CN215768891U - Intelligent comprehensive detection device for high-voltage switch - Google Patents

Abstract

The utility model relates to a high tension switchgear intelligence comprehensive testing device, it includes that one side open-ended cabinet body and switch mechanical properties detect the module, the internal baffle that is provided with of cabinet, the baffle separates the cabinet body for mounting groove and storing groove, switch mechanical properties detects the module and locates in the mounting groove, the storing inslot is provided with the mounting bracket, be provided with the product simulation frock of being connected with switch mechanical properties detection module electricity on the mounting bracket, the product simulation frock includes that frock body and level rotate the closing shaft that sets up on the frock body, be provided with on the frock body and be used for carrying out the fixture fixed to operating device. Through setting up the product simulation frock that is connected with switch mechanical properties detection module to replace entity load switch or entity circuit breaker to accomplish many times separating brake and combined floodgate operation through product simulation frock, thereby make testing personnel to operating device examine time measuring, circuit breaker or load switch can not receive the damage, and then have good guard action to circuit breaker or load switch.

Description

Intelligent comprehensive detection device for high-voltage switch

Technical Field

The application relates to the field of detection devices, in particular to an intelligent comprehensive detection device for a high-voltage switch.

Background

The switch cabinet is an electric device, the outside line of the switch cabinet firstly enters a main control switch in the cabinet and then enters a branch control switch, and each branch is arranged according to the requirement, such as an instrument, an automatic control, a motor magnetic switch, various alternating current contactors and the like. The main function of the switch cabinet is to open and close, control and protect electric equipment in the process of power generation, power transmission, power distribution and electric energy conversion of an electric power system. The components in the switch cabinet mainly comprise a circuit breaker, a disconnecting switch, a load switch, an operating mechanism, a mutual inductor, various protection devices and the like.

The load switch and the breaker are both used for closing and breaking a circuit, corresponding operating mechanisms are mounted in front of the load switch and the breaker, closing and grading mechanical operations of contacts are achieved through the operating mechanisms, and the purpose of opening and closing the circuit is achieved.

Before the circuit breaker or the load switch is used, the performance of an operating mechanism of the circuit breaker or the load switch is generally checked to determine whether the operating mechanism is qualified. The detection device in the related art usually adopts a switch mechanical characteristic tester, and when the operating mechanism of the load switch or the circuit breaker needs to be detected, a detection terminal of the switch mechanical characteristic tester is usually connected with the circuit breaker or the load switch, and then the switch mechanical characteristic tester is used for detecting the operating mechanism of the circuit breaker or the load switch.

The operating shaft of the operating mechanism is usually in insertion fit with the switching-on shaft of the load switch or the switching-on shaft of the circuit breaker, and when the operating mechanism needs to be subjected to related performance detection, the operating shaft of the operating mechanism is usually used for controlling the switching-on shaft of the load switch or the switching-on shaft of the circuit breaker to perform forward or reverse reciprocating rotation, so that switching-off and switching-on of the load switch or the circuit breaker are realized. Subsequently, the detection data of the operating mechanism is read, so that the performance detection of the operating mechanism is realized.

In view of the above-mentioned related technologies, when the performance of the operating mechanism is detected, the load switch or the circuit breaker needs to perform the opening and closing operations many times, so that the damage to the load switch or the circuit breaker is large and needs to be improved.

SUMMERY OF THE UTILITY MODEL

In order to improve the problem that load switch or circuit breaker damaged easily, this application provides a high-voltage switch intelligent integrated detection device.

The application provides a pair of high-voltage switch intelligent comprehensive detection device adopts following technical scheme:

the utility model provides a high tension switchgear intelligence integrated detection device, include one side open-ended cabinet body and set up in the internal switch mechanical properties of cabinet detects the module, the internal baffle that is provided with of cabinet, the baffle will the inside of the cabinet body separates for mounting groove and storing groove in proper order, switch mechanical properties detect the module set up in the mounting groove, the storing inslot is provided with the mounting bracket, be provided with on the mounting bracket with the product simulation frock that switch mechanical properties detect the module electricity and connect, product simulation frock include frock body and level rotate set up in closing the floodgate axle on the frock body, be provided with on the frock body and be used for carrying out the fixture fixed to operating device.

