CN113245630B

CN113245630B - Micro and special motor processing equipment

Info

Publication number: CN113245630B
Application number: CN202110571173.9A
Authority: CN
Inventors: 郭贵平
Original assignee: Shaoyang Hongzexin Electronic Technology Co ltd
Current assignee: Shaoyang Hongzexin Electronic Technology Co ltd
Priority date: 2021-05-25
Filing date: 2021-05-25
Publication date: 2022-09-09
Anticipated expiration: 2041-05-25
Also published as: CN113245630A

Abstract

The invention relates to the field of a micro special motor, in particular to a micro special motor processing device, which comprises a stator plate processing rack, a reciprocating intermittent transporter, a hydraulic propeller, a stator slot cutting regulator and a cutting puller, wherein the reciprocating intermittent transporter is connected to the stator plate processing rack in a left-right reciprocating sliding manner, the hydraulic propeller is connected to the middle end of the stator plate processing rack in an intermittent longitudinal sliding manner, the stator slot cutting regulator is connected to the hydraulic propeller in a threaded fit manner, and the cutting puller is fixedly connected to the stator slot cutting regulator; the invention has the beneficial effect that the inner wall of the motor stator plate can be rapidly and automatically processed.

Description

Micro and special motor processing equipment

Technical Field

The invention relates to the field of small and special motors, in particular to a small and special motor processing device.

Background

The patent number is CN202020556571.4 discloses a stamping device is used in manufacturing of motor stator punching, belong to motor stator punching technical field, including electric cabinet and base, the upper end of base is provided with connecting plate and first connecting bottom plate, the upper end of first connecting bottom plate is provided with the second cylinder, the upper end of second cylinder is provided with the second connecting bottom plate, the upper end of second connecting bottom plate is provided with the bearing block, the upper end of bearing block is provided with the movable rod, the third cylinder has been cup jointed on the movable rod, the bottom of third cylinder is provided with locking spanner. The utility model discloses, use through the cooperation of third cylinder, locking wrench and bumping post, will fix towards the piece, avoid towards the piece slippage, stability and accuracy when improving the device punching press improve the product percent of pass, use through the cooperation of connecting seat, punching press board, connecting axle, bearing block and second cylinder, can adjust the distance of movable rod and punching press board, make things convenient for the operation of punching press in advance towards the piece, convenience simple to use improves work efficiency. But this equipment can't automatic quick batch processing motor stator board's inside groove.

Disclosure of Invention

The invention aims to provide a micro special motor processing device which has the beneficial effect that the inner wall of a motor stator plate can be rapidly and automatically processed.

The purpose of the invention is realized by the following technical scheme:

the invention aims to provide a micro special motor processing device which comprises a stator plate processing rack, a reciprocating intermittent transporter, a hydraulic propeller, a stator slot cutting regulator and a cutting puller, wherein the reciprocating intermittent transporter is connected to the stator plate processing rack in a left-right reciprocating sliding mode, the hydraulic propeller is connected to the middle end of the stator plate processing rack in an intermittent longitudinal sliding mode, the stator slot cutting regulator is connected to the hydraulic propeller in a threaded fit mode, and the cutting puller is fixedly connected to the stator slot cutting regulator.

As a further optimization of the invention, the stator plate processing rack comprises a central processing rack, two limiting longitudinal sliding grooves, a hydraulic cylinder propelling rack and two stator plate stacking boxes, two shaping stator collection casees and interference cylinder, the internal fixation is the support plate, two horizontal spouts and miscellaneous material whereabouts round hole, both ends vertically are provided with two spacing vertical spouts respectively around the central processing frame inner wall, pneumatic cylinder propulsion frame fixed connection is in central processing frame upper end, two stator board accumulation box respectively fixed connection are at the upside at central processing frame both ends, two shaping stator collection casees are the downside of fixed connection at central processing frame both ends respectively, interfere the lower extreme at shaping stator collection incasement wall of cylinder sliding connection, the internal fixation is support plate fixed connection in central processing frame, including two horizontal spouts evenly set up, the internal fixation is on the support plate, miscellaneous material whereabouts round hole sets up the middle-end that is the support plate including fixed.

