CN112786305B - Automatic lamination device of distribution transformer - Google Patents

Abstract

The invention relates to an automatic lamination device, in particular to an automatic lamination device for a distribution transformer. The invention provides an automatic lamination device for a distribution transformer, which can be automatically laminated and reduces a great deal of manpower. The invention provides an automatic lamination device of a distribution transformer, which comprises the following components: the bottom plate is provided with a first supporting plate; the limiting mechanism is arranged on the first supporting plate; the transmission mechanism is arranged at the bottom of the first supporting plate; the bottom plate is provided with a driving mechanism which is matched with the transmission mechanism. The driving mechanism rotates to drive the transmission mechanism to rotate, and the transmission mechanism rotates to drive the limiting mechanism to slide in opposite directions to stack the iron cores.

Description

Automatic lamination device of distribution transformer

Technical Field

The invention relates to an automatic lamination device, in particular to an automatic lamination device for a distribution transformer.

Background

A distribution power transformer is a stationary electrical device that is used to change an ac voltage of a certain magnitude to another or several voltages of the same frequency and different magnitudes. When the primary winding is supplied with alternating current, alternating magnetic flux is generated, and alternating magnetic flux is conducted through the iron core to induce alternating electromotive force in the secondary winding.

In the process of processing the distribution transformer, the iron cores are required to be stacked according to the sequence of the middle, the left and the right, but the stacking mode is generally operated by two persons, a large amount of manpower is required, and the working efficiency is low.

It is therefore desirable to devise an automatic lamination device for distribution transformers that is capable of automatic lamination and reduces the amount of manpower required to solve the above-mentioned problems.

Disclosure of Invention

In order to overcome the defects that the iron core stacking mode is generally operated by two people, a large amount of labor is required to be consumed and the working efficiency is low, the technical problem to be solved is as follows: an automatic lamination device for a distribution transformer is provided, which can be automatically laminated and reduces a lot of manpower.

The technical implementation scheme of the invention is as follows: an automatic lamination device for a distribution transformer, comprising: the bottom plate is provided with a first supporting plate; the limiting mechanism is arranged on the first supporting plate; the transmission mechanism is arranged at the bottom of the first supporting plate; the bottom plate is provided with a driving mechanism which is matched with the transmission mechanism.

Further, the stop gear includes: six baffles are uniformly arranged in the middle of the first supporting plate at intervals; the four sides of the first supporting plate are provided with sliding grooves, and the four sliding grooves are internally provided with the first sliding blocks in a sliding manner; the first fixing blocks are arranged on opposite sides of the four first sliding blocks; the first fixing rods are symmetrically arranged on the four first fixing blocks.

Further, the transmission mechanism includes: the rotating shafts are uniformly and rotatably arranged at intervals at the bottom of the first supporting plate; the four rotating shafts are respectively provided with a first gear; the eccentric positions of the four first gears are respectively provided with a second fixed rod; the bottom ends of the four first sliding blocks are respectively provided with a first sliding rod in a sliding manner; the first straight-shaped chute plates are arranged at one ends of the four first sliding rods, which are close to the first gear, and are in sliding fit with the second fixing rods; and first elastic pieces are arranged between one sides of the four first sliding blocks and one sides of the four first sliding rods.

Further, the driving mechanism includes: the bottom plate at the bottom end of one side of the bracket is provided with the bracket; the rotating motor is arranged on the bracket; and the output shaft of the rotating motor is provided with a second gear, and the second gear is meshed with the four first gears.

Further, the method further comprises the following steps: two straight sliding grooves are formed in two sides of the bottom plate, and the second sliding blocks are arranged in the four straight sliding grooves in a sliding mode; the four second sliding blocks are respectively provided with a third fixing rod; the second straight type chute plates are arranged at two ends of the four third fixing rods; the first guide rods are arranged in each second straight type chute plate; the third sliding blocks are arranged on each first guide rod in a sliding mode; the second support plate is arranged between the two third sliding blocks on the same side; and a second elastic piece is arranged between one side of each third sliding block and one side of each second straight type chute plate.

