CN220457260U - Rotor winding-off forming mechanism - Google Patents

Abstract

The utility model discloses a rotor off-line forming mechanism, which relates to the technical field of engine rotors and comprises a workbench, wherein a plurality of groups of bottom struts are arranged on the outer surface of the lower end of the workbench, a controller is arranged on the outer surface of the upper end of the workbench, a right fixed vertical plate is arranged on the outer surface of the right side of the controller, a push-pull cylinder is arranged on the outer surface of the right side of the right fixed vertical plate, an off-line forming frame is arranged on the outer surface of the upper end of the workbench, a telescopic cylinder is arranged on the outer surface of the upper end of the off-line forming frame, a push-pull block is arranged on the outer surface of the lower end of the off-line forming frame, and a line pressing blade is arranged on the outer surface of the lower end of the push-pull block. According to the rotor winding-off forming mechanism, the rotor to be processed is placed in the processing cavity through the processing cavity, copper wires which need to be wound off in a sufficient quantity are inserted into the wire harness grooves, and then the copper wires are pressed into the winding-off grooves of the rotor through the wire harness blades, so that the winding-off forming efficiency is greatly reduced, and the manpower is liberated.

Description

Rotor winding-off forming mechanism

Technical Field

The utility model relates to the technical field of engine rotors, in particular to a rotor off-line forming mechanism.

Background

The rotor is a rotating body supported by a bearing, is a main component of a power machine or a working machine such as an engine, a generator, a gas turbine, a turbine compressor and the like, and is rotated at a high speed.

The existing rotor winding-off forming mechanism is characterized in that when the existing rotor winding-off forming mechanism is installed and used, formed copper wires are required to be inserted into an iron core groove one by an operator, time and labor are wasted, efficiency is low, the rotor is required to be rotated for many times in the process of inserting the iron core, copper wires inside the iron core groove on the side face of the rotor are convenient to install, the volume of a part of engine rotor is large, time and labor are wasted, efficiency is low, certain adverse effects are brought to the use process of people, and in order to solve the defects in the prior art, the rotor winding-off forming mechanism is provided.

Disclosure of Invention

The utility model mainly aims to provide a rotor offline forming mechanism which can effectively solve the problems in the background technology.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

the rotor winding forming mechanism comprises a workbench, wherein a plurality of groups of bottom struts are arranged on the outer surface of the lower end of the workbench, a controller is arranged on the outer surface of the upper end of the workbench, a display panel is arranged on the outer surface of the front end of the controller, a control button is arranged on the lower end of the display panel, a right fixed vertical plate is arranged on the outer surface of the right side of the controller, a push-pull cylinder is arranged on the outer surface of the right side of the right fixed vertical plate, a fixed column is arranged on the outer surface of the left side of the right fixed vertical plate, a winding forming frame is arranged on the outer surface of the upper end of the workbench, a telescopic cylinder is arranged on the outer surface of the upper end of the winding forming frame, a push-pull block is arranged on the outer surface of the lower end of the winding forming frame, a line pressing blade is arranged on the outer surface of the lower end of the push-pull block, and a clamping groove plate is arranged on the side surface of the bottom end of the line pressing blade.

Preferably, the upper end surface of workstation is provided with left fixed riser, the left side surface of left fixed riser is provided with the work motor, the right side surface of left fixed riser is provided with the fine tuning rotation axis, the right side surface of fine tuning rotation axis is provided with the fixed connection roller, the inboard of fixed connection roller is provided with the rotatory roller, the right side surface of fixed connection roller is provided with two sets of connecting rods, the right side surface of two sets of connecting rods is provided with left connecting plate, the right side surface of left connecting plate is provided with the processing chamber, the right side surface of processing chamber is provided with right connecting plate, the inboard of right connecting plate is provided with the wire casing, the inboard of right connecting plate is provided with the connecting hole.

Preferably, the bottom pillar is provided with four groups in the even symmetry of lower extreme surface of workstation, right side fixed riser sets up the upper end surface at the workstation, control button is the even symmetry of front end surface of controller and sets up, the inboard of right side fixed riser is provided with the through-hole, the outer wall of fixed column passes through the through-hole and can dismantle with the inner wall of right side fixed riser and be connected.

Preferably, the inner side of the lower line forming frame is provided with a through hole, the telescopic cylinder is connected with the push-pull block through the through hole, the inner side of the line pressing blade is provided with a through hole, and the clamping groove plate is in sliding connection with the line pressing blade through the through hole.

Preferably, the inner side of the left fixed vertical plate is provided with a through hole, the outer wall of the rotary roller is detachably connected with the inner wall of the left fixed vertical plate through the through hole, and the rotary roller is arranged between the two groups of connecting rods.

