CN112697605A - Compression resistance detection device and process for preparing molded transformer - Google Patents

Abstract

The invention belongs to the technical field of transformers, in particular to a compression resistance detection device for preparing a formed transformer, which aims at solving the problems that a plurality of surfaces of the transformer cannot be detected and detection personnel are easy to be hurt in the detection process and provides the following scheme, the invention is simple and convenient, the driving gear, the disc, the first rotating shaft and the semicircular gear ring can be controlled to rotate 90 degrees by starting the rotating motor, so that the transformer can rotate to change the surface to be detected, the detection of different surfaces can obtain more complete compression-resistant data, and the driving motor is started to control the two screws to move towards the middle to simultaneously extrude the two surfaces of the transformer, in addition, the door is provided with the tempered glass, so that not only can detection personnel be protected through the tempered glass, but also the tempered glass can penetrate through the detection process in the detection box.

Description

Compression resistance detection device and process for preparing molded transformer

Technical Field

The invention relates to the technical field of transformers, in particular to a compression resistance detection device and process for preparing a molded transformer.

Background

The transformer is used in the power system to transform voltage to facilitate power transmission, and is an indispensable device of the power system. The transformer is a device for changing alternating voltage by using the principle of electromagnetic induction, and main components are a primary coil, a secondary coil and an iron core. The main functions are as follows: voltage transformation, current transformation, impedance transformation, isolation, voltage stabilization, and the like. According to the application, the method can be divided into: the transformer is usually placed in the open air, the mounting positions of part of the transformers are low and are easy to be impacted by external force, and if the transformers are impacted by large force, the transformers are easy to be damaged and damage the whole circuit.

Therefore need carry out compressive property to the transformer and detect when transformer processing usually, but all carry out the compressive property to the transformer and detect in a direction when carrying out the compressive property to the transformer among the prior art, the resistance to compression data that obtains is incomplete, can not embody the true resistance to compression data of transformer, can influence the use of follow-up transformer, and the pressure that produces in detecting the resistance to compression process is very big moreover, if do not have protector, when the waste material splashes, easily injures detection personnel.

Disclosure of Invention

The invention aims to solve the defects in the prior art, and provides a compression resistance detection device for preparing a formed transformer.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides a compressive property detection device for preparing forming transformer, includes the detection case, one side hinge of detection case has the door, be equipped with tempered glass in the door, the bottom inner wall sliding connection of detection case has the sliding block, the bottom inner wall of sliding block rotates and is connected with first pivot, the board is placed to the top fixedly connected with of first pivot, be equipped with in the sliding block and be used for the drive to place the board and carry out 90 degrees pivoted rotating assembly, the transformer has been placed at the top of placing the board, the top sliding connection of sliding block has two symmetrical stripper plates, two a plurality of pressure sensor have been arranged to the equal equidistance in one side that the stripper plate is close to each other, the both sides inner wall of detection case all is equipped with and is used for carrying out extruded extrusion subassembly to the.

Preferably, the runner assembly includes the rotation motor of fixed connection at sliding block bottom inner wall, the output shaft fixedly connected with driving gear of rotation motor, the fixed cover of outer wall of first pivot is equipped with the disc, the fixed cover of outer wall of disc is equipped with the semicircle ring gear, the bottom inner wall of sliding block rotates and is connected with the second pivot, the top fixedly connected with gear of second pivot, gear and semicircle ring gear mesh mutually, the fixed cover of outer wall of second pivot is equipped with driven gear, driven gear and driving gear mesh mutually.

Preferably, the extrusion subassembly includes the fixed storehouse of fixed connection at detection case both sides inner wall, two the both sides inner wall of fixed storehouse is rotated and is connected with same rotation sleeve, rotate telescopic inner wall fixedly connected with nut, two equal threaded connection has the screw rod in the nut, two the one end that the screw rod is close to the transformer all runs through fixed storehouse and equal fixedly connected with push pedal, two it is equipped with first worm wheel all to rotate telescopic outer wall fixed cover.

Preferably, extrusion component still includes fixed connection at the driving motor at detection box top, driving motor's output shaft extends to in the detection box and fixedly connected with second worm, the top inner wall of detection box rotates and is connected with the dwang, the fixed cover of outer wall of dwang is equipped with the second worm wheel, second worm wheel and second worm mesh mutually, the equal fixedly connected with second helical gear in both ends of dwang, two the top inner wall and the bottom inner wall of fixed storehouse all rotate and are connected with same first worm, two fixed storehouse is all run through to the top of first worm and all rotate with the top inner wall of detection box and be connected, two first worm all meshes mutually with first worm wheel, two the outer wall of first worm is all fixed the cover and is equipped with first helical gear, first helical gear and second helical gear mesh mutually.