Further, the method further comprises the following steps: the bottoms of the first sliding rods on two sides are provided with second guide rods; the sliding sleeve is arranged on the two second guide rods in a sliding manner; the first bearing seats are arranged on one sides of the two sliding sleeves, which are opposite to each other; the bottoms of the two first sliding blocks on the same side are provided with second bearings; the first connecting rods are rotatably arranged on the two first bearing seats, and the other ends of the two first connecting rods are rotatably connected with the two second bearing seats; the second sliding rods are arranged between the sliding grooves of the two similar third fixing rods in a sliding manner; the two sides of the two sliding sleeves are provided with the fourth fixing rods; the second connecting rods are rotatably arranged on the four fourth fixing rods, and the four second connecting rods are rotatably connected with the two second sliding rods.

Further, the method further comprises the following steps: the first support plates on the side edges of the four first sliding blocks are respectively provided with a second fixing block; the third sliding rods are arranged on two sides of the four second fixing blocks in a sliding mode; the bottom end of each third sliding rod is provided with a sucking disc; and a third elastic piece is arranged between one side of the sucker and one side of the second fixing block.

Further, the rotating motor is a servo motor.

The invention has the following advantages: 1. the driving mechanism rotates to drive the transmission mechanism to rotate, and the transmission mechanism rotates to drive the limiting mechanism to slide in opposite directions to stack the iron cores.

2. The first slide bar drives the first slide block to slide in opposite directions, and can splice four iron cores simultaneously, so that the working efficiency is improved.

3. The iron core can be placed to the second backup pad more makes things convenient for the staff to change the iron core.

4. The sucking disc and the iron core contact can adsorb the iron core for the staff picks up the iron core more fast and carries out the stack operation, saves a large amount of time.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of a limiting mechanism according to the present invention.

Fig. 3 is a schematic perspective view of the transmission mechanism of the present invention.

Fig. 4 is a schematic perspective view of the driving mechanism of the present invention.

Fig. 5 is a schematic perspective view of a first part of the present invention.

Fig. 6 is a schematic perspective view of a second part of the present invention.

Fig. 7 is a schematic perspective view of a third portion of the present invention.

Wherein the above figures include the following reference numerals: 1. the first support plate, 3, the stop mechanism, 31, the baffle, 32, the first slider, 33, the first fixed block, 34, the first fixed rod, 4, the transmission mechanism, 41, the rotary shaft, 42, the first gear, 43, the second fixed rod, 44, the first sliding rod, 45, the first straight sliding groove plate, 46, the first elastic member, 5, the driving mechanism, 51, the bracket, 52, the rotary motor, 53, the second gear, 6, the second slider, 7, the third fixed rod, 8, the second straight sliding groove plate, 9, the first guide rod, 10, the third slider, 11, the second support plate, 12, the second elastic member, 13, the second guide rod, 14, the sliding sleeve, 15, the first bearing seat, 16, the second bearing seat, 17, the first connecting rod, 18, the second sliding rod, 19, the fourth fixed rod, 20, the second connecting rod, 21, the second fixed block, 22, the third sliding rod, 23, 24 and the third elastic member.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

As shown in fig. 1, an automatic lamination device of a distribution transformer comprises a bottom plate 1, a first supporting plate 2, a limiting mechanism 3, a transmission mechanism 4 and a driving mechanism 5, wherein the first supporting plate 2 is arranged on the bottom plate 1, the limiting mechanism 3 is arranged on the first supporting plate 2, the transmission mechanism 4 is arranged at the bottom of the first supporting plate 2, the driving mechanism 5 is arranged on the bottom plate 1, and the driving mechanism 5 is matched with the transmission mechanism 4.