As a further optimization of the invention, the reciprocating intermittent conveyor comprises a variable frequency driving motor, two sliding toothed plates, two present carrier plates, a falling groove and two sliding pushing baffles, wherein the variable frequency driving motor is fixedly connected to the lower end of the inner wall of the central processing frame through a motor fixing seat, the two sliding toothed plates are respectively connected with a transmission shaft of the variable frequency driving motor through gear meshing transmission, the two sliding toothed plates are respectively and slidably connected in the two transverse sliding grooves, the lower ends of the two present carrier plates are respectively and fixedly connected with the two sliding toothed plates, the falling groove is arranged between the two present carrier plates, the two sliding pushing baffles are respectively and fixedly connected to the two present carrier plates, and the present carrier plates and the sliding pushing baffles are slidably connected to two ends of the central processing frame.

As a further optimization of the invention, the hydraulic thruster comprises an intermittent driving oil cylinder, an oil cylinder top frame, a cutting edge fixing frame, two longitudinal limiting sliding seats and a fixing threaded hole, wherein the intermittent driving oil cylinder is fixedly connected at the middle end of the hydraulic cylinder propelling frame, a telescopic rod of the intermittent driving oil cylinder is fixedly connected at the middle end of the oil cylinder top frame, the oil cylinder top frame is fixedly connected on the cutting edge fixing frame, the cutting edge fixing frame is fixedly connected between the two longitudinal limiting sliding seats and longitudinally and slidably connected in the two limiting longitudinal sliding grooves, and the fixing threaded hole is arranged at the middle end of the cutting edge fixing frame.

As a further optimization of the invention, the stator slot cutting regulator comprises a fixed screw shaft, a hinged propulsion wheel, a plurality of hinged rods, a plurality of hinged propulsion sliding shafts, a plurality of cutting regulation chutes, a fixed top disc, a plurality of spring shaft holes, a plurality of fixed platforms, a stator inner circle cutting edge and a T-shaped slot cutting edge, wherein the fixed screw shaft is connected in the fixed screw hole in a threaded fit manner, the lower end of the fixed screw shaft is fixedly connected at the middle end of the fixed top disc, the hinged propulsion wheel is fixedly connected on the fixed screw shaft, the hinged propulsion wheel is uniformly hinged with a plurality of hinged rods, the outer ends of the hinged rods are respectively hinged with the plurality of hinged propulsion sliding shafts which are slidably connected in the cutting regulation chutes, the plurality of cutting regulation chutes are uniformly arranged on the fixed top disc, the lower end of the hinged propulsion sliding shaft is fixedly connected with the T-shaped slot cutting edge, and the plurality of spring shaft holes are uniformly arranged on the fixed top disc, the even fixed connection of a plurality of fixed stations is at the lower extreme, and circle cutting edge fixed connection is at the lower extreme of a plurality of fixed stations in the stator.

As a further optimization of the invention, the cutting puller comprises a puller disc, a plurality of spring shafts, a plurality of spring top seats and a plurality of puller springs, wherein the puller disc is fixedly connected to the lower ends of the spring shafts, the spring shafts are slidably connected in spring shaft holes and the spring top seats, the spring top seats are fixedly connected in fixed top disks, and the puller springs are sleeved in the spring shafts and arranged between the spring top seats and the fixed top disks.

As a further optimization of the invention, the inner circle cutting edge of the stator is a circular edge with a right-angled outer wall and an inclined inner wall.

As a further optimization of the invention, the jacking disc is arranged at the lower end of the inner circle cutting edge of the stator; the inner circle cutting edges of the stator are arranged at the lower ends of the plurality of T-shaped groove cutting edges.

As a further optimization of the invention, the side end of the fixed screw shaft is in threaded fit with the adjusting screw, and the threaded fit adjusting screw is meshed with the inner wall of the hinged propelling wheel.

As a further optimization of the invention, the height of the sliding propulsion baffle plate higher than the bearing plate is the same as the thickness of the stator plate.