By adopting the technical scheme, when the performance of the operating mechanism needs to be detected, the operating shaft of the operating mechanism is in insertion fit with the brake closing shaft on the product simulation tool, and then the operating mechanism is fixed by the clamping mechanism. And then, the switching-on shaft is controlled to rotate forwards or backwards in a reciprocating way by rotating the operating shaft of the operating mechanism, so that the switching-off and switching-on operations of the product simulation tool are realized. And then, the data on the switch mechanical characteristic detection module can be read, so that the performance test of the operating mechanism is realized.

The product simulation tool connected with the switch mechanical characteristic detection module is arranged, and the product simulation tool replaces an entity load switch or an entity breaker to complete multiple brake opening and closing operations. When a detector detects the operating mechanism, the operating shaft of the operating mechanism is only required to be rotated to control the closing shaft of the product simulation tool to rotate forwards or backwards in a reciprocating manner, and the conditions required by the operating mechanism during detection can be met. Therefore, when the operating mechanism is detected by detection personnel, the operating mechanism does not need to be detected on the solid circuit breaker or the solid load switch, so that the circuit breaker or the load switch is not damaged, and the circuit breaker or the load switch has a good protection effect.

When the breaker main body or the load switch main body needs to be detected, only the detection terminal of the switch mechanical characteristic detection module is connected with the breaker main body or the load switch main body, and then performance detection can be carried out on the breaker main body or the load switch main body through the switch mechanical characteristic detection module. The design enables the detection device to detect the breaker main body or the load switch main body and detect the operating mechanism independently, so that the integration capability of the detection device is improved. Meanwhile, the design can also enable the detection device to be more compact, so that the installation space required by the detection device is reduced, and the practicability is improved.

Optionally, the mounting rack is movably arranged in the storage groove.

Through adopting above-mentioned technical scheme, because the mounting bracket can be followed the storing groove and taken out to make testing personnel can carry out quick replacement to subassemblies such as product simulation frock, thereby make the user can detect the product of difference, and then improve and use the suitability. Meanwhile, the product simulation tool can be independently maintained or detected due to the design, so that the maintenance convenience is improved, and the practicability is improved.

Optionally, the bottom of the cabinet body is open and the mounting rack is placed on the ground, and a gap is formed between the surface of the mounting rack and the inner wall of the storage groove.

Through adopting above-mentioned technical scheme, because equal space between the inner wall in surface and the storing groove of mounting bracket reduces the risk that parts such as product simulation frock and the cabinet body take place to collide with. The design can reduce the possibility that the product simulation tool is damaged, has a good protection effect on parts such as the product simulation tool and the like, and further improves the use stability of the detection device.

Optionally, the tool body is horizontally slidably arranged on the mounting frame, and a driving piece used for driving the tool body to extend out of the storage groove is arranged on the mounting frame.

Through adopting above-mentioned technical scheme, can enter into the internal frock body of cabinet through the setting, when testing personnel detected operating device, can utilize the driving piece to promote the frock body internal with the cabinet. This design effectively reduces other personnel and miss the risk that touches operating device or operating device and receive to collide with to operating device has good protection effect, and then improves detection device's stability in use.

Optionally, the driving part is a first screw rod horizontally and rotatably arranged on the mounting frame, the first screw rod penetrates through the tool body and forms a threaded fit with the tool body, and a driving mechanism used for driving the first screw rod to rotate is arranged on the mounting frame.

By adopting the technical scheme, the first screw rod is driven to rotate by utilizing the driving mechanism, and then the first screw rod can drive the tool body to drive the operating mechanism to move horizontally. Through setting up simple structure, simple operation, the stable driving piece of drive effect, realize operating device's quick motion to the work efficiency when operating device detects is improved.