When the iron core of the distribution transformer is required to be stacked, a worker places the iron core on the first support plate 2 between the limiting mechanisms 3, then the worker starts the driving mechanism 5, the driving mechanism 5 rotates to drive the transmission mechanism 4 to rotate, the transmission mechanism 4 rotates to drive the limiting mechanisms 3 to slide in opposite directions to stack the iron core, after the iron core of the distribution transformer is stacked, the transmission mechanism 4 rotates to drive the limiting mechanisms 3 to slide in opposite directions to reset, the worker closes the driving mechanism 5, the driving mechanism 5 stops rotating, and the transmission mechanism 4 stops rotating accordingly. The device has simple structure and is convenient to operate.

Example 2

As shown in fig. 2, 3 and 4, based on embodiment 1, the limiting mechanism 3 includes a baffle 31, a first slider 32, a first fixing block 33 and a first fixing rod 34, six baffles 31 are uniformly spaced in the middle of the first support plate 2, four sides of the first support plate 2 are all provided with sliding grooves, the four sliding grooves are all provided with the first sliders 32 in a sliding manner, one side of each of the four first sliders 32 opposite to each other is provided with the first fixing block 33, and the four first fixing blocks 33 are all symmetrically provided with the first fixing rod 34.

When the iron core of the distribution transformer is required to be stacked, a worker places the iron core on the first support plate 2 between the first fixed block 33 and the baffle plate 31, then the worker starts the driving mechanism 5, the driving mechanism 5 rotates to drive the transmission mechanism 4 to rotate, the transmission mechanism 4 rotates to drive the first sliding block 32 to slide in the sliding groove on the first support plate 2, the first sliding block 32 slides in the opposite direction to drive the first fixed block 33 to slide in the opposite direction to splice the iron core, after the iron core of the distribution transformer is stacked, the transmission mechanism 4 rotates to drive the first sliding block 32 to slide in the sliding groove on the first support plate 2 back to reset, the first sliding block 32 slides in the back to drive the first fixed block 33 to slide back to reset, the worker closes the driving mechanism 5, the driving mechanism 5 stops rotating, and the transmission mechanism 4 stops rotating along with the driving mechanism. The device has a simple structure, can splice the iron cores, and does not need two workers to operate.

The transmission mechanism 4 comprises a rotating shaft 41, a first gear 42, a second fixing rod 43, a first sliding rod 44, a first straight-shaped sliding groove plate 45 and a first elastic piece 46, wherein four rotating shafts 41 are uniformly arranged at intervals at the bottom of the first supporting plate 2, the first gears 42 are arranged on the four rotating shafts 41, the second fixing rods 43 are arranged at the eccentric positions of the four first gears 42, the first sliding rods 44 are arranged at the bottom ends of the four first sliding blocks 32 in a sliding mode, the first straight-shaped sliding groove plate 45 is arranged at one end, close to the first gears 42, of the four first sliding rods 44, the four first straight-shaped sliding groove plates 45 are in sliding fit with the second fixing rod 43, and the first elastic piece 46 is arranged between one side of the four first sliding blocks 32 and one side of the four first sliding rods 44.

After the iron core is placed on the first supporting plate 2 between the first fixed block 33 and the baffle plate 31 by a worker, the worker starts the driving mechanism 5, the driving mechanism 5 rotates to drive the first gear 42 to rotate, the first gear 42 drives the second fixed rod 43 to move inwards, the second fixed rod 43 moves inwards to drive the first straight-shaped sliding groove plate 45 to move inwards, the first straight-shaped sliding groove plate 45 moves inwards to drive the first sliding rod 44 to slide in the first sliding block 32 in the opposite direction, the first elastic piece 46 is compressed, the first sliding rod 44 drives the first sliding block 32 to slide in the opposite direction, the first sliding block 32 slides in the opposite direction to drive the first fixed block 33 to slide in the opposite direction to splice the iron core, after the iron core of the power distribution transformer is overlapped, the first gear 42 drives the second fixed rod 43 to move outwards, the second fixed rod 43 moves outwards to drive the first straight-shaped sliding groove plate 45 to move outwards, the first sliding groove plate 45 moves outwards to drive the first sliding rod 44 to slide in the first sliding block 32 in the opposite direction, the first elastic piece 46 resets, the first sliding block 32 slides in the opposite direction to drive the first sliding block 32 to slide in the opposite direction to stop rotating the first gear 42 to stop rotating, and the first gear 42 stops rotating, and the driving mechanism 5 stops rotating and rotates. The device has a simple structure, can splice four iron cores simultaneously, and improves the working efficiency.

