CN206028738U - Vertical processingequipment of inversion of motor rotor core excircle - Google Patents

Abstract

The utility model discloses a vertical processingequipment of inversion of motor rotor core excircle, including workstation, knife rest, lathe tool, frame, primary shaft sliding module, secondary shaft sliding module, spindle unit, hydraulic chuck, the workstation is equipped with a mesa, the knife rest settle in on the mesa, the lathe tool is fixed in on the knife rest, the frame is equipped with the roof beam that is on a parallel with the first direction, primary shaft sliding module settle in constitute on the roof beam and follow the sliding connection of first direction, secondary shaft sliding module settle in primary shaft sliding module goes up the sliding connection who constitutes along the second direction, the spindle unit is fixed on the secondary shaft sliding module, the spindle unit is equipped with and is on a parallel with the pivot of second direction, hydraulic chuck fixes in the pivot. The beneficial effects of the utility model are that: electric motor rotor automatically clamped and high -efficient processing can be realized, the course of working is improved.

Description

The cylindrical inversion vertical machining device of motor rotor core

Technical field

This utility model belongs to rotor processing technique field, and in particular to a kind of cylindrical inversion of motor rotor core Vertical machining device.

Background technology

Motor is to realize important device that electric energy changes to mechanical energy, is widely used in all trades and professions.Motor mainly by turn Son and stator composition, rotor realize the rotation of motor.As shown in figure 1, rotor 200 is by rotating shaft 2001 and rotor core 2002 are constituted, and its production process mainly includes that rotating shaft is pressed into iron core, the cylindrical rolling paint cylindrical with iron core of processing iron core etc..Rotor Iron core it is cylindrical it is main by numerically controlled lathe processing, general method is first by rotor clamping in numerically controlled lathe by manual Main shaft on, main shaft rotarily drives workpiece rotation, realizes the turnery processing of rotor outer circle using knife rest feeding of fixing a cutting tool.It is electric at present There is following limitation in the machine rotor course of processing：

（1）Artificial loading and unloading, automaticity are low, and working (machining) efficiency is low；

（2）Workman needs directly to be contacted with lathe, and high labor intensive has certain potential safety hazard；

（3）Cost of labor rises steadily, labor shortage.

Utility model content

The purpose of this utility model is to overcome deficiency of the prior art, there is provided a kind of motor rotor core is cylindrical to fall Vertical machining device is put, rotor automated exchanged cutter and highly-efficient processing can be realized, improved the course of processing.

For solving prior art problem, the utility model discloses the vertical processing dress of the cylindrical inversion of motor rotor core Put, including workbench, knife rest, lathe tool, frame, first axle sliding module, the second axle sliding module, spindle unit, hydraulic chuck； Workbench is provided with a table top, and knife rest is placed on table top, and lathe tool is fixed on knife rest in the first direction；Frame is provided with parallel to The beam in one direction；First axle sliding module is placed on beam and constitutes being slidably connected in the first direction；Second axle sliding module is pacified It is placed in first axle sliding module and constitutes being slidably connected in a second direction；Spindle unit is fixed in the second axle sliding module； Spindle unit is provided with the rotating shaft parallel to second direction, and hydraulic chuck is fixed in rotating shaft；Hydraulic chuck can grip motor and turn The rotating shaft of son completes the cylindrical turning of rotor core；, parallel to table top, second direction is perpendicular to table top for first direction.

Further, first axle sliding module includes the first motor, the first guide rail, the first slide block, the first leading screw；First is electric Machine is fixed on beam, and the first guide rail is arranged on beam in the first direction；First leading screw is rotated in a first direction on beam, the One end of one leading screw is connected with the main shaft of the first motor；First slide block and the first guide rail constitute being slidably connected in the first direction, First slide block is provided with the first screwed hole for extending in a first direction；First slide block passes through the first screwed hole and the first leading screw spiral shell Stricture of vagina rotates connection.

Further, the second axle sliding module includes the second motor, the second guide rail, the second slide block, the second leading screw；Second is electric Machine is fixed on the first slide block, and the second guide rail is arranged on the first slide block in a second direction；Second leading screw is rotated in a second direction, On the first slide block, one end of the second leading screw is connected with the main shaft of the second motor；Second slide block and the second guide rail constitute edge Second direction is slidably connected, and the second slide block is provided with the second screwed hole for extending in a second direction；Second slide block is by the Two screwed holes are rotated with the second threads of lead screw and are connected.