Optionally, a supporting block is vertically slidably arranged on the mounting frame, an operating sleeve is horizontally and rotatably arranged on the supporting block, the operating sleeve is used for being matched with an operating shaft on the operating mechanism in an inserting manner, a control mechanism used for driving the operating sleeve to rotate is arranged on the supporting block, and a control piece used for driving the supporting block to vertically move is arranged on the mounting frame.

By adopting the technical scheme, when the operating mechanism enters the cabinet body, the supporting block is driven by the control piece to drive the operating sleeve to move upwards, and the operating sleeve is aligned with the operating shaft on the operating mechanism. Then, the tool body is utilized to drive the operating mechanism to move towards the supporting block, and the operating shaft on the operating mechanism is in insertion fit with the operating sleeve. Then, drive the sleeve through management and control mechanism and drive the reciprocating rotation of control axle and closing shaft, afterwards, can realize the automatic switching-off and the closing operation of product simulation frock. This design benefit for the measurement personnel need not manual control closing shaft reciprocating rotation, can reduce measurement personnel's work burden, can improve the work efficiency when examining operating device again.

Optionally, the control element is a second lead screw vertically and rotatably arranged on the mounting frame, the second lead screw penetrates through the supporting block and forms threaded fit with the supporting block, and a control mechanism for driving the second lead screw to rotate is arranged on the mounting frame.

By adopting the technical scheme, the control mechanism is utilized to drive the second screw rod to rotate, and then the second screw rod can drive the supporting block to drive the control sleeve to vertically move. Through setting up the control that the structure is succinct, the operation of being convenient for, drive effect are stable for the control sleeve can aim at the control axle fast, thereby further improves the work efficiency when examining operating device.

Optionally, the cabinet body is hinged with a cabinet door used for closing the port of the storage groove, and the cabinet door is provided with a yielding hole for the tool body to pass through.

Through adopting above-mentioned technical scheme, can carry out confined cabinet door to the port in storing groove through the setting to shield subassembly such as mounting bracket and product simulation frock through the cabinet door, effectively reduce and control subassembly such as sleeve and product simulation frock and receive the risk that external force collided with. Therefore, the protection device has a good protection effect on the detection device, and further improves the use stability and the service life of the detection device.

Optionally, the cabinet door is vertically slidably provided with a baffle used for shielding the receding hole, and the cabinet door is provided with an adjusting part used for driving the baffle to vertically move.

Through adopting above-mentioned technical scheme, can carry out the baffle that shields to the hole of stepping down through the setting, when operating device was located the cabinet internally, the measurement personnel can close the cabinet door to utilize the baffle to seal the hole of stepping down, thereby have good syllable-dividing effect. This design can be isolated to the noise that operating device produced, and then has good guard action to measurement personnel.

Optionally, the adjusting part is a third screw rod vertically rotatably arranged on the cabinet door, the third screw rod penetrates through the baffle and forms a threaded fit with the baffle, and a power part for driving the third screw rod to rotate is arranged on the cabinet door.

By adopting the technical scheme, the third screw rod is driven to rotate by the power part, and then the third screw rod can be utilized to drive the baffle to vertically move. Through setting up simple structure, the regulating part of being convenient for operation, realize opening and close fast of hole of stepping down to improve work efficiency.

In summary, the present application includes at least one of the following beneficial technical effects:

the product simulation tool connected with the switch mechanical characteristic detection module is arranged, and the product simulation tool replaces an entity load switch or an entity breaker to complete multiple switching-off and switching-on operations, so that the breaker or the load switch is not damaged when a detector detects the operating mechanism, and the breaker or the load switch is well protected;

by arranging the tool body which can enter the cabinet body, the risk that other personnel touch the operating mechanism by mistake or the operating mechanism is collided is effectively reduced, so that the operating mechanism is well protected, and the use stability of the detection device is improved;

the operating shaft on the operating mechanism is controlled by the operating sleeve to drive the switching-on shaft to rotate in a reciprocating mode, automatic switching-off and switching-on operations of the product simulation tool are achieved, and therefore detection personnel do not need to manually control the operating shaft on the operating mechanism to rotate, the workload of the detection personnel can be reduced, and the work efficiency during detection of the operating mechanism can be improved.