The driving mechanism 5 comprises a bracket 51, a rotating motor 52 and a second gear 53, the bracket 51 is arranged on the bottom plate 1 at the right side bottom end, the rotating motor 52 is arranged on the bracket 51, the second gear 53 is arranged on the output shaft of the rotating motor 52, and the second gear 53 is meshed with the four first gears 42.

After the iron core is placed, the operator starts the rotating motor 52, the rotating motor 52 rotates to drive the second gear 53 to rotate, the second gear 53 rotates to be meshed with the first gear 42, the first gear 42 rotates to drive the second fixing rod 43 to move inwards, further, the first sliding rod 44 drives the first sliding block 32 to slide oppositely, the first sliding block 32 slides oppositely to drive the first fixing block 33 to slide oppositely to splice the iron cores, after the first sliding block 32 slides back to drive the first fixing block 33 to slide back to reset, the operator turns off the rotating motor 52, the rotating motor 52 stops rotating, the second gear 53 stops rotating along with the rotating motor, and the upper parts of the second gear 53 stop rotating. The device has simple structure and can provide power for the whole device.

Example 3

As shown in fig. 5, 6 and 7, the sliding groove plate further comprises a second sliding block 6, a third fixing rod 7, a second straight type sliding groove plate 8, a first guide rod 9, third sliding blocks 10, a second supporting plate 11 and a second elastic piece 12, two straight sliding grooves are formed in the front side and the rear side of the bottom plate 1, the second sliding blocks 6 are arranged in the four straight sliding grooves in a sliding mode, the third fixing rods 7 are arranged on the four second sliding blocks 6, the second straight type sliding groove plates 8 are arranged at two ends of the four third fixing rods 7, a first guide rod 9 is arranged in each second straight type sliding groove plate 8, a third sliding block 10 is arranged on each first guide rod 9 in a sliding mode, a second supporting plate 11 is arranged between the two third sliding blocks 10 on the same side, and a second elastic piece 12 is arranged between one side of each third sliding block 10 and one side of each second straight type sliding groove plate 8.

When the distribution transformer is required to be stacked, a worker places a certain amount of iron cores on the second supporting plate 11, drives the third sliding block 10 to slide downwards on the first guide rod 9 under the action of the gravity of the iron cores, the second elastic piece 12 is compressed, the third sliding block 10 slides downwards to drive the second supporting plate 11 to move downwards, at this time, the worker places the iron cores on the first supporting plate 2 between the first fixing block 33 and the baffle plate 31 to perform stacking operation, and as the number of the iron cores is smaller and smaller, the second elastic piece 12 resets to drive the third sliding block 10 to slide upwards on the first guide rod 9, and the third sliding block 10 slides upwards to drive the second supporting plate 11 to move upwards to reset. The device has a simple structure, and can be used for placing the iron core more conveniently for a worker to replace the iron core.

The novel sliding rod type hydraulic lifting device is characterized by further comprising a second guide rod 13, sliding sleeves 14, first bearing seats 15, second bearing shafts 16, first connecting rods 17, second sliding rods 18, fourth fixing rods 19 and second connecting rods 20, wherein the bottoms of the first sliding rods 44 on the front side and the rear side are respectively provided with the second guide rods 13, the sliding sleeves 14 are respectively arranged on the two second guide rods 13 in a sliding mode, the first bearing seats 15 are respectively arranged on the back side of the two sliding sleeves 14, the second bearing seats 16 are respectively arranged on the bottoms of the two first sliding blocks 32 on the front side and the rear side, the first connecting rods 17 are respectively arranged on the two first bearing seats 15 in a rotating mode, the other ends of the two first connecting rods 17 are respectively connected with the two second bearing seats 16 in a rotating mode, sliding grooves are respectively formed in the four third fixing rods 7 on the same side, second sliding rods 18 are respectively arranged between the sliding grooves of the two similar third fixing rods 7, the two sliding sleeves 14 are respectively provided with the fourth fixing rods 19, and the four second connecting rods 20 are respectively connected with the two second sliding rods 18 in a rotating mode.

