CN210272061U - Transformer silicon steel sheet stacking platform device - Google Patents

Abstract

The utility model discloses a transformer silicon steel sheet closed assembly platform device, it relates to transformer silicon steel sheet manufacture equipment technical field. The stacking machine comprises a stacking station, wherein a linear moving mechanism is arranged at the bottom of the stacking station; a lifting mechanism is arranged on the bottom plate of the stacking station; the lifting plate is provided with a silicon steel sheet supporting rod which is perpendicular to the lifting plate, the side edge of the silicon steel sheet supporting rod is connected with a first silicon steel sheet supporting block, and the silicon steel sheet supporting rod and the first silicon steel sheet supporting block are in sliding connection with the lifting plate; and a second silicon steel sheet supporting block is arranged on the silicon steel sheet supporting rod and is in sliding connection with the silicon steel sheet supporting rod. The utility model has the advantages that: the lifting mechanism can drive the lifting plate on the lifting mechanism to lift along with the change of the iron core stacking height; the silicon steel sheet can move transversely and longitudinally, and the size can be automatically adjusted to be suitable for the overlapping of iron cores with different specifications; and outputting the iron core which is completely stacked and stacked outwards after the stacking is completed.

Description

Transformer silicon steel sheet stacking platform device

Technical Field

The utility model relates to a transformer silicon steel sheet manufacture equipment technical field, concretely relates to transformer silicon steel sheet closed assembly platform device.

Background

The stacking of silicon steel sheet iron cores is generally that silicon steel sheets are cut and stacked through a transverse shearing line, the transverse shearing line of the silicon steel sheets generally consists of a material placing device, a material feeding channel, a punching device, a V-shaped shearing device, a material collecting device and a control center, wherein the material feeding device, the punching device, the V-shaped shearing device and the shearing device are sequentially arranged on the material feeding channel, the silicon steel sheets are manually transported to a stacking working place after being cut through the transverse shearing line, and are stacked into the iron cores through manual stacking, or the silicon steel sheets are manually sorted (the silicon steel sheets are stacked orderly), and then are loaded into a preset station of automatic stacking equipment, and are stacked into the iron cores through the automatic stacking equipment.

The stacking of silicon steel sheet iron cores is usually carried out on a stacking table, the stacking table in the prior art is fixed, the silicon steel sheet iron cores need to be transported through other devices after the stacking is finished, the stacking table can only stack silicon steel sheet iron cores of one specification, a silicon steel sheet supporting mechanism on the stacking table cannot be adjusted, the distance between the silicon steel sheets cannot be adjusted according to different specifications of the silicon steel sheet iron cores, and the application range is small.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide transformer silicon steel sheet closed assembly platform device, can solve the closed assembly that exists among the prior art and need carry, can not carry out the distance adjustment scheduling problem between the silicon steel sheet according to the different specifications of silicon steel sheet iron core through other devices after accomplishing.

In order to solve the technical problem, the utility model adopts the technical scheme that: comprises that

At least one stacking station is arranged, a linear moving mechanism is arranged at the bottom of the stacking station, and the linear moving mechanism outputs the iron cores which are stacked outwards;

a lifting mechanism is arranged on a bottom plate of the stacking station, and the lifting mechanism drives a lifting plate on the lifting mechanism to lift along with the change of the stacking height of the iron core through a lifting motor;

the lifting plate is provided with at least 2 silicon steel sheet supporting rods which are perpendicular to the lifting plate, the side edge of each silicon steel sheet supporting rod is connected with a first silicon steel sheet supporting block, and the silicon steel sheet supporting rods and the first silicon steel sheet supporting blocks are in sliding connection with the lifting plate;

and at least 2 silicon steel sheet supporting blocks II are arranged on the silicon steel sheet supporting rod, and the silicon steel sheet supporting blocks II are in sliding connection with the silicon steel sheet supporting rod.

Furthermore, the linear moving mechanism is provided with a station driving motor arranged at the bottom of the stacking station, the station driving motor is connected with a gear belt arranged on the stacking platform support through a gear, the bottom of the stacking station is connected with a sliding track on the stacking platform support in a sliding mode through a moving block, and the sliding track on the stacking platform support is arranged on the side edge of the gear belt.

Furthermore, a first driving motor is installed on the lifting plate, an output shaft of the first driving motor is connected with a first lead screw through a coupler, a first adjusting nut is arranged at the bottom of the silicon steel sheet supporting rod and is connected with the first lead screw in a matched mode, and the bottom of the first silicon steel sheet supporting block is connected with a sliding rail arranged on the lifting plate in a sliding mode through a sliding block.

Furthermore, a second driving motor is installed on the side edge of the silicon steel sheet supporting rod, the second driving motor drives a rotating shaft perpendicular to the silicon steel sheet supporting rod to rotate, the rotating shaft drives a second lead screw parallel to the silicon steel sheet supporting rod to rotate through a sector gear, the bottom of the side edge of the second silicon steel sheet supporting block is connected with a second adjusting nut, the second adjusting nut is connected with the second lead screw in a matched mode, and the bottom of the second silicon steel sheet supporting block is connected with a sliding rail arranged on the silicon steel sheet supporting rod in a sliding mode through a sliding block.