Compared with the prior art, the technical scheme provided by the invention has the following beneficial effects that the inner wall of the motor stator plate can be rapidly and automatically processed; stator slot cutting regulators with different slot numbers can be better adjusted according to the specification requirements; the depth of the trapezoid groove on the inner wall of the stator can be adjusted; can push up tight stator board before cutting process, prevent to take place cutting a plurality of inner wall dovetail grooves of cutting behind the appointed diameter of earlier cutting inner wall after the deviation.

Drawings

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a first schematic structural view of a stator plate processing rack of the present invention;

FIG. 4 is a second structural view of the stator plate processing frame of the present invention;

FIG. 5 is a schematic view of the structure of the reciprocating intermittent conveyor of the present invention;

FIG. 6 is a partial structural schematic of the present invention;

FIG. 7 is a schematic diagram of the hydraulic thruster of the present invention;

FIG. 8 is a first schematic view of the stator slot cutting adjuster of the present invention;

FIG. 9 is a second schematic structural view of the stator slot cutting adjuster of the present invention;

FIG. 10 is a schematic view of the cutting tip of the present invention.

In the figure: a stator plate processing rack 1; a central processing frame 1-1; a limiting longitudinal sliding groove 1-2; a hydraulic cylinder propulsion frame 1-3; a stator plate accumulation box 1-4; forming a stator recovery box 1-5; 1-6 of interference cylinders; a carrier plate 1-7 is fixed inside; 1-8 of a transverse chute; 1-9 parts of sundry material falling round hole; a reciprocating intermittent transporter 2; a variable frequency drive motor 2-1; a sliding toothed plate 2-2; 2-3 of a carrying pallet; 2-4 of a drop tank; sliding the pushing baffle 2-5; a hydraulic thruster 3; intermittently driving the oil cylinder 3-1; 3-2 of an oil cylinder top frame; a cutting edge fixing frame 3-3; 3-4 of a longitudinal limiting sliding seat; 3-5 of a fixed threaded hole; a stator slot cutting adjuster 4; fixing a screw shaft 4-1; the hinged propulsion wheel 4-2; a hinge rod 4-3; a hinged propulsion sliding shaft 4-4; cutting and adjusting the sliding chute 4-5; 4-6 of a fixed top plate; a spring shaft hole 4-7; 4-8 of a fixed table; 4-9 parts of inner circle cutting edges of the stator; 4-10 parts of a T-shaped groove cutting edge; a cutting ejector 5; tightly pushing the disc 5-1; 5-2 of a spring shaft; 5-3 parts of a spring top seat; and 5-4 of a jacking spring.

Detailed Description

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

The fixed connection in the device can be fixed by welding, thread fixing and the like, the rotary connection can be realized by baking the bearing on a shaft, a spring retainer groove or an inter-shaft baffle is arranged on the shaft or a shaft hole, the axial fixation of the bearing is realized by clamping an elastic retainer ring in the spring retainer groove or the inter-shaft baffle, and the rotation is realized by the relative sliding of the bearing; different connection modes are used in combination with different use environments.

The first specific implementation way is as follows:

as shown in fig. 1 to 10, the micro special motor processing device comprises a stator plate processing rack 1, a reciprocating intermittent transporter 2, a hydraulic propeller 3, a stator slot cutting regulator 4 and a cutting puller 5, wherein the reciprocating intermittent transporter 2 is connected to the stator plate processing rack 1 in a left-right reciprocating sliding manner, the hydraulic propeller 3 is connected to the middle end of the stator plate processing rack 1 in an intermittent longitudinal sliding manner, the stator slot cutting regulator 4 is connected to the hydraulic propeller 3 in a threaded fit manner, and the cutting puller 5 is fixedly connected to the stator slot cutting regulator 4. The stator plate is stacked on the stator plate processing rack 1, and is pushed to the lower end of the hydraulic propeller 3 through the reciprocating intermittent motion of the reciprocating intermittent conveyor 2; the stator slot cutting regulator 4 is fixed on the hydraulic propeller 3, the hydraulic propeller 3 is driven intermittently to cut the stator plate through the stator slot cutting regulator 4, the stator plate is extruded and tightly pressed through the cutting and pressing device 5, then the inner wall of a specified stator is cut in the pressing process, and then the trapezoidal slots with uniform inner walls of the stator are cut in sequence; automatically recycling the cut stator plates after cutting, and simultaneously adding new stator plates; so as to reciprocate. Thereby realizing the fast and automatic processing of the inner wall of the motor stator plate; stator slot cutting regulators with different slot numbers can be better adjusted according to the specification requirements; the depth of the trapezoid groove on the inner wall of the stator can be adjusted; can push up tight stator board before cutting process, prevent to take place cutting a plurality of inner wall dovetail grooves of cutting behind the appointed diameter of earlier cutting inner wall after the deviation.