The first sliding rod 44 moves in opposite directions to drive the first connecting rod 17 to rotate downwards, the first connecting rod 17 rotates downwards to drive the sliding sleeve 14 to slide upwards on the second guide rod 13, the sliding sleeve 14 slides upwards to drive the second connecting rod 20 to rotate upwards, the second connecting rod 20 rotates upwards to drive the second sliding rod 18 to slide in opposite directions on the third fixing rod 7, the third fixing rod 7 moves upwards to drive the second sliding block 6 to slide upwards in the straight sliding groove, the third fixing rod 7 moves upwards to drive the second supporting plate 11 to move upwards, so that workers can pick up iron cores more conveniently, when the first sliding rod 44 slides backwards, the first sliding block 32 slides backwards to drive the first connecting rod 17 to rotate upwards, the first connecting rod 17 rotates upwards to drive the sliding sleeve 14 to slide downwards on the second guide rod 13 to reset, the second connecting rod 20 slides downwards to drive the second connecting rod 20 to rotate downwards to drive the second sliding rod 18 to slide backwards on the third fixing rod 7 to reset, the third fixing rod 7 is pressed downwards to drive the third fixing rod 7 to move downwards, and the third fixing rod 7 moves downwards to drive the second supporting plate 11 to slide downwards to reset in the straight sliding groove. The device has simple structure, and can enable staff to pick up the iron core more conveniently for stacking operation.

The novel sliding block comprises a first supporting plate 2, a second fixing block 21, a third sliding rod 22, suckers 23 and third elastic pieces 24, wherein the first supporting plate 2 on the side edges of four first sliding blocks 32 is provided with the second fixing block 21, the two sides of the four second fixing blocks 21 are provided with the third sliding rod 22 in a sliding mode, the bottom end of each third sliding rod 22 is provided with each sucker 23, and the third elastic pieces 24 are arranged between one side of each sucker 23 and one side of each second fixing block 21.

The third dead lever 7 moves upward and drives the second backup pad 11 to move upward, and then makes sucking disc 23 and iron core contact, and upwards extrude third slide bar 22 through sucking disc 23, third slide bar 22 upwards slides on second fixed block 21, third elastic component 24 is compressed, sucking disc 23 and iron core contact, can adsorb the iron core, at this moment the staff places the iron core on first backup pad 2 between first fixed block 33 and baffle 31, when the downward movement of third dead lever 7 drives second backup pad 11 and moves down, and then make sucking disc 23 and iron core no longer contact, third elastic component 24 resets and drives third slide bar 22 to slide down and reset on second fixed block 21. The device simple structure can adsorb the iron core for the staff picks up the iron core more fast, saves a large amount of time.

The foregoing examples have shown only the preferred embodiments of the invention, which are described in more detail and are not to be construed as limiting the scope of the invention. It should be noted that modifications, improvements and substitutions can be made by those skilled in the art without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (5)

1. An automatic lamination device for a distribution transformer, comprising:

a bottom plate (1), wherein a first supporting plate (2) is arranged on the bottom plate (1);

the limiting mechanism (3) is arranged on the first supporting plate (2);

the transmission mechanism (4) is arranged at the bottom of the first supporting plate (2);

the driving mechanism (5) is arranged on the bottom plate (1), and the driving mechanism (5) is matched with the transmission mechanism (4);

the limit mechanism (3) comprises:

six baffles (31) are uniformly arranged in the middle of the first supporting plate (2) at intervals;