Drawings

Fig. 1 is a schematic overall structure diagram of an embodiment of the present application.

Fig. 2 is a schematic view of the internal structure of the cabinet in the embodiment of the present application.

Fig. 3 is a schematic structural view of the embodiment of the present application in a use state, and shows a state where casters are disposed at the bottom of the mounting frame.

Fig. 4 is a schematic structural diagram of a mounting frame in the embodiment of the present application.

Fig. 5 is a schematic structural diagram of a product simulation tool in an embodiment of the present application.

Fig. 6 is a schematic structural diagram of a cabinet door in an embodiment of the present application.

FIG. 7 is a schematic view of the structure of the support block in the embodiment of the present application.

Fig. 8 is a schematic structural diagram of a control mechanism in the embodiment of the present application.

Fig. 9 is a schematic structural diagram of a control mechanism in the embodiment of the present application.

Description of reference numerals: 1. a cabinet body; 2. a partition plate; 3. mounting grooves; 4. a storage tank; 7. a switch mechanical characteristic detection module; 8. a mounting frame; 9. a product simulation tool; 91. a tool body; 92. a switching-on shaft; 10. a clamping mechanism; 101. a cylinder; 102. a support frame; 103. a compression post; 11. a support post; 12. positioning pins; 13. a first lead screw; 14. a drive mechanism; 141. a first drive wheel; 142. a first driven wheel; 15. a first positive and negative rotation motor; 16. a first belt; 17. a cabinet door; 18. a hole of abdication; 19. a baffle plate; 20. a third screw rod; 21. a third positive and negative rotation motor; 22. a support block; 23. a steering sleeve; 24. a management and control mechanism; 241. a fourth positive and negative rotation motor; 242. a drive gear; 243. a first driven gear; 25. a second lead screw; 26. a control mechanism; 261. a second drive wheel; 262. a second driven wheel; 27. a second positive and negative rotation motor; 28. a second belt; 29. a grounding sleeve; 30. a second driven gear; 31. and a caster.

Detailed Description

The present application is described in further detail below with reference to figures 1-9.

The embodiment of the application discloses high-voltage switch intelligent comprehensive detection device. Referring to fig. 1 and 2, high-voltage switch intelligent comprehensive detection device includes one side open-ended cabinet body 1, the horizontal fixedly connected with baffle 2 of the inner wall of the cabinet body 1 to the circumference lateral wall of baffle 2 and the three side inner wall fixed connection of the cabinet body 1, thereby make baffle 2 separate the inside of the cabinet body 1 for mounting groove 3 and storing groove 4 from top to bottom.

Referring to fig. 2 and 3, the upper end surface of the partition board 2 is provided with a switch mechanical characteristic detection module 7 located in the mounting groove 3, and the switch mechanical characteristic detection module 7 includes a switch mechanical characteristic tester, a power supply and a control panel, so that a detection person can perform performance detection on the breaker main body or the load switch main body by using the switch mechanical characteristic detection module 7.

Referring to fig. 2 and 3, the bottom of the cabinet 1 is open, and a mounting rack 8 is movably disposed in the storage tank 4 and the mounting rack 8 is placed on the ground. Meanwhile, the mounting bracket 8 can be taken out of the storage groove 4, and the caster 31 with a brake can be mounted at the lower end of the mounting bracket 8, so that the mounting bracket 8 can be conveniently carried.

Referring to fig. 4 and 5, a product simulation tool 9 is provided at an upper end of the mounting frame 8, and the product simulation tool 9 is formed by re-engraving a solid load switch or a solid circuit breaker, so that a tester can replace the solid load switch or the solid circuit breaker with the product simulation tool 9. Meanwhile, the product simulation tool 9 is made of a more durable material, so that the service life of the product simulation tool 9 is prolonged.