The second embodiment is as follows:

as shown in FIGS. 1 to 10, the first embodiment is further explained in the present embodiment, the stator plate processing rack 1 includes a central processing rack 1-1, two limiting longitudinal sliding grooves 1-2, a hydraulic cylinder pushing rack 1-3, two stator plate stacking boxes 1-4, two formed stator recycling boxes 1-5 and an interference cylinder 1-6, an internal fixing support plate 1-7, two transverse sliding grooves 1-8 and a round hole for dropping sundries 1-9, the front and rear ends of the inner wall of the central processing rack 1-1 are respectively and longitudinally provided with two limiting longitudinal sliding grooves 1-2, the hydraulic cylinder pushing rack 1-3 is fixedly connected to the upper end of the central processing rack 1-1, the two stator plate stacking boxes 1-4 are respectively and fixedly connected to the upper sides of the two ends of the central processing rack 1-1, and the two formed stator recycling boxes 1-5 are respectively and fixedly connected to the two ends of the central processing rack 1-1 The lower side of the interference cylinder 1-6 is connected with the lower end of the inner wall of the formed stator recovery box 1-5 in a sliding way, an internal fixed support plate 1-7 is fixedly connected in a central processing frame 1-1, two transverse sliding grooves 1-8 are uniformly arranged on the internal fixed support plate 1-7, and a sundry falling round hole 1-9 is arranged at the middle end of the internal fixed support plate 1-7. Motor stator plates are stacked in two stator plate stacking boxes 1-4, a variable-frequency driving motor 2-1 is electrically connected to drive two sliding tooth plates 2-2 to slide in two transverse sliding grooves 1-8 which are fixed on carrier plates 1-7 in an inner mode, when a sliding propulsion baffle 2-5 is separated from blocking the stator plate stacking boxes 1-4, a stator falls on two carrier plates 2-3 and a falling groove 2-4, the stator cannot fall in a formed stator recovery box 1-5 due to the fact that the diameter of the stator plate is smaller than that of an interference cylinder 1-6, the sliding propulsion baffle 2-5 pushes the stator plate falling on the two carrier plates 2-3 and the falling groove 2-4 to a mixed material falling circular hole 1-9 and stops, meanwhile, the sliding propulsion baffle 2-5 blocks the two stator plate stacking boxes 1-4 until the formed stator plate is pushed to the formed stator recovery box 1-5 and the interference cylinder 1- And 6, the inner diameter of the cut stator is larger than that of the interference cylinder 1-6, and then the cut stator falls into a formed stator recovery box 1-5 for recovery, and the steps are repeated.

The third concrete implementation mode:

as shown in fig. 1 to 10, the second embodiment is further described in the present embodiment, the reciprocating intermittent conveyor 2 includes a variable frequency driving motor 2-1, two sliding toothed plates 2-2, two present carrying plates 2-3, a falling chute 2-4 and two sliding pushing baffles 2-5, the variable frequency driving motor 2-1 is fixedly connected to the lower end of the inner wall of the central processing frame 1-1 through a motor fixing seat, the two sliding toothed plates 2-2 are respectively connected to a transmission shaft of the variable frequency driving motor 2-1 through gear meshing transmission, the two sliding toothed plates 2-2 are respectively connected in two transverse sliding chutes 1-8 in a sliding manner, the lower ends of the two present carrying plates 2-3 are both fixedly connected to the two sliding toothed plates 2-2, the falling chute 2-4 is arranged between the two present carrying plates 2-3, the two sliding pushing baffles 2-5 are respectively and fixedly connected to the two bearing plates 2-3, and the bearing plates 2-3 and the sliding pushing baffles 2-5 are slidably connected to two ends of the central processing frame 1-1.

