CN221101011U - DCS cabinet fuse testing device - Google Patents

Abstract

The application relates to the technical field of testing devices and discloses a DCS cabinet fuse testing device which comprises a workbench, a conveying assembly arranged at the top of the workbench and a detection assembly arranged at the top of the workbench and close to the position of the conveying assembly, wherein the conveying assembly comprises a conveying block arranged at the top of the workbench, a conveying rod hinged to the side wall of the conveying block and a conveying clamp arranged at one end of the conveying rod far away from the conveying block, the conveying clamp is used for clamping a fuse, and the detection assembly is used for detecting the clamped fuse. The application has the effect of improving the convenience of detecting the fuse.

Description

DCS cabinet fuse testing device

Technical Field

The application relates to the technical field of testing devices, in particular to a DCS cabinet fuse testing device.

Background

In the field of power system automation, a DCS system is widely used, and the DCS system is also called a distributed control system, which is a novel computer control system relative to a centralized control system, and a cabinet for accommodating the DCS control system is called a DCS cabinet.

During operation of the circuit system, the circuit is generally protected by fuses, so that the possibility of damage to various devices of the DCS system due to short circuits and overload is reduced.

The fuse is generally required to be detected before leaving the factory, and currently, when the fuse is detected, a worker is required to detect the fuse through a detection pen.

For the related art, the inventor considers that when detecting the fuse, the worker needs to repeatedly take and put the detection pen for many times, and the defect that the detection process is complicated exists.

Disclosure of utility model

In order to improve the convenience of detecting fuses, the application provides a DCS cabinet fuse testing device.

The application provides a DCS cabinet fuse testing device, which adopts the following technical scheme:

The utility model provides a DCS rack fuse testing arrangement, includes the workstation, arranges in the transport subassembly at workstation top and arranges in the detection component that the workstation top is close to transport subassembly position in, transport subassembly is including arranging in transport piece at workstation top, articulated transport pole on transport piece lateral wall and arranging in the transport clamp that transport pole kept away from transport piece one end in, transport clamp is used for carrying out the centre gripping to the fuse, detection component is used for detecting the fuse of centre gripping.

Through adopting above-mentioned technical scheme, when needs detect the fuse, arrange the fuse in and carry the clamp inside to carry the clamp through carrying and carry out the centre gripping spacing to the fuse, then, will carry the clamp through the conveying pole and rotate towards the position that is close to detection subassembly, and stop rotating in detection position, then, make detection subassembly detect the fuse, after detecting, directly take off the fuse can, and then, promoted the convenience that the staff detected the fuse.

Optionally, the conveying assembly further comprises a conveying motor arranged on the side wall of the conveying block, a motor shaft of the conveying motor rotates to penetrate through the conveying block, and the motor shaft of the conveying motor is fixedly connected with the end part of the conveying rod.

By adopting the technical scheme, when the conveying rod is required to rotate, the motor shaft of the conveying motor drives the conveying rod to rotate, so that the convenience of rotation of the conveying rod is improved; meanwhile, the motor shaft of the conveying motor penetrates through the conveying block, and the conveying block plays a role in guiding and supporting the motor shaft of the conveying motor, so that the possibility that the motor shaft of the conveying motor bends in the working process is reduced.

Optionally, the transport clamp is including arranging in the lower grip block of conveyer rod tip and arranging in the last grip block of grip block top down, go up the grip block and be close to the one end of conveyer rod is provided with the shifting block, the shifting block is followed be close to go up the grip block to keeping away from go up the position of grip block diminishes gradually, go up the grip block with be provided with the torsional spring between the grip block down, the one end of torsional spring with go up the grip block conflict, the other end of torsional spring with the grip block conflict down, just the torsional spring is when natural state, go up the grip block with the grip block is kept away from down the one end of conveyer rod is contradicted each other.

Through adopting above-mentioned technical scheme, when needs carry out the centre gripping to the fuse, press the shifting block, make the shifting block be close to the one end of conveyer rod and contradict with lower grip block, then, place the fuse between grip block and the lower grip block to make grip block and lower grip block carry out the centre gripping to the fuse under the elasticity effect of torsional spring, thereby, promoted the convenience of centre gripping fuse.

Optionally, a groove is formed in a side, close to the upper clamping block, of the lower clamping block, and a groove center of the groove is located in a side, close to the upper clamping block, of the lower clamping block.

Through adopting above-mentioned technical scheme, when carrying out the centre gripping to the fuse, arrange the fuse in inside the recess, the recess inside wall leads spacingly to the fuse to, promoted the stability of placing of fuse.