Preferably, two equal fixedly connected with three hornblocks in one side that the stripper plate kept away from each other, two the bottom of three hornblocks all with the top sliding connection of sliding block, can play the supporting role to the stripper plate through three hornblocks.

Preferably, a placing groove is formed in the placing plate, and the transformer can be positioned through the placing groove.

Preferably, the top of each of the two fixed bins is fixedly embedded with a rotating bearing, the top ends of the two first worms penetrate through the inner ring of the rotating bearing and are fixedly connected with the inner ring of the rotating bearing, and the friction resistance of the fixed bins to the first worm can be reduced through the rotating bearings, so that the first worm can rotate more easily.

Preferably, two the equal sliding connection in one side that fixed storehouse is close to the transformer has a plurality of telescopic links, and is a plurality of the one end that fixed storehouse was kept away from to the telescopic link all with push pedal fixed connection, the telescopic link comprises first sleeve and second sleeve, and a sleeve and second sleeve sliding connection, can prop up the push pedal through the telescopic link.

A compression resistance detection process for preparing a molded transformer comprises the following steps:

s1, firstly opening the door, pulling the sliding block outwards, placing the transformer in the placing groove, positioning the transformer, then pushing the sliding block inwards, and then closing the door;

s2, starting a driving motor to drive a second worm to rotate, wherein the second worm is meshed with a second worm wheel, the second worm drives the second worm wheel, a rotating rod and a second bevel wheel to rotate simultaneously, a first bevel wheel is meshed with the second bevel wheel, and the first bevel wheel and the first worm are meshed with each other along with the rotation of the first bevel wheel and the first worm, so that the first worm drives the first worm wheel and a rotating sleeve to rotate;

s3, the nut rotates along with the rotating sleeve, the screw rods are in threaded connection with the nut, the two screw rods start to move towards the middle along with the rotation of the nut, the two screw rods push the two pressure sensors to slide towards the middle to extrude the transformer, and the pressure sensors can detect the extrusion force of the push plate on the extrusion plate;

s4, after the first detection is finished, the driving motor is started, the second worm starts to rotate reversely, the two screws drive the two push plates to slide towards two sides, then the driving motor is started to rotate to drive the driving gear to rotate, the placing plate is meshed with the driven gear, the placing plate drives the second rotating shaft, the driven gear and the gear to rotate, the gear is meshed with the semicircular gear ring, the semicircular gear ring drives the gear, the disc and the first rotating shaft to rotate for 90 degrees, and the transformer can be replaced by one face for detection.

The detection device is simple and convenient, the driving gear, the disc, the first rotating shaft and the semicircular gear ring can be controlled to rotate 90 degrees by starting the rotating motor, the transformer can be rotated to replace the surface to be detected, different surfaces can be detected, more complete compression resistance data can be obtained, the driving motor is started to control the two screws to move towards the middle to simultaneously extrude the two surfaces of the transformer, in addition, the strengthened glass is arranged in the door, and not only can detection personnel be protected by the strengthened glass, but also the strengthened glass can penetrate through the detection process in the detection box.

Drawings

Fig. 1 is a front sectional view of a compression resistance detecting apparatus for manufacturing a molded transformer according to the present invention;

FIG. 2 is a top view of the compression resistance testing apparatus for manufacturing a formed transformer according to the present invention;

FIG. 3 is a front view of the compression resistance testing apparatus for manufacturing a formed transformer according to the present invention;

FIG. 4 is a top view of a sliding block for a compression resistance testing device for manufacturing a formed transformer according to the present invention;

FIG. 5 is a side sectional view of a sliding block for use in a compression resistance testing apparatus for manufacturing a molded transformer according to the present invention;

FIG. 6 is a diagram of the engagement between the semi-circular gear ring and the gear for the compression resistance testing device of the formed transformer according to the present invention;

fig. 7 is a top cross-sectional view of a fixing bin for a compression resistance detection apparatus for manufacturing a formed transformer according to the present invention.