Referring to fig. 4 and 5, the product simulation tool 9 includes a tool body 91 disposed on the mounting frame 8, a switching-on shaft 92 is horizontally and rotatably connected to the tool body 91, and the switching-on shaft 92 is used for controlling the tool body 91 to perform switching-off and switching-on. Meanwhile, the end of the tool body 91 is provided with a clamping mechanism 10 for fixing the operating mechanism.

Referring to fig. 1 and 5, the tool body 91 is electrically connected to the switching mechanical characteristic detection module 7, so that the switching mechanical characteristic detection module 7 can collect data of the tool body 91.

When the performance of the operating mechanism is detected, the clamping mechanism 10 is used for fixing the operating mechanism, and the operating shaft of the operating mechanism is in insertion fit with the closing shaft 92 on the product simulation tool 9. Then, the operating shaft of the rotating operating mechanism drives the switching-on shaft 92 to rotate forward or backward, so that switching-off and switching-on operations of the product simulation tool 9 are realized. Then, the data on the switch mechanical characteristic detection module 7 can be read, so that the performance test of the operating mechanism is realized.

Referring to fig. 5, the clamping mechanism 10 includes a plurality of cylinders 101 fixedly embedded at the end of the tool body 91, and a supporting frame 102 is fixedly connected to the end surface of each cylinder 101 at one side of the piston end. Each support frame 102 is provided with a pressing column 103, and the middle position of the pressing column 103 is hinged with the corresponding support frame 102. One end of each compression column 103 is hinged to the corresponding piston end of the cylinder 101, and the other end is used for abutting against the end of the tool body 91.

When the operating mechanism is placed at the end of the tool body 91, the piston end of the cylinder 101 extends and causes the corresponding hold-down column 103 to turn around the corresponding support bracket 102. Then, the end of the pressing column 103, which is far away from the piston end of the cylinder 101, can press the operating mechanism on the tool body 91, so as to fix the operating mechanism.

Referring to fig. 5, the end of the tool body 91 is horizontally and fixedly connected with a plurality of receiving posts 11, the plurality of receiving posts 11 are parallel to each other, and the operating mechanism is placed on the plurality of receiving posts 11 to support the operating mechanism. Meanwhile, the end of the tool body 91 is fixedly connected with a plurality of positioning pins 12 which are used for being matched with the connecting holes in the operating mechanism, so that the placing position of the operating mechanism can be quickly determined.

Referring to fig. 2 and 4, the tool body 91 is horizontally connected to the mounting frame 8, and the tool body 91 can drive the operating mechanism to extend out of the storage groove 4 or enter the storage groove 4, so as to protect the operating mechanism. Meanwhile, a driving member for driving the tool body 91 to horizontally move is arranged on the mounting frame 8. The driving piece is a first screw rod 13 horizontally and rotatably connected to the mounting frame 8, and the first screw rod 13 penetrates through the tool body 91 and forms threaded fit with the tool body 91. When the first lead screw 13 rotates, the first lead screw 13 can drive the tool body 91 to horizontally slide.

Referring to fig. 4, in order to realize the quick adjustment of the position of the tool body 91, a driving mechanism 14 for driving the first lead screw 13 to rotate is disposed on the mounting frame 8. The mounting frame 8 is fixedly connected with a first forward and reverse rotation motor 15, and the driving mechanism 14 comprises a first driving wheel 141 fixedly sleeved on an output shaft of the first forward and reverse rotation motor 15. A first driven wheel 142 is fixedly sleeved on the end part of the first screw rod 13 close to one end of the first forward and reverse rotation motor 15, and the first driving wheel 141 and the first driven wheel 142 are connected through a first belt 16. When the first forward and reverse rotation motor 15 drives the first driving wheel 141 to drive the first belt 16 to move, the first belt 16 can drive the first driven wheel 142 to drive the first lead screw 13 to rotate.

Referring to fig. 1 and 2, a cabinet door 17 for closing a port of the storage tank 4 is hinged to the cabinet body 1 to protect components such as an operating mechanism.