Optionally, the detection subassembly is including arranging in the detection piece at workstation top, arrange in the detection piece and be close to two measuring bars of conveying subassembly one side and arrange in the detection pen on every measuring bar, the detection piece is close to the detection groove has been seted up to the level on conveying subassembly's the lateral wall, two the measuring bar is close to the one end in detection groove is all arranged in the detection inslot portion, and every the measuring bar all with detection groove sliding fit.

Through adopting above-mentioned technical scheme, when needs detect the fuse, make two measuring bars slide in the measuring cell inside to, make the tip that detects pen and fuse contradict, and then, be convenient for to. Detecting a fuse; simultaneously, two detection poles slide in the detection groove, have promoted the adaptability of detection component to different length fuses.

Optionally, the inside detection lead screw that is provided with of detection groove, the detection lead screw is provided with two sections and revolves to opposite screw thread, two the detection pole with detect two sections screw thread one-to-one of lead screw, the detection lead screw is all threaded to be established the detection pole, be provided with the detection motor on the detection piece lateral wall, the motor shaft of detection motor wears to establish the detection piece lateral wall, just the motor shaft of detection motor with adjacent detect lead screw tip fixed connection.

By adopting the technical scheme, when the detection rod moves in the detection groove, the detection motor drives the detection screw rod to rotate, and the detection screw rod drives the detection rod to move in the detection groove, so that the convenience of moving the detection rod is improved; meanwhile, as the two detection rods are corresponding to the reverse threads at the two ends of the detection screw rod, the two detection rods are synchronously close to each other or synchronously far away from each other under the drive of the detection motor, and therefore, the fuse wire is convenient to adapt to fuses with different lengths.

Optionally, each detection rod side wall is provided with an elastic belt, and the detection pen is arranged between the elastic belt and the detection rod.

Through adopting above-mentioned technical scheme, when connecting between measuring rod and the measuring pen, the elastic webbing has promoted the adaptability to different model measuring pens under the reliable prerequisite of guaranteeing measuring rod and measuring pen connection.

Optionally, the measuring rod top is followed measuring rod length direction both sides are provided with a plurality of couples, elastic band both ends all are provided with the pull ring, the pull ring with corresponding couple grafting cooperation.

Through adopting above-mentioned technical scheme, after contradicting measuring rod and measuring pen, peg graft the cooperation with pull ring and corresponding couple to, promoted the convenience of fixed measuring pen.

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

1. When needs detect the fuse, place the fuse in and carry the clamp inside to carry the clamp through carrying and carry out the centre gripping spacing to the fuse, then, carry the clamp through the conveying pole and rotate towards the position that is close to detection assembly, and stop rotating in the detection position, then, make detection assembly detect the fuse, after detecting, directly take off the fuse can, and then, promoted the convenience that the staff detected the fuse.

2. When the conveying rod is required to rotate, the motor shaft of the conveying motor drives the conveying rod to rotate, so that the convenience of rotation of the conveying rod is improved; meanwhile, the motor shaft of the conveying motor penetrates through the conveying block, and the conveying block plays a role in guiding and supporting the motor shaft of the conveying motor, so that the possibility that the motor shaft of the conveying motor bends in the working process is reduced.

Drawings

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

Fig. 2 is a schematic diagram of a transport assembly structure embodying an embodiment of the present application.

FIG. 3 is a schematic diagram showing the structure of a detection assembly according to an embodiment of the present application.

Fig. 4 is an enlarged schematic view of the portion a in fig. 3.

Reference numerals illustrate:

01. A fuse; 1. a work table; 2. a transport assembly; 21. a transport block; 22. a conveying rod; 23. a transport clamp; 231. an upper clamping block; 232. a lower clamping block; 233. a torsion spring; 234. a shifting block; 235. a groove; 24. a conveying motor; 3. a detection assembly; 31. a detection block; 311. a detection groove; 312. detecting a screw rod; 313. detecting a motor; 32. a detection rod; 321. a placement groove; 322. a hook; 323. an elastic belt; 324. a pull ring; 33. and detecting a pen.

Detailed Description

The application is described in further detail below with reference to fig. 1-4.

The embodiment of the application discloses a device for testing a fuse of a DCS cabinet.

Referring to fig. 1, a DCS cabinet fuse testing device includes a table 1, a conveying assembly 2, and a detecting assembly 3. The conveying component 2 and the detecting component 3 are both arranged at the top of the workbench 1, the conveying component 2 and the detecting component 3 are close to each other, the conveying component 2 is used for clamping and transporting the fuse 01, and the detecting component 3 is used for detecting the fuse 01 on the conveying component 2.