In the figure: 1. a detection box; 2. a door; 3. a slider; 4. a first rotating shaft; 5. a disc; 6. a second rotating shaft; 7. a gear; 8. a semicircular toothed ring; 9. a driven gear; 10. rotating the motor; 11. placing the plate; 12. a transformer; 13. a pressing plate; 14. a pressure sensor; 15. fixing the bin; 16. rotating the sleeve; 17. a nut; 18. a screw; 19. pushing the plate; 20. a first worm gear; 21. a first worm; 22. a first helical gear; 23. rotating the rod; 24. a second worm gear; 25. a drive motor; 26. a second worm; 27. a second helical gear; 28. a driving gear; 29. a telescopic rod; 30. a triangular block; 31. a placement groove; 32. strengthening the glass; 33. and rotating the bearing.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Example one

Referring to fig. 1-7, a compressive property detection device for preparing shaping transformer, including detection case 1, there is door 2 one side hinge of detection case 1, be equipped with tempered glass 32 in the door 2, the bottom inner wall sliding connection of detection case 1 has sliding block 3, the bottom inner wall of sliding block 3 rotates and is connected with first pivot 4, board 11 is placed to the top fixedly connected with of first pivot 4, be equipped with in the sliding block 3 and be used for the drive to place board 11 and carry out 90 degrees pivoted rotating assembly, place the top of board 11 and placed transformer 12, the top sliding connection of sliding block 3 has two symmetrical stripper plates 13, the equal equidistance in one side that two stripper plates 13 are close to each other has arranged a plurality of pressure sensor 14, the both sides inner wall of detection case 1 all is equipped with and is used for carrying out extruded extrusion assembly to transformer 12.

Example two

The embodiment is improved on the basis of the first embodiment: the rotating assembly comprises a rotating motor 10 fixedly connected to the inner wall of the bottom of the sliding block 3, an output shaft of the rotating motor 10 is fixedly connected with a driving gear 28, the outer wall of the first rotating shaft 4 is fixedly sleeved with a disc 5, the outer wall of the disc 5 is fixedly sleeved with a semicircular gear ring 8, the inner wall of the bottom of the sliding block 3 is rotatably connected with a second rotating shaft 6, the top of the second rotating shaft 6 is fixedly connected with a gear 7, the gear 7 is meshed with the semicircular gear ring 8, the outer wall of the second rotating shaft 6 is fixedly sleeved with a driven gear 9, the driven gear 9 is meshed with the driving gear 28, the extrusion assembly comprises fixed bins 15 fixedly connected to the inner walls of two sides of the detection box 1, the inner walls of two fixed bins 15 are rotatably connected with a same rotating sleeve 16, nuts 17 are fixedly connected to the inner wall of the rotating sleeve 16, screw rods 18 are uniformly and threadedly connected in the two nuts 17, the outer walls of the two rotating sleeves 16 are fixedly sleeved with first worm gears 20, the extrusion assembly further comprises a driving motor 25 fixedly connected to the top of the detection box 1, an output shaft of the driving motor 25 extends into the detection box 1 and is fixedly connected with second worm gears 26, the inner wall of the top of the detection box 1 is rotatably connected with a rotating rod 23, the outer wall of the rotating rod 23 is fixedly sleeved with a second worm gear 24, the second worm gear 24 is meshed with the second worm gears 26, the two ends of the rotating rod 23 are fixedly connected with second bevel gears 27, the inner walls of the top and the bottom of the two fixed bins 15 are rotatably connected with the same first worm 21, the tops of the two first worm gears 21 penetrate through the fixed bins 15 and are rotatably connected with the inner wall of the top of the detection box 1, the two first worm gears 21 are meshed with the first worm gears 20, the outer walls of the two first worm gears 21 are fixedly sleeved with first bevel gears 22, the first bevel gears 22 are meshed, the side, far away from each other, of each of the two squeezing plates 13 is fixedly connected with a triangular block 30, the bottoms of the two triangular blocks 30 are slidably connected with the top of the sliding block 3, the squeezing plates 13 can be supported by the triangular blocks 30, a placing groove 31 is arranged in the placing plate 11, the transformer 12 can be positioned by the placing groove 31, rotating bearings 33 are fixedly embedded at the tops of the two fixing bins 15, the top ends of the two first worms 21 penetrate through the inner rings of the rotating bearings 33 and are fixedly connected with the inner rings of the rotating bearings 33, the frictional resistance of the fixing bins 15 to the first worms 21 can be reduced by the rotating bearings 33, so that the first worms 21 can rotate more easily, one side, near the transformer 12, of the two fixing bins 15 is slidably connected with a plurality of telescopic rods 29, one ends, far away from the fixing bins 15, of the plurality of telescopic rods 29 are fixedly connected with the pushing plate 19, each telescopic rod 29 is composed of a first sleeve and a, and a sleeve is connected with the second sleeve in a sliding way, and the push plate 19 can be supported by the telescopic rod 29.

