CN221734483U - Motor iron core shaping device - Google Patents

Abstract

The utility model relates to a motor iron core shaping device which mainly comprises a plurality of presses, wherein the plurality of presses are arranged in a row, a first conveying line is arranged on one side of the row of presses, a plurality of first type conveying components are arranged on the outer side of the first conveying line, a second conveying line is arranged on the other side of the row of presses, a plurality of second type conveying components are arranged on the outer side of the second conveying line, a plurality of first type blocking components are arranged on one side of the first conveying line, the first type blocking components are used for blocking iron cores on the first conveying line at corresponding first type conveying components, a plurality of second type blocking components are arranged on the second conveying components, and the second type blocking components are used for blocking the iron cores on the second conveying line at corresponding second type conveying components. The device is favorable to improving the plastic efficiency of iron core.

Description

Motor iron core shaping device

Technical Field

The utility model relates to the field of motor iron core production, in particular to a motor iron core shaping device.

Background

The motor core needs to be shaped after the press riveting process. Shaping the iron core generally adopts a press, the iron core is placed on the press, and the iron core is pressed down by a pressure head of the press, so that the iron core is shaped. The traditional method is that after an iron core is placed on a press by a manipulator, the iron core is shaped, and after the shaping is finished, the iron core is taken out from the press by the manipulator and then placed on a conveying line. This shaping process is relatively inefficient.

Disclosure of utility model

Based on this, a motor core shaping device is provided. The device is favorable to improving the plastic efficiency of iron core.

The utility model provides a motor iron core shaping device, includes a plurality of press, and a plurality of press arranges into one row, and one side of one row of press is provided with first transfer chain, and the outside of first transfer chain is provided with a plurality of first class transport subassembly, and the opposite side of one row of press is provided with the second transfer chain, and the outside of second transfer chain is provided with a plurality of second class transport subassembly, and one side of first transfer chain is provided with a plurality of first class and blocks the subassembly, first class is blocked the subassembly and is used for blocking the iron core on the first transfer chain in the first class transport subassembly department that corresponds, and second transfer subassembly department is provided with a plurality of second class and blocks the subassembly, the second class is blocked the subassembly and is used for blocking the iron core on the second transfer chain in the second class transport subassembly department that corresponds.

In one embodiment, the number of presses is at least 4, the number of first type handling assemblies is at least 2, each first type handling assembly is for handling the core for 2 of the presses, the number of second type handling assemblies is at least 2, and each second type handling assembly is for handling the core for 2 of the presses.

In one embodiment, the first conveyor line is a belt conveyor line, the second conveyor line is a belt conveyor line, and the conveyor line further comprises a receiving box, wherein the receiving box is located at the tail ends of the first conveyor line and the second conveyor line.

In one embodiment, the press comprises a press head and a first lifting mechanism connected with the press head, an objective table is arranged below the press head, a positioning through hole is formed in the objective table, a positioning rod is arranged below the positioning through hole, and the positioning rod is connected with a second lifting mechanism.

In one embodiment, the first type handling component and the second type handling component have the same structure, the first type handling component comprises a base, a transverse cylinder is arranged on the base and connected with a driving plate, a first group of sliding blocks, a second group of sliding blocks, a third group of sliding blocks and a fourth group of sliding blocks are arranged on the base at intervals, a first sliding rail is arranged on the first group of sliding blocks, a second sliding rail is arranged on the second group of sliding blocks, a third sliding rail is arranged on the third group of sliding blocks, a fourth sliding rail is arranged on the fourth group of sliding blocks, the driving plate is connected with the first sliding rail, the second sliding rail, the third sliding rail and the fourth sliding rail respectively, a first frame body and a second frame body are further arranged, the first frame body is connected with the first sliding rail and the second sliding rail, a first lifting cylinder is arranged on the first lifting cylinder, a first clamping jaw cylinder is connected on the second frame body, and a second lifting cylinder is connected with a second clamping jaw.

In one embodiment, the first type blocking component has the same structure as the second type blocking component, the first type blocking component comprises a lifting component and a mounting plate connected with the lifting component, and a blocking plate is connected to the mounting plate.

In one embodiment, the blocking plate is provided with a groove.

The beneficial effects of the application are as follows:

The application is provided with a first conveying line and a second conveying line on two sides of a row of presses respectively, wherein one side of the first conveying line is provided with a plurality of first-type conveying components, and one side of the second conveying line is provided with a plurality of second-type conveying components. The first type carrying assembly can place the iron cores on the corresponding presses after the first conveying line conveys the iron cores, and the second type carrying assembly can carry the iron cores to the second conveying line for conveying after the press finishes shaping the iron cores. At this time, the first type of handling assembly can handle the iron cores on the first conveying line to the press again. With the device of the application, a plurality of iron cores can be shaped within a few seconds. The shaping efficiency is obviously improved.

Drawings

Fig. 1 is a schematic diagram of a motor core shaping apparatus according to an embodiment of the present application.

Fig. 2 is a schematic view of a press according to an embodiment of the application.