the four sides of the first supporting plate (2) are provided with sliding grooves, and the four sliding grooves are internally provided with the first sliding blocks (32) in a sliding manner;

the first fixing blocks (33) are arranged on opposite sides of the four first sliding blocks (32);

the first fixing rods (34) are symmetrically arranged on the four first fixing blocks (33);

the transmission mechanism (4) comprises:

the rotating shafts (41) are uniformly arranged at intervals at the bottom of the first supporting plate (2), and four rotating shafts (41) are rotatably arranged at intervals;

the first gears (42) are arranged on the four rotating shafts (41);

the second fixing rods (43) are arranged at the eccentric positions of the four first gears (42);

the bottom ends of the four first sliding blocks (32) are respectively provided with a first sliding rod (44) in a sliding manner;

the first straight-shaped chute plates (45), one ends of the four first sliding rods (44) close to the first gear (42) are respectively provided with a first straight-shaped chute plate (45), and the four first straight-shaped chute plates (45) are in sliding fit with the second fixing rods (43);

the first elastic pieces (46) are arranged between one side of the four first sliding blocks (32) and one side of the four first sliding bars (44);

the drive mechanism (5) comprises:

a bracket (51) is arranged on the bottom plate (1) at one side bottom end;

a rotating motor (52), the rotating motor (52) being provided on the bracket (51);

and the second gear (53) is arranged on the output shaft of the rotating motor (52), and the second gear (53) is meshed with the four first gears (42).

2. An automatic lamination device for a distribution transformer as recited in claim 1, further comprising:

the two sides of the bottom plate (1) are provided with two straight sliding grooves, and the four straight sliding grooves are internally provided with the second sliding blocks (6) in a sliding manner;

the third fixing rods (7) are arranged on the four second sliding blocks (6);

the second straight type chute plates (8) are arranged at the two ends of the four third fixing rods (7);

the first guide rods (9) are arranged in each second straight-type chute plate (8);

the third sliding blocks (10) are arranged on each first guide rod (9) in a sliding mode;

a second supporting plate (11) is arranged between two third sliding blocks (10) on the same side;

and second elastic pieces (12) are arranged between one side of each third sliding block (10) and one side of each second straight type chute plate (8).

3. An automatic lamination device for a distribution transformer as defined in claim 2, further comprising:

the second guide rod (13) is arranged at the bottom of the first sliding rod (44) at two sides, and the second guide rod (13) is arranged at the bottom of the first sliding rod;

the sliding sleeve (14) is arranged on the two second guide rods (13) in a sliding manner, and the sliding sleeve (14) is arranged on the two second guide rods (13) in a sliding manner;

the two sliding sleeves (14) are respectively provided with a first bearing seat (15) on one side opposite to the first bearing seat (15);

the bottoms of the two first sliding blocks (32) on the same side are provided with second bearings (16);

the first connecting rods (17) are rotatably arranged on the two first bearing seats (15), and the other ends of the two first connecting rods (17) are rotatably connected with the two second bearing seats (16);

the second slide bars (18) are respectively arranged on the four third fixed bars (7) on the same side, and the second slide bars (18) are respectively arranged between the sliding grooves of the two similar third fixed bars (7) in a sliding manner;

the fourth fixed rod (19) is arranged on both sides of the two sliding sleeves (14);

the second connecting rods (20) are rotatably arranged on the four fourth fixing rods (19), and the four second connecting rods (20) are rotatably connected with the two second sliding rods (18).

4. An automatic lamination device for a distribution transformer as recited in claim 3, further comprising:

the second fixing blocks (21) are arranged on the first supporting plates (2) at the sides of the four first sliding blocks (32);

the third sliding rods (22) are arranged on two sides of the four second fixed blocks (21) in a sliding mode;

the bottom end of each third sliding rod (22) is provided with a sucker (23);

and a third elastic piece (24) is arranged between one side of the sucker (23) and one side of the second fixed block (21).

5. An automatic lamination device for distribution transformers according to claim 1, characterized in that the rotary electric machine (52) is a servomotor.