A compression resistance detection process for preparing a molded transformer comprises the following steps:

s1, firstly opening the door 2, pulling the sliding block 3 outwards, placing the transformer 12 in the placing groove 31, positioning the transformer 12, then pushing the sliding block 3 inwards, and then closing the door 2;

s2, starting the driving motor 25 to drive the second worm 26 to rotate, wherein the second worm 26 is meshed with the second worm wheel 24, the second worm 26 drives the second worm wheel 24, the rotating rod 23 and the second bevel wheel 27 to simultaneously rotate, the first bevel wheel 22 is meshed with the second bevel wheel 27, the first bevel wheel 22 is meshed with the first worm 21 along with the rotation of the first worm 21, and the first worm 21 is meshed with the first worm wheel 20, so that the first worm 21 drives the first worm wheel 20 and the rotating sleeve 16 to rotate;

s3, the nut 17 rotates along with the rotating sleeve 16, the screw rods 18 are in threaded connection with the nut 17, the two screw rods 18 start to move towards the middle along with the rotation of the nut 17, the two screw rods 18 push the two pressure sensors 14 to slide towards the middle to extrude the transformer 12, and at the moment, the pressure sensors 14 can detect the extrusion force applied by the push plate 19 to the extrusion plate 13;

s4, after the first detection is finished, the driving motor 25 is started, the second worm 26 starts to rotate reversely, the two screw rods 18 drive the two push plates 19 to slide towards two sides, then the rotating motor 10 is started to drive the driving gear 28 to rotate, the plate 11 is placed to be meshed with the driven gear 9, the plate 11 is placed to drive the second rotating shaft 6, the driven gear 9 and the gear 7 to rotate, the gear 7 is meshed with the semicircular toothed ring 8, the semicircular toothed ring 8 drives the gear 7, the disc 5 and the first rotating shaft 4 rotate 90 degrees, and the transformer 12 can be replaced by one face for detection.

However, as is well known to those skilled in the art, the working principle and wiring method of the rotating motor 10 and the driving motor 25 are common and are conventional means or common knowledge, and will not be described herein, and those skilled in the art can make any choice according to their needs or convenience.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (9)

1. The compression resistance detection device for preparing the molded transformer comprises a detection box (1) and is characterized in that a door (2) is hinged to one side of the detection box (1), tempered glass (32) is arranged in the door (2), a sliding block (3) is connected to the bottom inner wall of the detection box (1) in a sliding mode, a first rotating shaft (4) is connected to the bottom inner wall of the sliding block (3) in a rotating mode, a placing plate (11) is fixedly connected to the top of the first rotating shaft (4), a rotating assembly used for driving the placing plate (11) to rotate 90 degrees is arranged in the sliding block (3), a transformer (12) is placed at the top of the placing plate (11), two symmetrical extrusion plates (13) are connected to the top of the sliding block (3), and a plurality of pressure sensors (14) are arranged on one side, close to each other, of the extrusion plates (13) at equal intervals, the inner walls of two sides of the detection box (1) are provided with extrusion components for extruding the transformer (12).

2. The apparatus for detecting compression resistance of a formed transformer according to claim 1, it is characterized in that the rotating component comprises a rotating motor (10) fixedly connected with the inner wall of the bottom of the sliding block (3), an output shaft of the rotating motor (10) is fixedly connected with a driving gear (28), a disc (5) is fixedly sleeved on the outer wall of the first rotating shaft (4), a semicircular gear ring (8) is fixedly sleeved on the outer wall of the disc (5), the inner wall of the bottom of the sliding block (3) is rotatably connected with a second rotating shaft (6), the top of the second rotating shaft (6) is fixedly connected with a gear (7), the gear (7) is meshed with a semicircular gear ring (8), the outer wall of the second rotating shaft (6) is fixedly sleeved with a driven gear (9), and the driven gear (9) is meshed with the driving gear (28).