Referring to fig. 1 and 4, a concession hole 18 for the tool body 91 to pass through is formed in the cabinet door 17, so that a detector can assemble the operating mechanism on the tool body 91 conveniently.

Referring to fig. 1 and 6, a baffle 19 for shielding the abdicating hole 18 is vertically and slidably connected to the inner side wall of the cabinet door 17 to realize the protection and sound insulation capability of the operating mechanism. Meanwhile, the cabinet door 17 is provided with an adjusting member for driving the baffle plate 19 to vertically move. The adjusting piece is a third screw rod 20 vertically and rotatably connected to the inner side wall of the cabinet door 17, and the third screw rod 20 penetrates through the baffle 19 and forms threaded fit with the baffle 19. When the third screw rod 20 rotates, the third screw rod 20 can drive the baffle 19 to move vertically.

Referring to fig. 1 and 6, in order to realize the quick adjustment of the position of the baffle 19, a power member for driving the third screw rod 20 to rotate is arranged on the cabinet door 17. The power part is a third forward and reverse rotating motor 21 fixedly connected to the inner side wall of the cabinet door 17, and an output shaft of the third forward and reverse rotating motor 21 is fixedly connected with the lower end part of the third screw rod 20, so that stable driving force is provided for the rotation of the third screw rod 20.

Referring to fig. 4 and 7, a support block 22 is vertically slidably connected to a side wall of the mounting frame 8, and a manipulation sleeve 23 is horizontally rotatably connected to the support block 22.

Referring to fig. 5 and 7, the operating sleeve 23 is adapted to engage with an operating shaft of the operating mechanism, so that the operating sleeve 23 can rotate the operating shaft and the closing shaft 92.

Referring to fig. 5 and 7, the mounting bracket 8 is provided with a control member for driving the support block 22 to move vertically so that the steering sleeve 23 can be quickly aligned with the steering shaft. Meanwhile, the supporting block 22 is provided with a regulating mechanism 24 for driving the operation sleeve 23 to rotate, so as to realize rapid rotation of the closing shaft 92.

Referring to fig. 7 and 8, the control element is a second screw rod 25 vertically and rotatably connected to the mounting frame 8, and the second screw rod 25 penetrates through the supporting block 22 and forms a threaded fit with the supporting block 22. When the second screw 25 rotates, the second screw 25 drives the supporting block 22 to move vertically.

Referring to fig. 7 and 8, in order to realize the quick adjustment of the position of the supporting block 22, a control mechanism 26 for driving the second lead screw 25 to rotate is provided on the mounting frame 8. The side wall of the mounting bracket 8 is fixedly connected with a second forward and reverse rotation motor 27, and the control mechanism 26 comprises a second driving wheel 261 fixedly sleeved on an output shaft of the second forward and reverse rotation motor 27. The lower end of the second screw 25 is fixedly sleeved with a second driven wheel 262, and the second driving wheel 261 and the second driven wheel 262 are connected by a second belt 28. When the second forward and reverse rotation motor 27 drives the second driving wheel 261 to drive the second belt 28 to move, the second belt 28 can drive the second driven wheel 262 to drive the second lead screw 25 to rotate.

Referring to fig. 9, the regulating mechanism 24 includes a fourth forward/reverse rotation motor 241 fixedly connected to the side wall of the supporting block 22, and a driving gear 242 is fixedly sleeved on an output shaft of the fourth forward/reverse rotation motor 241. The operating sleeve 23 is fixedly sleeved with a first driven gear 243 engaged with the driving gear 242, so that when the output shaft of the fourth forward/reverse motor 241 drives the driving gear 242 to rotate, the driving gear 242 can drive the first driven gear 243 to drive the operating sleeve 23 to rotate.

Referring to fig. 8 and 9, a grounding sleeve 29 is horizontally and rotatably connected to a side wall of the support block 22 on the side of the operating sleeve 23, and the grounding sleeve 29 is used for being in plug-in fit with a grounding shaft on the operating mechanism. Therefore, when the operating mechanism completes detection, a detector can drive the grounding shaft to rotate through the grounding sleeve 29, and electric energy in the operating mechanism is released quickly.