The fourth concrete implementation mode is as follows:

as shown in fig. 1 to 10, in the third embodiment, the hydraulic thruster 3 includes an intermittent driving cylinder 3-1 and a cylinder top frame 3-2, the intermittent type driving oil cylinder 3-1 is fixedly connected to the middle end of the hydraulic cylinder propelling frame 1-3, a telescopic rod of the intermittent type driving oil cylinder 3-1 is fixedly connected to the middle end of the oil cylinder top frame 3-2, the oil cylinder top frame 3-2 is fixedly connected to the cutting edge fixing frame 3-3, the cutting edge fixing frame 3-3 is fixedly connected between the two longitudinal limiting sliding seats 3-4 and longitudinally slidably connected into the two limiting longitudinal sliding grooves 1-2, and the fixing threaded hole 3-5 is formed in the middle end of the cutting edge fixing frame 3-3. The intermittent driving oil cylinder 3-1 intermittently pushes the oil cylinder top frame 3-2, the cutting edge fixing frame 3-3 and the two longitudinal limiting sliding seats 3-4 to reciprocate longitudinally in the two limiting longitudinal sliding grooves 1-2 on the hydraulic cylinder pushing frame 1-3, so that power is provided for cutting when the stator plates are positioned in the sundry falling round holes 1-9.

The fifth concrete implementation mode is as follows:

as shown in fig. 1 to 10, the fourth embodiment is further illustrated in the present embodiment, the stator slot cutting adjuster 4 includes a fixed screw shaft 4-1, a hinged propulsion wheel 4-2, a plurality of hinged rods 4-3, a plurality of hinged propulsion sliding shafts 4-4, a plurality of cutting adjustment sliding chutes 4-5, a fixed top disk 4-6, a plurality of spring shaft holes 4-7, a plurality of fixed platforms 4-8, stator inner circular cutting edges 4-9 and T-shaped slot cutting edges 4-10, the fixed screw shaft 4-1 is connected in the fixed threaded hole 3-5 by screw thread fit, the lower end of the fixed screw shaft 4-1 is fixedly connected to the middle end of the fixed top disk 4-6, the hinged propulsion wheel 4-2 is fixedly connected to the fixed screw shaft 4-1, the hinged propulsion wheel 4-2 is uniformly hinged to the plurality of hinged rods 4-3, the outer ends of the plurality of hinged rods 4-3 are respectively hinged with a plurality of hinged propulsion sliding shafts 4-4, the hinged propulsion sliding shafts 4-4 are slidably connected into cutting regulation sliding chutes 4-5, the plurality of cutting regulation sliding chutes 4-5 are uniformly arranged on the fixed top disc 4-6, the lower end of the hinged propulsion sliding shaft 4-4 is fixedly connected with T-shaped groove cutting edges 4-10, a plurality of spring shaft holes 4-7 are uniformly arranged on the fixed top disc 4-6, a plurality of fixed tables 4-8 are uniformly and fixedly connected at the lower end, and the inner circle cutting edges 4-9 of the stator are fixedly connected at the lower ends of the plurality of fixed tables 4-8.

The sixth specific implementation mode:

as shown in fig. 1 to 10, in the present embodiment, a fifth embodiment is further described, wherein the cutting jacking device 5 includes a jacking disk 5-1, a plurality of spring shafts 5-2, a plurality of spring footstock 5-3 and a plurality of jacking springs 5-4, the jacking disk 5-1 is fixedly connected to the lower ends of the plurality of spring shafts 5-2, the spring shafts 5-2 are slidably connected to the spring shaft holes 4-7 and the spring footstock 5-3, the spring footstock 5-3 is fixedly connected to the fixed footstock 4-6, and the jacking springs 5-4 are sleeved in the spring shafts 5-2 and are arranged between the spring footstock 5-3 and the fixed footstock 4-6. The stator plate is extruded and fixed through the tightening disc 5-1, fixed positions are realized through the spring shafts 5-2, the spring top seats 5-3 and the tightening springs 5-4, the stator is cut into a stator with determined diameters through the downward stator inner circle cutting edges 4-9 in sequence, and the cutting of the trapezoid grooves of the stator is realized through the T-shaped groove cutting edges 4-10, so as to reciprocate.