Preferably, the left connecting plate is nested into the processing cavity, and the plurality of groups of wire binding grooves are uniformly formed in the inner side of the right connecting plate.

Advantageous effects

Compared with the prior art, the utility model has the following beneficial effects:

1. according to the utility model, the rotor to be processed is placed in the processing cavity through the processing cavity, copper wires which need to be laid down in a sufficient quantity are inserted into the wire harness grooves, and then the copper wires are all pressed into the wire harness grooves of the rotor by the wire harness blades, so that the efficiency of wire harness forming is greatly saved, and the manpower is liberated.

2. According to the utility model, the rotating roller is driven to carry out fine rotation adjustment on the rotor in the processing cavity through the fine adjustment rotating shaft, and manual carrying adjustment is not needed, so that the wire feeding groove of the rotor can be rapidly determined, the wire pressing blade can more accurately reach the wire feeding position, and the copper wire is pressed into the wire feeding groove of the rotor.

Drawings

FIG. 1 is a schematic view of the overall structure of the present utility model;

FIG. 2 is a schematic view of the structure of the processing chamber of the present utility model;

FIG. 3 is a schematic view of the structure of the down-line forming frame of the present utility model;

fig. 4 is a schematic view of the structure of the wire pressing blade of the present utility model.

In the figure: 1. a work table; 2. a bottom pillar; 3. a left fixed vertical plate; 4. a working motor; 5. a right fixed vertical plate; 6. a controller; 7. a display panel; 8. a control button; 9. a push-pull cylinder; 10. fixing the column; 11. a lower line forming frame; 12. finely adjusting a rotating shaft; 13. fixing a connecting roller; 14. a rotating roller; 15. a processing chamber; 16. a connecting rod; 17. a left connecting plate; 18. a right connecting plate; 19. wire bundling groove; 20. a connection hole; 21. a telescopic cylinder; 22. a push-pull block; 23. a wire pressing blade; 24. a slot plate.

Detailed Description

The utility model is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the utility model easy to understand.

In the first embodiment, as shown in fig. 1-4, the rotor winding forming mechanism comprises a workbench 1, a rotor to be processed is inserted into a processing cavity 15, a rotary roller 14 is inserted into the rotor to be processed so as not to fall off, then a right connecting plate 18 is processed again into the cavity 15, a push-pull cylinder 9 is started through a control button 8, the push-pull cylinder 9 pushes a fixed column 10 to move, and the fixed column passes through a connecting hole 20 to the rotor to be processed, so that the fixation of the rotor is completed, and then a corresponding number of copper wires are inserted into each group of wire binding grooves 19.

In the second embodiment, as shown in fig. 1-4, after the work is completed, the control button 8 controls the left connecting plate 17 to move towards the direction of the fixed column 10, the movement is stopped when the obtained processing cavity 15 is completely under the wire clamping blade 23, at this time, the control button 8 controls the telescopic cylinder 21 to push the push-pull block 22 to drive the wire clamping blade 23 to move downwards, after the copper wire is touched into the processing cavity 15, the clamping groove plate 24 limits the copper wire under the wire clamping blade 23, then the wire clamping blade 23 continues to move downwards under the push of the push-pull block 22, when the position of the rotor wire clamping groove is reached, the clamping groove plate 24 stays at two sides of the rotor wire clamping groove to limit the position of the copper wire, then the wire clamping blade 23 presses the copper wire into the rotor wire clamping groove, after the completion of the first position, the telescopic cylinder 21 pulls the push-pull block 22 to move upwards, the wire clamping blade 23 is driven to be separated from the rotor wire clamping groove upwards, the fine rotation shaft 12 is driven by the rotating roller 14 until the other position of the clamping groove is completely under the wire clamping blade 23, and the whole wire clamping groove is clamped, so that the forming process of the rotor wire is completed.