Referring to fig. 3 and 9, the grounding sleeve 29 is located directly below the steering sleeve 23, and the center distance between the grounding sleeve 29 and the steering sleeve 23 is larger than the center distance between the steering shaft and the grounding shaft on the operating mechanism. So that the operating sleeve 23 is offset from the operating shaft when the earthing sleeve 29 is aligned with the earthing shaft, and the earthing sleeve 29 is offset from the earthing shaft when the operating sleeve 23 is aligned with the operating shaft, to achieve protection of the operating structure.

Referring to fig. 8 and 9, a second driven gear 30 engaged with the driving gear 242 is fixedly sleeved on the grounding sleeve 29, and the driving gear 242 is located between the first driven gear 243 and the second driven gear 30, so that the driving gear 242 can simultaneously drive the first driven gear 243 and the second driven gear 30 to synchronously rotate.

Referring to fig. 2 and 4, since the mounting frame 8 can be taken out of the storage groove 4, the detection personnel can pull the mounting frame 8 to drive the tool body 91 and the supporting block 22 to move, and the detection personnel can replace the product simulation tool 9 and other parts, so as to improve the use adaptability of the detection device. Simultaneously, there is the clearance all in each part that is located storing tank 4 and the inside wall of the inner wall of the cabinet body 1 and cabinet door 17 to avoid each part that is located storing tank 4 and the cabinet body 1 to appear colliding with.

The implementation principle of the intelligent comprehensive detection device for the high-voltage switch in the embodiment of the application is as follows: when the performance of the physical circuit breaker or the physical load switch needs to be detected, the detection terminal of the switch mechanical characteristic detection module 7 is connected with the circuit breaker main body or the physical load switch. Subsequently, the switch mechanical characteristic detection module 7 can detect the performance of the physical circuit breaker or the physical load switch.

When the operating mechanism needs to be detected, the operating mechanism is placed on the plurality of bearing columns 11, the pressing columns 103 are used for pressing the operating mechanism on the tool body 91, and meanwhile, the operating shaft of the operating mechanism is in inserting fit with the closing shaft 92 on the product simulation tool 9. Then, the first forward and reverse rotation motor 15 drives the first driving wheel 141 to drive the first belt 16 to move, and then the first belt 16 drives the first driven wheel 142 to drive the first lead screw 13 to rotate forward. Subsequently, the tool body 91 is driven by the first lead screw 13 to drive the operating mechanism and other components to enter the cabinet 1.

Subsequently, the second driving wheel 261 is driven by the second forward and reverse rotation motor 27 to drive the second belt 28 to move, and the second driven wheel 262 is driven by the second belt 28 to drive the second lead screw 25 to rotate in the forward direction. Subsequently, the support block 22 is driven by the second lead screw 25 to move the operating sleeve 23 and other components vertically upwards, and the operating sleeve 23 is aligned with the operating shaft on the operating mechanism. Then, the first forward and reverse rotation motor 15 drives the first driving wheel 141 to drive the first belt 16 to move, and then the first belt 16 drives the first driven wheel 142 to drive the first lead screw 13 to rotate reversely. Subsequently, the tool body 91 is driven by the first lead screw 13 to drive components such as an operating mechanism and the like to move towards the supporting block 22, and the operating sleeve 23 is in plug fit with an operating shaft on the operating mechanism.