Referring to fig. 1, when the fuse 01 needs to be detected, the fuse 01 is placed on the conveying component 2, and the fuse 01 is clamped by the conveying component 2, then, the fuse 01 is conveyed to the vicinity of the detecting component 3 by the conveying component 2, and the fuse 01 on the conveying component 2 is detected by the detecting component 3, so that convenience of detecting the fuse 01 by a worker is improved.

Referring to fig. 1 and 2, the transport assembly 2 includes a transport block 21, a transport rod 22, a transport clamp 23, and a transport motor 24. The conveying block 21 is arranged at the top of the workbench 1 through bolts, the conveying block 21 is a rectangular block, the conveying rod 22 is a square rod, one end of the conveying rod 22 is close to the side wall of the conveying block 21 in the length direction, and the other end of the conveying rod 22 is connected with the conveying clamp 23 through bolts. The conveying motor 24 is mounted on the other side, far away from the conveying rod 22, of the conveying block 21 through bolts, a motor shaft of the conveying motor 24 rotates to penetrate through the conveying block 21, and the motor shaft of the conveying motor 24 is connected with the end portion of the conveying rod 22 through bolts, and the conveying motor 24 is a servo motor.

Referring to fig. 1 and 2, the conveying clamp 23 includes an upper clamp block 231 and a lower clamp block 232, the upper clamp block 231 and the lower clamp block 232 are rectangular blocks, a torsion spring 233 is disposed between the upper clamp block 231 and the lower clamp block 232, one end of the torsion spring 233 abuts against the upper clamp block 231, one end of the torsion spring 233 abuts against the lower clamp block 232, and when the torsion spring 233 is in a natural state, one ends of the upper clamp block 231 and the lower clamp block 232, which are far away from the conveying rod 22, abut against each other.

Referring to fig. 1 and 2, a dial block 234 is integrally formed at one end of the upper clamping block 231 adjacent to the conveying rod 22, and an inclined surface is provided at one side of the dial block 234 adjacent to the lower clamping block 232.

Referring to fig. 1 and 2, a groove 235 is formed in a side of the lower clamping block 232 adjacent to the upper clamping block 231, the groove 235 penetrates through a lateral wall of the lower clamping block 232 in a width direction, a center of the groove 235 is located at a position of the lower clamping block 232 adjacent to the upper clamping block 231, and one side of the lower clamping block 232 adjacent to the conveying rod 22 is connected with an end portion of the conveying rod 22 through a bolt.

Referring to fig. 1, 3 and 4, the sensing assembly 3 includes a sensing block 31, a sensing rod 32 and a sensing pen 33. The detection block 31 is rectangular block setting, detection block 31 passes through the bolt mounting at workstation 1 top, detection groove 311 has been seted up to one side that workstation 1 is close to conveying component 2, detection groove 311 level sets up, detection groove 311 inside is provided with detection lead screw 312, detection lead screw 312 is provided with two sections screw threads that revolve opposite directions, and the both ends of detection lead screw 312 all rotate and wear to establish adjacent detection groove 311 inside wall, detection groove 311 lateral wall is fixed with detection motor 313 through the bolt, detection motor 313 is servo motor, the motor shaft of detection motor 313 with be adjacent detection lead screw 312 tip fixed connection.

Referring to fig. 1, 3 and 4, two detection rods 32 are provided, two detection rods 32 and two sections of threads of a detection screw rod 312 with opposite rotation directions are in one-to-one correspondence, the end part of each detection rod 32 is arranged inside a detection groove 311, the end part of each detection rod 32 is in conflict with the inner side wall of the detection groove 311, and each detection rod 32 is spirally penetrated by the detection screw rod 312.

Referring to fig. 1, 3 and 4, the standing groove 321 is formed in the top of each detecting rod 32 along the length direction of the detecting rod 32, the standing groove 321 penetrates through one end of the detecting rod 32 far away from the detecting block 31, a plurality of hooks 322 are welded on two sides of the top of each detecting rod 32 along the length direction of the detecting rod 32, elastic bands 323 are arranged between two opposite hooks 322, pull rings 324 are arranged at two ends of each elastic band 323 in a penetrating mode, and the pull rings 324 are in plug-in connection with the corresponding hooks 322.