Fig. 3 is a schematic view of a first type of handling assembly according to an embodiment of the present application.

Fig. 4 is a schematic view of a first type of blocking assembly according to an embodiment of the present application.

Wherein:

110. A press; 120. a first conveyor line; 130. a second conveyor line; 140. a first type of handling assembly; 150. a second type of handling assembly; 160. a receiving box; 170. a first type of blocking assembly; 171. a lifting assembly; 172. a blocking plate;

111. a first lifting mechanism; 112. a pressure head; 113. a positioning rod; 114. a second lifting mechanism;

141. A base; 142. a driving plate; 1431. a first slide rail; 1432. a second slide rail; 1433. a third slide rail; 1434. a fourth slide rail; 1441. a first frame body; 1442. a second frame body; 1451. a first lifting cylinder; 1452. a second lifting cylinder; 1461. a first jaw cylinder; 1462. a second jaw cylinder; 147. a transverse cylinder;

200. And (3) an iron core.

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to the appended drawings.

As shown in fig. 1, an embodiment of the present application provides a motor core shaping device, which includes a plurality of presses 110, the plurality of presses 110 are arranged in a row, a first conveying line 120 is disposed on one side of the row of presses 110, a plurality of first type conveying components 140 are disposed on the outer side of the first conveying line 120, a second conveying line 130 is disposed on the other side of the row of presses 110, a plurality of second type conveying components are disposed on the outer side of the second conveying line 130, a plurality of first type blocking components are disposed on one side of the first conveying line 120, the first type blocking components are used for blocking cores on the first conveying line 120 at corresponding first type conveying components 140, a plurality of second type blocking components are disposed at the second conveying components, and the second type blocking components are used for blocking cores on the second conveying line 130 at corresponding second type conveying components.

Specifically, when the iron core to be shaped is conveyed on the first conveying line 120, the first type conveying assembly 140 can convey the iron core on the first conveying line 120 to the corresponding press 110 for shaping, and after shaping, the second type conveying mechanism can convey the iron core on the press 110 to the second conveying line 130 for conveying. Similarly, the second conveyor line 130 may also convey the iron core to be shaped, and at this time, the second type conveying mechanism is used to convey the iron core on the second conveyor line 130 to the corresponding press 110 for shaping, and after shaping, the first type conveying mechanism conveys the iron core on the press 110 to the first conveyor line 120 for conveying. So configured, the first conveyor line 120 may convey one type of core requiring shaping, and after shaping such core, the second conveyor line 130 may convey another type of core requiring shaping.

In one embodiment, the number of the presses 110 is at least 4, the number of the first type handling assemblies 140 is at least 2, each first type handling assembly 140 is configured to handle the iron core for 2 presses 110 therein, and the number of the second type handling assemblies is at least 2, each second type handling assembly is configured to handle the iron core for 2 presses 110 therein.

For example, as shown in fig. 1, the number of presses 110 is 4, with 4 presses 110 arranged in a row. The 4 presses 110 are provided with a first conveyor line 120 at one side and a second conveyor line 130 at the other side. The outer side of the first conveyor line 120 is provided with 2 first type handling assemblies 140, and each first type handling assembly 140 can handle 2 cores at a time. 2 second type carrying assemblies are arranged on the outer side of the second conveying line 130, and each second type carrying assembly can carry 2 iron cores at a time.

In one embodiment, the first conveyor line 120 is a belt conveyor line, the second conveyor line 130 is a belt conveyor line, and the conveyor line further includes a receiving box, where the receiving box is located at the tail ends of the first conveyor line 120 and the second conveyor line 130.

Specifically, the inlet end of the receiving box is close to the first conveying line 120 and the second conveying line 130. So arranged, the core on the first conveyor line 120 or the core on the second conveyor line 130 may drop into the magazine from the inlet end.

In one embodiment, as shown in fig. 2, the press 110 includes a ram and a first lifting mechanism connected to the ram, which may be the hydraulic press 110 and a corresponding guide assembly. The pressure head below is provided with the objective table, be provided with the location through-hole on the objective table, the location through-hole below is provided with the locating lever, the locating lever links to each other with second elevating system. The second lifting mechanism is an air cylinder.

After the iron core is carried on the objective table, the positioning rod extends out and is inserted into the through hole in the center of the iron core, and the iron core is positioned through the positioning rod. Then, the ram descends and applies pressure to the core. Then, the pressing head ascends, and the positioning rod resets. The handling assembly can handle the iron core.

In one embodiment, as shown in fig. 3, the first type of carrying assembly 140 and the second type of carrying assembly have the same structure, the first type of carrying assembly 140 includes a base 141, a transverse cylinder 147 is disposed on the base 141, the transverse cylinder 147 is connected with a driving plate 142, a first group of sliding blocks, a second group of sliding blocks, a third group of sliding blocks and a fourth group of sliding blocks are disposed on the base 141 at intervals, a first sliding rail 1431 is disposed on the first group of sliding blocks, a second sliding rail 1432 is disposed on the second group of sliding blocks, a third sliding rail 1433 is disposed on the third group of sliding blocks, a fourth sliding rail 1434 is disposed on the fourth group of sliding blocks, the driving plate 142 is connected with a first sliding rail 1431, a second sliding rail 1432, a third sliding rail 1433 and a fourth sliding rail 1434 respectively, a first frame 1441 is connected with the first sliding rail 1431 and the second sliding rail 1432, a second frame 1442 is connected with the first cylinder 1451, and a second cylinder 1452 is disposed on the first frame 1441.