The seventh embodiment:

as shown in fig. 1 to 10, in the sixth embodiment, the inner circular cutting edge 4-9 of the stator is a circular edge whose outer wall is right-angled and inner wall is inclined.

The specific implementation mode is eight:

as shown in fig. 1 to 10, in the present embodiment, to further explain the seventh embodiment, the tightening disc 5-1 is disposed at the lower end of the inner circle cutting edge 4-9 of the stator; the stator inner circle cutting edge 4-9 is arranged at the lower end of the plurality of T-shaped groove cutting edges 4-10.

The specific implementation method nine:

as shown in fig. 1 to 10, in the eighth embodiment, the side end of the fixed screw shaft 4-1 is engaged with the adjusting screw, and the adjusting screw is engaged with the inner wall of the hinged propulsion wheel 4-2. The screw thread of the side end of the fixed screw shaft 4-1 is matched with the adjusting screw rod through rotation, so that the hinged propulsion wheel 4-2 is driven to rotate on the fixed screw shaft 4-1, the hinged propulsion sliding shafts 4-4 are pushed to slide in the cutting adjusting sliding grooves 4-5, and the depth of the cutting dovetail groove is adjusted.

The detailed implementation mode is ten:

as shown in fig. 1 to 10, in the present embodiment, a ninth embodiment is further described, wherein the height of the sliding push baffle 2-5 above the supporting plate 2-3 is the same as the thickness of the stator plate.

The working principle of the invention is as follows: motor stator plates are stacked in two stator plate stacking boxes 1-4, a variable-frequency driving motor 2-1 is electrically connected to drive two sliding tooth plates 2-2 to slide in two transverse sliding grooves 1-8 which are fixed on carrier plates 1-7 in an inner mode, when a sliding propulsion baffle 2-5 is separated from blocking the stator plate stacking boxes 1-4, a stator falls on two carrier plates 2-3 and a falling groove 2-4, the stator cannot fall in a formed stator recovery box 1-5 due to the fact that the diameter of the stator plate is smaller than that of an interference cylinder 1-6, the sliding propulsion baffle 2-5 pushes the stator plate falling on the two carrier plates 2-3 and the falling groove 2-4 to a mixed material falling circular hole 1-9 and stops, meanwhile, the sliding propulsion baffle 2-5 blocks the two stator plate stacking boxes 1-4 until the formed stator plate is pushed to the formed stator recovery box 1-5 and the interference cylinder 1-6, the inner diameter of the cut stator is larger than that of the interference cylinder 1-6, and then the cut stator falls into a formed stator recovery box 1-5 for recovery, and the steps are repeated; the intermittent driving oil cylinder 3-1 intermittently pushes an oil cylinder top frame 3-2, a cutting edge fixing frame 3-3 and two longitudinal limiting sliding seats 3-4 to perform longitudinal reciprocating displacement in two limiting longitudinal sliding grooves 1-2 on a hydraulic cylinder pushing frame 1-3, so that power is provided for cutting when the stator plates are positioned in the sundry falling round holes 1-9; the stator plate is extruded and fixed through the tightening disc 5-1, fixed positions are realized through the spring shafts 5-2, the spring top seats 5-3 and the tightening springs 5-4, the stator is cut into a stator with determined diameters through the downward stator inner circle cutting edges 4-9 in sequence, and the cutting of the trapezoid grooves of the stator is realized through the T-shaped groove cutting edges 4-10, so as to reciprocate; the screw thread of the side end of the fixed screw shaft 4-1 is matched with the adjusting screw rod through rotation, so that the hinged propulsion wheel 4-2 is driven to rotate on the fixed screw shaft 4-1, the hinged propulsion sliding shafts 4-4 are pushed to slide in the cutting adjusting sliding grooves 4-5, and the depth of the cutting dovetail groove is adjusted. Thereby realizing the fast and automatic processing of the inner wall of the motor stator plate; stator slot cutting regulators with different slot numbers can be better adjusted according to the specification requirements; the depth of the trapezoid groove on the inner wall of the stator can be adjusted; can push up tight stator board before cutting process, prevent to take place cutting earlier after the deviation a plurality of inner wall dovetail grooves of cutting behind the appointed diameter of inner wall.