Principle of operation

It should be noted that, in the present utility model, the rotor winding forming mechanism is used, when the right connecting plate 18 is opened preferentially, the right connecting plate 18 is placed aside, then the rotor to be processed is inserted into the processing cavity 15, the rotating roller 14 is inserted into the rotor to be processed, so that the rotor will not fall, then the right connecting plate 18 is processed again into the cavity 15, the push-pull cylinder 9 is started by the control button 8, the push-pull cylinder 9 pushes the fixed column 10 to move, the connecting hole 20 passes through the rotor to be processed, thus completing the fixation of the rotor, then a corresponding number of copper wires are inserted into each group of wire harness slots 19, after the work is completed, the left connecting plate 17 is controlled by the control button 8 to move towards the fixed column 10, when the processing cavity 15 is completely under the wire harness blade 23, the movement is stopped, at this time, the push-pull block 22 is pushed by the control button 8 to drive the wire harness blade 23 to move downwards, after entering the processing cavity 15, after touching the copper wire, the clamping groove plate 24 limits the copper wire below the wire pressing blade 23, then the wire pressing blade 23 continues to move downwards under the pushing of the push-pull block 22, when reaching the position of the rotor wire feeding groove, the clamping groove plate 24 stays at two sides of the rotor wire feeding groove to limit the position of the copper wire, then the wire pressing blade 23 presses the copper wire into the rotor wire pressing groove, after one part is completed, the telescopic cylinder 21 pulls the push-pull block 22 to move upwards to drive the wire pressing blade 23 to be separated from the rotor wire pressing groove, the fine rotating shaft 12 drives the rotating roller 14 to rotate finely, and the wire pressing blade 23 is repeated to clamp the wire until the other part of the wire pressing groove is completely positioned right below the wire pressing blade 23, so that the wire clamping forming of the whole rotor is completed.

The foregoing has shown and described the basic principles and main features of the present utility model and the advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. Rotor off-line forming mechanism, including workstation (1), its characterized in that: the automatic wire drawing machine is characterized in that a plurality of groups of bottom struts (2) are arranged on the outer surface of the lower end of the workbench (1), a controller (6) is arranged on the outer surface of the upper end of the workbench (1), a display panel (7) is arranged on the outer surface of the front end of the controller (6), a control button (8) is arranged on the lower end of the display panel (7), a right fixed riser (5) is arranged on the outer surface of the right side of the controller (6), a push-pull cylinder (9) is arranged on the outer surface of the right side of the right fixed riser (5), a fixed column (10) is arranged on the outer surface of the left side of the right fixed riser (5), a wire drawing forming frame (11) is arranged on the outer surface of the upper end of the workbench (1), a telescopic cylinder (21) is arranged on the outer surface of the upper end of the wire drawing frame (11), a push-pull block (22) is arranged on the outer surface of the lower end of the wire drawing frame (11), a wire drawing blade (23) is arranged on the outer surface of the lower end of the push-pull block (22), and a clamping groove plate (24) is arranged on the side of the bottom of the wire drawing blade (23).

2. The rotor off-line forming mechanism of claim 1, wherein: the automatic wire bundling machine is characterized in that a left fixed vertical plate (3) is arranged on the outer surface of the upper end of the workbench (1), a working motor (4) is arranged on the outer surface of the left side of the left fixed vertical plate (3), a fine-tuning rotating shaft (12) is arranged on the outer surface of the right side of the left fixed vertical plate (3), a fixed connection roller (13) is arranged on the outer surface of the right side of the fine-tuning rotating shaft (12), a rotating roller (14) is arranged on the inner side of the fixed connection roller (13), two groups of connecting rods (16) are arranged on the outer surface of the right side of the fixed connection roller (13), a left connecting plate (17) is arranged on the outer surface of the right side of the two groups of connecting rods (16), a processing cavity (15) is arranged on the outer surface of the right side of the left connecting plate (17), a wire bundling groove (19) is arranged on the inner side of the right connecting plate (18), and a connecting hole (20) is formed in the inner side of the right connecting plate (18).

3. The rotor off-line forming mechanism of claim 1, wherein: the bottom support column (2) is evenly and symmetrically provided with four groups on the outer surface of the lower end of the workbench (1), the right fixed vertical plate (5) is arranged on the outer surface of the upper end of the workbench (1), the control button (8) is evenly and symmetrically arranged on the outer surface of the front end of the controller (6), a through hole is formed in the inner side of the right fixed vertical plate (5), and the outer wall of the fixed column (10) is detachably connected with the inner wall of the right fixed vertical plate (5) through the through hole.

4. The rotor off-line forming mechanism of claim 1, wherein: the inner side of the lower line forming frame (11) is provided with a through hole, the telescopic cylinder (21) is connected with the push-pull block (22) through the through hole, the inner side of the line pressing blade (23) is provided with a through hole, and the clamping groove plate (24) is in sliding connection with the line pressing blade (23) through the through hole.

5. The rotor off-line forming mechanism of claim 2, wherein: the inner side of the left fixed vertical plate (3) is provided with a through hole, the outer wall of the rotary roller (14) is detachably connected with the inner wall of the left fixed vertical plate (3) through the through hole, and the rotary roller (14) is arranged between two groups of connecting rods (16).

6. The rotor off-line forming mechanism of claim 2, wherein: the left connecting plate (17) is nested into the processing cavity (15), and the plurality of groups of wire binding grooves (19) are uniformly formed in the inner side of the right connecting plate (18).