Referring to fig. 1, 3 and 4, the number of the inspection pens 33 is two, the two inspection pens 33 and the two inspection bars 32 are in one-to-one correspondence, and each inspection pen 33 is disposed between the inspection bar 32 and the elastic belt 323.

The implementation principle of the DCS cabinet fuse testing device provided by the embodiment of the application is as follows: when the fuse 01 needs to be detected, the fuse 01 is placed in the groove 235 on the lower clamping block 232 and clamped through the upper clamping block 231, then, the conveying motor 24 conveys the fuse 01 to be close to between the two detection pens 33 through the conveying rod 22, the detection motor 313 drives the detection rod 32 to be close to each other through the detection screw rod 312, and the two detection pens 33 are abutted against the end parts of the fuse 01, so that the detection of the fuse 01 is completed.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (8)

1. The utility model provides a DCS rack fuse testing arrangement which characterized in that: including workstation (1), place in conveying component (2) at workstation (1) top and place in detection component (3) that the workstation (1) top is close to conveying component (2) position, conveying component (2) are including placing in conveying piece (21) at workstation (1) top, articulated conveying pole (22) on conveying piece (21) lateral wall and place in conveying pole (22) and keep away from conveying clamp (23) of conveying piece (21) one end, conveying clamp (23) are used for carrying out the centre gripping to fuse (01), detection component (3) are used for detecting fuse (01) of centre gripping.

2. The DCS cabinet fuse testing device of claim 1, wherein: the conveying assembly (2) further comprises a conveying motor (24) arranged on the side wall of the conveying block (21), a motor shaft of the conveying motor (24) rotates to penetrate through the conveying block (21), and the motor shaft of the conveying motor (24) is fixedly connected with the end part of the conveying rod (22).

3. The DCS cabinet fuse testing device of claim 1, wherein: the conveying clamp (23) comprises a lower clamping block (232) arranged at the end part of the conveying rod (22) and an upper clamping block (231) arranged above the lower clamping block (232), wherein the upper clamping block (231) is close to one end of the conveying rod (22) and provided with a shifting block (234), the shifting block (234) is gradually reduced along the position, close to the upper clamping block (231), far away from the upper clamping block (231), a torsion spring (233) is arranged between the upper clamping block (231) and the lower clamping block (232), one end of the torsion spring (233) is in abutting contact with the upper clamping block (231), the other end of the torsion spring (233) is in abutting contact with the lower clamping block (232), and when the torsion spring (233) is in a natural state, the upper clamping block (231) and the lower clamping block (232) are far away from one end of the conveying rod (22) and are in abutting contact with each other.

4. A DCS cabinet fuse testing device as claimed in claim 3, wherein: a groove (235) is formed in one side, close to the upper clamping block (231), of the lower clamping block (232), and the groove center of the groove (235) is located on one side, close to the upper clamping block (231), of the lower clamping block (232).

5. The DCS cabinet fuse testing device of claim 1, wherein: the detection assembly (3) comprises a detection block (31) arranged at the top of the workbench (1), two detection rods (32) arranged on one side of the detection block (31) close to the conveying assembly (2) and a detection pen (33) arranged on each detection rod (32), detection grooves (311) are horizontally formed in the side wall of the detection block (31) close to the conveying assembly (2), one ends, close to the detection grooves (311), of the two detection rods (32) are arranged inside the detection grooves (311), and each detection rod (32) is in sliding fit with each detection groove (311).

6. The DCS cabinet fuse testing device of claim 5, wherein: the detection groove (311) is internally provided with a detection screw rod (312), the detection screw rod (312) is provided with two sections of threads with opposite screwing directions, the two detection screw rods (32) and the two sections of threads of the detection screw rod (312) are in one-to-one correspondence, the detection screw rod (312) is spirally threaded through the detection screw rods (32), the side wall of the detection block (31) is provided with a detection motor (313), a motor shaft of the detection motor (313) is threaded through the side wall of the detection block (31), and the motor shaft of the detection motor (313) is fixedly connected with the end part of the detection screw rod (312) adjacent to the motor shaft.

7. The DCS cabinet fuse testing device of claim 5, wherein: an elastic belt (323) is arranged on the side wall of each detection rod (32), and the detection pen (33) is arranged between the elastic belt (323) and the detection rods (32).

8. The DCS cabinet fuse testing device of claim 7, wherein: the utility model discloses a measuring device, including measuring rod (32), elastic webbing (323), pull ring (324) are all provided with on measuring rod (32) top edge measuring rod (32) length direction both sides are provided with a plurality of couples (322), pull ring (324) and corresponding couple (322) grafting cooperation.