Subsequently, the third screw rod 20 is driven to rotate by the third forward and reverse rotation motor 21, and the baffle 19 is driven to move upwards by the third screw rod 20, so that the yielding hole 18 is sealed by the baffle 19. Then, the output shaft of the fourth forward/reverse rotation motor 241 drives the driving gear 242 to rotate, and the driving gear 242 drives the first driven gear 243 to rotate the operating sleeve 23. Next, the operating sleeve 23 can drive the operating shaft on the operating mechanism to drive the switching-on shaft 92 to perform forward and reverse reciprocating rotation, so as to realize switching-off and switching-on operations of the product simulation tool 9, and then the data of the switch mechanical characteristic detection module 7 can be read, so that the performance detection of the operating mechanism is realized.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. The utility model provides a high tension switchgear intelligence integrated detection device, includes one side open-ended cabinet body (1) and set up in switch mechanical properties in the cabinet body (1) detects module (7), its characterized in that: be provided with baffle (2) in the cabinet body (1), baffle (2) will the inside of the cabinet body (1) is separated for mounting groove (3) and storing groove (4) in proper order, switch mechanical characteristic detect module (7) set up in mounting groove (3), be provided with mounting bracket (8) in storing groove (4), be provided with on mounting bracket (8) with product simulation frock (9) that switch mechanical characteristic detect module (7) electricity is connected, product simulation frock (9) including frock body (91) and horizontal rotation set up in closing floodgate axle (92) on frock body (91), be provided with on frock body (91) and be used for carrying out fixed fixture (10) to operating device.

2. The intelligent comprehensive detection device for the high-voltage switch according to claim 1, characterized in that: the mounting rack (8) is movably arranged in the storage groove (4).

3. The intelligent comprehensive detection device for the high-voltage switch according to claim 2, characterized in that: the bottom of the cabinet body (1) is open and enables the mounting rack (8) to be placed on the ground, and a gap is reserved between the surface of the mounting rack (8) and the inner wall of the storage groove (4).

4. The intelligent comprehensive detection device for the high-voltage switch according to claim 1, characterized in that: the tool body (91) is horizontally arranged on the mounting rack (8) in a sliding mode, and a driving piece used for driving the tool body (91) to stretch out of the storage groove (4) is arranged on the mounting rack (8).

5. The intelligent comprehensive detection device for the high-voltage switch according to claim 4, characterized in that: the driving piece is horizontally and rotatably arranged on a first screw rod (13) on the mounting frame (8), the first screw rod (13) penetrates through the tool body (91) and forms threaded fit with the tool body (91), and a driving mechanism (14) used for driving the first screw rod (13) to rotate is arranged on the mounting frame (8).

6. The intelligent comprehensive detection device for the high-voltage switch according to claim 1, characterized in that: the vertical slip is provided with supporting shoe (22) on mounting bracket (8), supporting shoe (22) are gone up the level and are rotated and be provided with control sleeve (23), control sleeve (23) are used for carrying out the grafting cooperation with the control axle on the operating device, be provided with on supporting shoe (22) and be used for driving control sleeve (23) pivoted management and control mechanism (24), be provided with on mounting bracket (8) and be used for driving supporting shoe (22) vertical motion's control.

7. The intelligent comprehensive detection device for the high-voltage switch according to claim 6, characterized in that: the control piece is a second screw rod (25) which is vertically and rotatably arranged on the mounting frame (8), the second screw rod (25) penetrates through the supporting block (22) and forms threaded fit with the supporting block (22), and a control mechanism (26) used for driving the second screw rod (25) to rotate is arranged on the mounting frame (8).

8. The intelligent comprehensive detection device for the high-voltage switch according to claim 1, characterized in that: articulated on the cabinet body (1) have be used for right the port of storing groove (4) carries out confined cabinet door (17), offer the confession on cabinet door (17) the hole of stepping down (18) that frock body (91) passed.

9. The intelligent comprehensive detection device for the high-voltage switch according to claim 8, characterized in that: the vertical sliding on the cabinet door (17) is provided with a baffle (19) used for shielding the abdicating hole (18), and the cabinet door (17) is provided with an adjusting piece used for driving the baffle (19) to vertically move.

10. The intelligent comprehensive detection device for the high-voltage switch according to claim 9, characterized in that: the adjusting piece is a third screw rod (20) which is vertically and rotatably arranged on the cabinet door (17), the third screw rod (20) penetrates through the baffle (19) and forms threaded fit with the baffle (19), and a power piece which is used for driving the third screw rod (20) to rotate is arranged on the cabinet door (17).

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