3. The compression resistance detection device for preparing the forming transformer is characterized in that the extrusion assembly comprises fixed bins (15) fixedly connected to the inner walls of two sides of the detection box (1), two inner walls of two sides of the fixed bins (15) are rotatably connected with the same rotating sleeve (16), nuts (17) are fixedly connected to the inner walls of the rotating sleeve (16), two screws (18) are connected to the nuts (17) in a threaded manner, one ends of the screws (18) close to the transformer (12) penetrate through the fixed bins (15) and are fixedly connected with push plates (19), and two first worm gears (20) are fixedly sleeved on the outer walls of the rotating sleeve (16).

4. The compression resistance detection device for preparing the formed transformer according to claim 3, wherein the extrusion assembly further comprises a driving motor (25) fixedly connected to the top of the detection box (1), an output shaft of the driving motor (25) extends into the detection box (1) and is fixedly connected with a second worm (26), the top inner wall of the detection box (1) is rotatably connected with a rotating rod (23), the outer wall of the rotating rod (23) is fixedly sleeved with a second worm wheel (24), the second worm wheel (24) is meshed with the second worm (26), two ends of the rotating rod (23) are both fixedly connected with second bevel gears (27), the top inner walls and the bottom inner walls of the two fixed bins (15) are both rotatably connected with the same first worm (21), the tops of the two first worms (21) both penetrate through the fixed bins (15) and are both rotatably connected with the top inner walls of the detection box (1), two first worm (21) all mesh with first worm wheel (20), two the outer wall of first worm (21) all fixed cover is equipped with first helical gear (22), first helical gear (22) and second helical gear (27) mesh mutually.

5. The device for detecting the compression resistance of the formed transformer according to claim 1, wherein a triangular block (30) is fixedly connected to each side of the two extrusion plates (13) far away from each other, and the bottom of each triangular block (30) is slidably connected with the top of the sliding block (3).

6. The device for detecting the compression resistance of the formed transformer according to claim 1, wherein a placing groove (31) is formed in the placing plate (11).

7. The device for detecting the compression resistance of the formed transformer according to claim 4, wherein a rotating bearing (33) is fixedly embedded at the top of each of the two fixed bins (15), and the top ends of the two first worms (21) penetrate through the inner ring of the rotating bearing (33) and are fixedly connected with the inner ring of the rotating bearing (33).

8. The device for detecting the compression resistance of the formed transformer according to claim 3, wherein a plurality of telescopic rods (29) are slidably connected to one side of each of the two fixed bins (15) close to the transformer (12), and one ends of the plurality of telescopic rods (29) far away from the fixed bins (15) are fixedly connected with the push plate (19).

9. The process for detecting the compressive property of the formed transformer according to any one of claims 1 to 8, comprising the steps of:

s1, firstly opening the door (2), pulling the sliding block (3) outwards, placing the transformer (12) in the placing groove (31), positioning the transformer (12), then pushing the sliding block (3) inwards, and then closing the door (2);

s2, starting a driving motor (25) to drive a second worm (26) to rotate, wherein the second worm (26) is meshed with a second worm wheel (24), the second worm (26) drives the second worm wheel (24), a rotating rod (23) and a second bevel gear (27) to simultaneously rotate, a first bevel gear (22) is meshed with the second bevel gear (27), the first bevel gear (22) and a first worm (21) rotate along with the rotation, the first worm (21) is meshed with a first worm wheel (20), and therefore the first worm (21) drives the first worm wheel (20) and a rotating sleeve (16) to rotate;

s3, the nut (17) rotates along with the rotating sleeve (16), the screw rods (18) are in threaded connection with the nut (17), the two screw rods (18) start to move towards the middle along with the rotation of the nut (17), the two screw rods (18) push the two pressure sensors (14) to slide towards the middle to extrude the transformer (12), and the pressure sensors (14) can detect the extrusion force applied by the push plate (19) to the extrusion plate (13);

s4, after the first detection, start driving motor (25), second worm (26) begin antiport, two screw rods (18) drive two push pedal (19) and slide to both sides, start rotating motor (10) drive driving gear (28) and rotate after that, place board (11) and driven gear (9) and mesh mutually, it drives second pivot (6) to place board (11), driven gear (9) and gear (7) rotate, and gear (7) and semicircle ring gear (8) mesh mutually, semicircle ring gear (8) drive gear (7), disc (5) and first pivot (4) rotate 90 degrees, make transformer (12) can change a face again and detect.

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