Specifically, the transverse air cylinder 147 drives the driving plate 142 to move, the driving plate 142 drives each sliding rail to move, and each sliding rail drives the first frame 1441 and the second frame 1442 to move. The first lifting cylinder 1451 is used for driving the first clamping jaw cylinder 1461 to lift, and the second lifting cylinder 1452 is used for driving the second clamping jaw cylinder to lift. The first and second jaw cylinders 1461 and 1462 described above are used to pick up the iron cores. The clamping jaw on the clamping jaw cylinder can be provided with a simulated groove.

It will be appreciated that the first type of handling assembly 140 and the second type of handling assembly may be other embodiments, for example, the first type of handling assembly and the second type of handling assembly mainly include cylinders, the cylinders drive the frame to move laterally, two lifting cylinders are disposed on the frame, each lifting cylinder is provided with a clamping jaw cylinder, and the frame is integrally mounted on the guide rail assembly.

In one embodiment, as shown in fig. 4, the first type of blocking assembly has the same structure as the second type of blocking assembly, and the first type of blocking assembly includes a lifting assembly and a mounting plate connected to the lifting assembly, and a blocking plate is connected to the mounting plate. The lifting assembly may be a cylinder.

Specifically, the blocking plate can be lifted or lowered under the driving of the lifting assembly. After the blocking plate descends, the iron core can be blocked.

On the basis of the above, in one embodiment, the blocking plate is provided with a groove. The groove is used for accommodating the iron core.

The above examples illustrate only a few embodiments of the utility model, which are described in detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of protection of the present utility model is to be determined by the appended claims.

Claims (7)

1. The utility model provides a motor iron core shaping device, its characterized in that, including a plurality of press, a plurality of press arranges into one row, and one side of one row of press is provided with first transfer chain, and the outside of first transfer chain is provided with a plurality of first class transport subassembly, and the opposite side of one row of press is provided with the second transfer chain, and the outside of second transfer chain is provided with a plurality of second class transport subassembly, and one side of first transfer chain is provided with a plurality of first class and blocks the subassembly, first class is blocked the subassembly and is used for blockking the iron core on first transfer chain in the first class transport subassembly department that corresponds, and second transfer subassembly department is provided with a plurality of second class and blocks the subassembly, the second class is blocked the subassembly and is used for blockking the iron core on the second transfer chain in the second class transport subassembly department that corresponds.

2. The motor core shaping apparatus of claim 1 wherein the number of presses is at least 4, the number of first type handling assemblies is at least 2, each first type handling assembly is for handling cores for 2 of the presses, the number of second type handling assemblies is at least 2, and each second type handling assembly is for handling cores for 2 of the presses.

3. The motor core shaping device of claim 1 wherein the first conveyor line is a belt conveyor line and the second conveyor line is a belt conveyor line, further comprising a receiver positioned at the trailing ends of the first conveyor line and the second conveyor line.

4. The motor core shaping device of claim 1, wherein the press comprises a ram and a first lifting mechanism connected with the ram, an objective table is arranged below the ram, a positioning through hole is arranged on the objective table, a positioning rod is arranged below the positioning through hole, and the positioning rod is connected with a second lifting mechanism.

5. The motor core shaping device according to claim 1, wherein the first type handling component and the second type handling component have the same structure, the first type handling component comprises a base, a transverse air cylinder is arranged on the base, the transverse air cylinder is connected with a driving plate, a first group of sliding blocks, a second group of sliding blocks, a third group of sliding blocks and a fourth group of sliding blocks are further arranged on the base at intervals, a first sliding rail is arranged on the first group of sliding blocks, a second sliding rail is arranged on the second group of sliding blocks, a third sliding rail is arranged on the third group of sliding blocks, a fourth sliding rail is arranged on the fourth group of sliding blocks, the driving plate is connected with the first sliding rail, the second sliding rail, the third sliding rail and the fourth sliding rail respectively, a first frame body and a second frame body are further arranged, the first frame body is connected with the first sliding rail and the second sliding rail, a first lifting air cylinder is connected with the first clamping jaw air cylinder, a second lifting air cylinder is arranged on the second frame body, and a second lifting air cylinder is connected with the second clamping jaw.

6. The motor core shaping device of claim 1, wherein the first type of blocking assembly is identical in structure to the second type of blocking assembly, the first type of blocking assembly comprises a lifting assembly and a mounting plate connected with the lifting assembly, and a blocking plate is connected to the mounting plate.

7. The motor core shaping device of claim 6 wherein the barrier plate is provided with a groove.