Further, spindle unit is installed on the second slide block.

The invention also discloses the cylindrical method of motor rotor core is processed using said apparatus, including following step Suddenly：

The first step, lathe tool is fixedly mounted on the table top of workbench by knife rest；

Second step, spindle unit move to discharge position and move downward along the second axle sliding module, by hydraulic chuck The rotating shaft of rotor is gripped so as to its clamping on spindle unit, to be completed the automatic charging and clamping of workpiece；

3rd step, spindle unit are moved upwards along the second axle sliding module, then move on beam along first axle sliding module, Drive motor rotor moves to Working position；

4th step, after reaching Working position, spindle unit starts rotation, and drive motor rotor is rotated, and spindle unit is along vertical Straight guide is moved downward, and drive motor rotor vertical feed from the top down, lathe tool are processed to the outer circumference surface of rotor core；

5th step, completion of processing, spindle unit are moved upwards along the second axle sliding module, then are existed along first axle sliding module On beam, motion, drive motor rotor move to lower discharge position；

6th step, after reaching lower discharge position, spindle unit moves downwardly to blanking bin along the second axle sliding module, hydraulic clip Head release rotor, rotor fall the automatic blanking for completing workpiece.

Further, hydraulic chuck can clamp various sizes of rotor.

This utility model has the advantage that：By on the beam, spindle unit that can be vertically as well as horizontally Automatization's clamping of rotor, loading and unloading and processing feeding is realized, artificial loading and unloading is solved and clamping efficiency is low, labor The big problem of fatigue resistance, handling equipment and processing feed arrangement is united two into one, time beat is optimized, is greatly improved life Efficiency is produced, the potential safety hazard in production process is reduced.

Description of the drawings

Fig. 1 is the structural representation of rotor to be processed；

Structural representations of the Fig. 2 for one preferred embodiment of this utility model.

Reference：

10 workbench；101 table tops；

20 knife rests；

30 lathe tools；

40 frames；401 beams；

50 first axle sliding modules；

60 second axle sliding modules；

70 spindle units；

80 hydraulic chucks；

200 rotors；2001 rotating shafts；2002 rotor cores.

Specific embodiment

Below in conjunction with the accompanying drawings this utility model is further described.Following examples are only used for clearly illustrating this The technical scheme of utility model, and protection domain of the present utility model can not be limited with this.

As shown in Fig. 2 the cylindrical device of processing rotor 200, including workbench 10, knife rest 20, lathe tool 30, frame 40th, first axle sliding module 50, the second axle sliding module 60, spindle unit 70, hydraulic chuck 80.

Workbench 10 is provided with a table top 101, and knife rest 20 is placed on table top 101, and lathe tool 30 is fixed on knife in the first direction On frame 20.Frame 40 is provided with the beam 401 parallel to first direction；First axle sliding module 50 is placed on beam 401 and constitutes along One direction is slidably connected；Second axle sliding module 60 is placed in first axle sliding module 50 slip for constituting in a second direction Connection.Spindle unit 70 is fixed in the second axle sliding module 60, and spindle unit 70 is provided with the rotating shaft parallel to second direction, liquid Pressure chuck 80 is fixed in rotating shaft, and hydraulic chuck 80 can clamp the rotating shaft 2001 of various sizes of rotor 200 and complete to turn 2002 turning of sub- iron core.First direction is x-axis direction in Fig. 2, and it is parallel to table top 101；Second direction is y-axis direction in Fig. 2, It is perpendicular to table top 101.

Operation principle of the present utility model and process

Lathe tool 30 is fixedly mounted on the table top 101 of workbench 10 by knife rest 20.

Spindle unit 70 moves to discharge position and moves downward along the second axle sliding module 60, by hydraulic chuck 80 The rotating shaft 2001 of rotor 200 is gripped so as to its clamping on spindle unit 70, to be completed the automatic charging and clamping of workpiece.

Spindle unit 70 is moved upwards along the second axle sliding module 60, then is transported on beam 401 along first axle sliding module 50 Dynamic, drive motor rotor 200 moves to Working position.