After adopting the structure, the utility model has the advantages that:

1. a plurality of stacking stations are arranged, the stacking stations can linearly move on the stacking platform bracket, and stacked iron cores can be output outwards after stacking is finished;

2. a lifting mechanism is arranged on a bottom plate of the stacking station, and the lifting mechanism can drive a lifting plate on the lifting mechanism to lift along with the change of the stacking height of the iron core;

3. the distance between the first silicon steel sheet supporting blocks and the distance between the second silicon steel sheet supporting blocks are adjusted through the matching of the multiple groups of adjusting nuts and the adjusting screw rods, so that the silicon steel sheets can move transversely and longitudinally, and the size can be automatically adjusted to be suitable for the stacking of iron cores of different specifications.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged schematic view of the structure within the circle in FIG. 1;

fig. 3 is a side view of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention will be further described in detail with reference to the accompanying drawings and the following detailed description. The following examples are presented to enable those skilled in the art to more fully understand the present invention and are not intended to limit the scope of the present invention.

As shown in fig. 1 to fig. 3, the following technical solutions are adopted in the present embodiment: it comprises

In the embodiment, two stacking stations 1 are provided, a linear moving mechanism 11 is provided at the bottom of the stacking station 1, and the linear moving mechanism 11 can drive the stacking station 1 to move outwards to output the iron core after stacking;

a lifting mechanism 12 is arranged on the bottom plate of the stacking station 1, the lifting mechanism 12 drives a lifting plate 13 on the lifting mechanism 12 to lift along with the change of the stacking height of the iron core through a lifting motor 121, guide pillars are arranged at the vertex angles of the lifting plate 13 and penetrate through the vertex angles of the bottom plate of the stacking station 1, and the lifting plate 13 lifts on the bottom plate through the guiding action of the guide pillars;

the lifting plate 13 is provided with silicon steel sheet supporting rods 14 which are perpendicular to the lifting plate 13, in the embodiment, the number of the silicon steel sheet supporting rods 14 is 2, the side edges of the silicon steel sheet supporting rods 14 are connected with 2 silicon steel sheet supporting blocks 141, the silicon steel sheet supporting rods 14 and the silicon steel sheet supporting blocks 141 are in sliding connection with the lifting plate 13, and the silicon steel sheet supporting blocks 141 move on the lifting plate 13, so that the adjustment of the distance between the silicon steel sheet supporting blocks 141 can be realized;

in this example, 3 silicon steel sheet supporting blocks two 142 are arranged on the silicon steel sheet supporting rod 14, the middle silicon steel sheet supporting block two 142 is fixed, the silicon steel sheet supporting blocks two 142 at two ends are slidably connected with the silicon steel sheet supporting rod 14, and the silicon steel sheet supporting blocks two 142 at two ends move on the silicon steel sheet supporting rod 14, so that the distance between the silicon steel sheet supporting blocks two 142 can be adjusted.

The linear moving mechanism 11 is provided with a station driving motor 111 arranged at the bottom of the stacking station 1, the station driving motor 111 is connected with a gear belt arranged on a stacking table support through a gear, the bottom of the stacking station 1 is connected with a sliding track on the stacking table support in a sliding mode through a moving block, the sliding track on the stacking table support is arranged on the side edge of the gear belt, the station driving motor 111 drives the gear to rotate, and the gear moves on the gear belt to drive the station to move linearly.

Install driving motor one 15 on the lifter plate 13, driving motor one 15's output shaft passes through coupling joint lead screw one, silicon steel sheet bracing piece 14's bottom is equipped with adjusting nut one, adjusting nut one is connected with the cooperation of lead screw one, the slide rail sliding connection that sets up on sliding block and the lifter plate 13 is passed through to silicon steel sheet supporting shoe one 141's bottom, driving motor one 15 drives lead screw one and rotates, because adjusting nut is firstly nonrotatable, adjusting nut produces the removal on lead screw one for a while, drive lifter plate 13 and remove, thereby drive silicon steel sheet supporting shoe one 141 and remove, the distance between silicon steel sheet supporting shoe one 141 is adjustable, make the distance between the silicon steel sheet on silicon steel sheet supporting shoe one 141 adjustable.

The side edge of the silicon steel sheet supporting rod 14 is provided with a second driving motor 16, the second driving motor 16 drives a rotating shaft perpendicular to the silicon steel sheet supporting rod 14 to rotate, the rotating shaft drives a second lead screw parallel to the silicon steel sheet supporting rod 14 to rotate through a sector gear, the bottom of the side edge of the second silicon steel sheet supporting block 142 is connected with a second adjusting nut, the second adjusting nut is connected with the second lead screw in a matched mode, the bottom of the second silicon steel sheet supporting block 142 is connected with a sliding rail arranged on the silicon steel sheet supporting rod 14 in a sliding mode through a sliding block, the second driving motor 16 drives the second lead screw to rotate under the action of the sector gear, the second adjusting nut is not rotatable and can move on the second lead screw, so that the second silicon steel sheet supporting block 142 is driven to move, the distance between the second silicon steel sheet supporting blocks 142 is adjustable.

