2) is arranged on the bracket (3) in a sliding way; the safety assembly (1) comprises a safety rotating disc (112) which is rotatably arranged on the bracket (3), a safety cam (113) and a safety handle (117) are fixedly arranged on the safety rotating disc (112), a safety rotating column (115) is rotatably arranged on the safety cam (113), a safety energy storage spring (116) is movably arranged on the other side of the safety rotating column (115), and the other end of the safety energy storage spring (116) is fixedly arranged on the bracket (3); the safety rotating disc (112) is in sliding fit with a first safety limiting block (105) movably arranged on the support (3), the first safety limiting block (105) is in sliding fit with a first safety clamping block (104) movably arranged on the support (3), the first safety clamping block (104) is in sliding fit with a safety sliding block (102) movably arranged on the support (3), the safety sliding block (102) is rotatably arranged on the safety push rod (101), the safety push rod (101) is slidably arranged on the support (3), the safety sliding block (102) is in sliding fit with a second safety limiting block (108) rotatably arranged on the support (3), and the safety sliding block (103) is in sliding fit with a second safety limiting block (108) movably arranged on the support (3);

the second safety limiting block (108) is in sliding fit with a safety contact block (107) movably arranged on the bracket (3), the safety contact block (107) is in sliding fit with a first safety binding post (106) fixedly arranged on a second safety locking nut (124), the safety contact block (107) is in sliding fit with a second safety binding post (118) slidably arranged on a first safety locking nut (123), and a safety wiring spring (119) is arranged between the second safety binding post (118) and the first safety locking nut (123); a safety wire II (127) is fixedly arranged on the safety lock nut I (123), a safety wire I (125) is fixedly arranged on the safety lock nut II (124), and the safety wire I (125) is fixedly arranged on the safety power supply (126); the other end of the second safety wire (127) is fixedly arranged on the first cable fixing screw (128), and the other end of the first safety wire (125) is fixedly arranged on the second cable fixing screw (129);

the safety cam (113) is in sliding fit with the safety stirring piece (110), the safety stirring piece (110) is fixedly provided with a safety arc piece (111), the safety arc piece (111) is in sliding fit with the safety limiting block II (108), the safety stirring piece (110) is movably provided with a safety cylinder (109), the other side of the safety cylinder (109) is rotatably arranged on the bracket (3), and the safety stirring piece (110) is slidably provided with a safety compression bar (114);

a third safety spring (122) is fixedly arranged between the first safety clamping block (104) and the bracket (3), a second safety spring (121) is fixedly arranged between the first safety limiting block (105) and the bracket (3), and a first safety spring (120) is fixedly arranged between the second safety limiting block (108) and the bracket (3);

the detection assembly (2) is fixedly arranged at the other end of the safety pressing rod (114), the detection assembly (2) comprises a detection sliding column (201) fixedly arranged on the safety pressing rod (114), the detection sliding column (201) is arranged on the support (3) in a sliding mode, the detection sliding column (201) is arranged on the detection friction disc (202) in a sliding mode, the detection friction disc (202) is arranged on the detection rotating column (206) in a sliding mode, the detection rotating column (206) is connected with the detection friction disc (202) through a spline, and the detection rotating column (206) is arranged on the support (3) in a rotating mode;

the two ends of the detection rotating column (206) are fixedly provided with detection fixing sheets (207), the detection fixing sheets (207) are rotatably provided with detection U-shaped sheets (208), the detection U-shaped sheets (208) are rotatably arranged on a detection rotating column I (209), and the detection rotating column I (209) is rotatably arranged on the bracket (3);

a detection conical block (210) is fixedly arranged on the first detection rotating column (209), and a detection ring (212) and a detection storage tank (211) are fixedly arranged on the detection conical block (210);

the detection friction disc (202) is in friction fit with the detection arc disc (203), the detection arc disc (203) is arranged on an output shaft of the detection motor (204) in a sliding mode, a detection spring (205) is movably arranged between the detection arc disc (203) and the detection motor (204), and the detection arc disc (203) is connected to the output shaft of the detection motor (204) through a spline.