After reaching Working position, spindle unit 70 starts rotation, and drive motor rotor 200 is rotated, and spindle unit 70 is along vertical Straight guide is moved downward, and the vertical feed from the top down of drive motor rotor 200, lathe tool 30 are entered to 200 outer circumference surface of rotor Row processing.

Completion of processing, spindle unit 70 are moved upwards along the second axle sliding module 60, then are existed along first axle sliding module 50 On beam 401, motion, drive motor rotor 200 move to lower discharge position.

After reaching lower discharge position, spindle unit 70 moves downwardly to blanking bin along the second axle sliding module 60, hydraulic chuck 80 unclamp rotor 200, and rotor 200 falls the automatic blanking for completing workpiece.

Preferably, first axle sliding module 50 includes the first motor, the first guide rail, the first slide block, the first leading screw； First motor is fixed on beam 401, and the first guide rail is arranged on beam 401 in the first direction；First leading screw is rotated in a first direction On beam 401, one end of the first leading screw is connected with the main shaft of the first motor；First slide block and the first guide rail are constituted along first Direction is slidably connected, and the first slide block is provided with the first screwed hole for extending in a first direction；First slide block passes through the first spiral shell Pit is rotated with the first threads of lead screw and is connected.

Preferably, the second axle sliding module 60 includes the second motor, the second guide rail, the second slide block, the second leading screw； Second motor is fixed on the first slide block, and the second guide rail is arranged on the first slide block in a second direction；Second leading screw is along second party To being rotatably installed on the first slide block, one end of the second leading screw is connected with the main shaft of the second motor；Second slide block and the second guide rail Being slidably connected in a second direction is constituted, the second slide block is provided with the second screwed hole for extending in a second direction；Second slide block Rotated with the second threads of lead screw by the second screwed hole and be connected.

Preferably, spindle unit 70 is installed on the second slide block.

The above is only preferred implementation of the present utility model, it is noted that for the common skill of the art For art personnel, on the premise of without departing from this utility model know-why, some improvement and deformation can also be made, these change Enter and deform also to should be regarded as protection domain of the present utility model.

Claims (4)

1. the cylindrical inversion vertical machining device of motor rotor core, including workbench, it is characterised in that：Also include knife rest, car Knife, frame, first axle sliding module, the second axle sliding module, spindle unit, hydraulic chuck；The workbench is provided with a table top, The knife rest is placed on the table top, and the lathe tool is fixed on the knife rest in the first direction；The frame is provided with parallel In the beam of first direction；The first axle sliding module is placed on the beam and constitutes being slidably connected along the first direction； The second axle sliding module is placed in the first axle sliding module and constitutes being slidably connected in a second direction；The main shaft Part is fixed in the second axle sliding module；The spindle unit is provided with the rotating shaft parallel to the second direction, described Hydraulic chuck is fixed in the rotating shaft；The hydraulic chuck can grip the rotating shaft of rotor and complete the outer of its rotor core Circle turning；, parallel to the table top, the second direction is perpendicular to the table top for the first direction.

2. the cylindrical inversion vertical machining device of motor rotor core according to claim 1, it is characterised in that：First axle Sliding module includes the first motor, the first guide rail, the first slide block, the first leading screw；First motor is fixed on the beam, institute State the first guide rail to be arranged on the beam along the first direction；First leading screw is rotatably installed in institute along the first direction State on beam, one end of first leading screw is connected with the main shaft of first motor；First slide block and first guide rail Being slidably connected along the first direction is constituted, first slide block is provided with the first screw thread extended along the first direction Hole；First slide block is rotated with first threads of lead screw by first screwed hole and is connected.

3. the cylindrical inversion vertical machining device of motor rotor core according to claim 2, it is characterised in that：Second axle Sliding module includes the second motor, the second guide rail, the second slide block, the second leading screw；Second motor is fixed on described first and slides On block, second guide rail is arranged on first slide block along the second direction；Second leading screw is along the second party To being rotatably installed on first slide block, one end of second leading screw is connected with the main shaft of second motor；Described Two slide blocks constitute being slidably connected along the second direction with second guide rail, and second slide block is provided with along the second party To the second screwed hole of extension；Second slide block is rotated with second threads of lead screw by second screwed hole and is connected Connect.

4. the cylindrical inversion vertical machining device of motor rotor core according to claim 3, it is characterised in that：The master Axle portion part is installed on second slide block.