The working principle is as follows: silicon steel sheets are placed on a first silicon steel sheet supporting block 141 and a second silicon steel sheet supporting block 142 on a stacking station 1 through a conveying device, two silicon steel sheets placed on the first silicon steel sheet supporting block 141 are perpendicular to three silicon steel sheets placed on the second silicon steel sheet supporting block 142, the stacking device is applied to the iron core in a shape like the Chinese character 'ri', a first driving motor 15 drives a first screw rod to rotate, an adjusting nut does not rotate, the adjusting nut moves on the first screw rod for a moment and drives a lifting plate 13 to move, so that the first silicon steel sheet supporting block 141 is driven to move, the distance between the first silicon steel sheet supporting block 141 is adjustable, the distance between the two silicon steel sheets on the first silicon steel sheet supporting block 141 is adjustable, a second driving motor 16 drives a second screw rod to rotate through the action of a sector gear, and the second adjusting nut does not rotate and moves on the second screw rod so as to drive the second silicon steel sheet supporting block, the distance between the two silicon steel sheet supporting blocks 142 is adjustable, so that the distance between the three silicon steel sheets on the two silicon steel sheet supporting blocks 142 is adjustable, the silicon steel sheet iron cores with different specifications can be stacked, after the iron core stacking height changes, the lifting mechanism 12 can drive the lifting plate 13 to lift, so that the subsequent stacking operation can be conveniently carried out, after the stacking on one stacking station 1 is completed, the linear moving mechanism 11 can drive the stacking station 1 to realize linear movement, and the stacked iron core is output.

A plurality of stacking stations are arranged, the stacking stations can linearly move on a stacking platform support, and stacked iron cores can be output outwards after stacking is finished; a lifting mechanism is arranged on a bottom plate of the stacking station, and the lifting mechanism can drive a lifting plate on the lifting mechanism to lift along with the change of the stacking height of the iron core; the distance between the first silicon steel sheet supporting blocks and the distance between the second silicon steel sheet supporting blocks are adjusted through the matching of the multiple groups of adjusting nuts and the adjusting screw rods, so that the silicon steel sheets can move transversely and longitudinally, and the size can be automatically adjusted to be suitable for the stacking of iron cores of different specifications.

The basic principles and main features of the invention and the advantages of the invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (4)

1. Transformer silicon steel sheet closed assembly platform device, its characterized in that: comprises that

At least one stacking station is arranged, a linear moving mechanism is arranged at the bottom of the stacking station, and the linear moving mechanism outputs the iron cores which are stacked outwards;

a lifting mechanism is arranged on a bottom plate of the stacking station, and the lifting mechanism drives a lifting plate on the lifting mechanism to lift along with the change of the stacking height of the iron core through a lifting motor;

the lifting plate is provided with at least 2 silicon steel sheet supporting rods which are perpendicular to the lifting plate, the side edge of each silicon steel sheet supporting rod is connected with a first silicon steel sheet supporting block, and the silicon steel sheet supporting rods and the first silicon steel sheet supporting blocks are in sliding connection with the lifting plate;

and at least 2 silicon steel sheet supporting blocks II are arranged on the silicon steel sheet supporting rod, and the silicon steel sheet supporting blocks II are in sliding connection with the silicon steel sheet supporting rod.

2. The transformer silicon steel sheet stacking table device according to claim 1, wherein: the linear moving mechanism is provided with a station driving motor arranged at the bottom of the stacking station, the station driving motor is connected with a gear belt arranged on the stacking platform support through a gear, the bottom of the stacking station is connected with a sliding track on the stacking platform support in a sliding mode through a moving block, and the sliding track on the stacking platform support is arranged on the side edge of the gear belt.

3. The transformer silicon steel sheet stacking table device according to claim 1, wherein: the lifting plate is provided with a first driving motor, an output shaft of the first driving motor is connected with a first lead screw through a coupler, the bottom of the silicon steel sheet supporting rod is provided with a first adjusting nut, the first adjusting nut is connected with the first lead screw in a matched mode, and the bottom of the first silicon steel sheet supporting block is connected with a sliding rail arranged on the lifting plate in a sliding mode through a sliding block.

4. The transformer silicon steel sheet stacking table device according to claim 1, wherein: and a second driving motor is installed on the side edge of the silicon steel sheet supporting rod and drives a rotating shaft perpendicular to the silicon steel sheet supporting rod to rotate, the rotating shaft drives a second lead screw parallel to the silicon steel sheet supporting rod to rotate through a sector gear, the bottom of the side edge of the second silicon steel sheet supporting block is connected with a second adjusting nut, the second adjusting nut is connected with the second lead screw in a matched mode, and the bottom of the second silicon steel sheet supporting block is connected with a sliding rail arranged on the silicon steel sheet supporting rod in a sliding mode through a sliding block.

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