The above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and variations, modifications, additions and substitutions which may be made by those skilled in the art within the spirit of the present invention are within the scope of the present invention.

Claims

1. The utility model provides a little special motor processing equipment, includes stator board processing frame (1), reciprocal intermittent type conveyer (2), hydraulic pressure propeller (3), stator slot cutting regulator (4) and cutting puller (5), its characterized in that: the reciprocating intermittent transporter (2) is connected to the stator plate processing rack (1) in a left-right reciprocating sliding manner, the hydraulic propeller (3) is connected to the middle end of the stator plate processing rack (1) in an intermittent longitudinal sliding manner, the stator slot cutting regulator (4) is connected to the hydraulic propeller (3) in a threaded fit manner, and the cutting puller (5) is fixedly connected to the stator slot cutting regulator (4);

the stator plate processing rack (1) comprises a central processing frame (1-1), two limiting longitudinal sliding grooves (1-2), a hydraulic cylinder pushing frame (1-3), two stator plate stacking boxes (1-4), two formed stator recovery boxes (1-5), interference cylinders (1-6), an internal fixed support plate (1-7), two transverse sliding grooves (1-8) and a sundry falling round hole (1-9), wherein the front end and the rear end of the inner wall of the central processing frame (1-1) are respectively and longitudinally provided with the two limiting longitudinal sliding grooves (1-2), the hydraulic cylinder pushing frame (1-3) is fixedly connected to the upper end of the central processing frame (1-1), the two stator plate stacking boxes (1-4) are respectively and fixedly connected to the upper sides of the two ends of the central processing frame (1-1), the two formed stator recovery boxes (1-5) are respectively fixedly connected to the lower sides of two ends of a central processing frame (1-1), interference cylinders (1-6) are slidably connected to the lower ends of the inner walls of the formed stator recovery boxes (1-5), an internal fixed support plate (1-7) is fixedly connected in the central processing frame (1-1), two transverse sliding grooves (1-8) are uniformly arranged on the internal fixed support plate (1-7), and a sundry falling round hole (1-9) is arranged at the middle end of the internal fixed support plate (1-7);

the reciprocating intermittent conveyor (2) comprises a variable frequency driving motor (2-1), two sliding toothed plates (2-2), two load bearing plates (2-3), a drop chute (2-4) and two sliding pushing baffles (2-5), the variable frequency driving motor (2-1) is fixedly connected to the lower end of the inner wall of the central processing frame (1-1) through a motor fixing seat, the two sliding toothed plates (2-2) are respectively connected with a transmission shaft of the variable frequency driving motor (2-1) through gear meshing transmission, the two sliding toothed plates (2-2) are respectively connected in two transverse sliding chutes (1-8) in a sliding manner, the lower ends of the two load bearing plates (2-3) are respectively and fixedly connected with the two sliding toothed plates (2-2), the drop chute (2-4) is arranged between the two load bearing plates (2-3), the two sliding pushing baffles (2-5) are respectively and fixedly connected to the two bearing plates (2-3), and the bearing plates (2-3) and the sliding pushing baffles (2-5) are slidably connected to two ends of the central processing frame (1-1).

2. A micro-electro-mechanical machining apparatus as claimed in claim 1, wherein: the hydraulic propeller (3) comprises an intermittent driving oil cylinder (3-1), an oil cylinder top frame (3-2), a cutting edge fixing frame (3-3), two longitudinal limiting sliding seats (3-4) and a fixing threaded hole (3-5), the intermittent driving oil cylinder (3-1) is fixedly connected to the middle end of the hydraulic cylinder propelling frame (1-3), the telescopic rod of the intermittent driving oil cylinder (3-1) is fixedly connected to the middle end of the oil cylinder top frame (3-2), the oil cylinder top frame (3-2) is fixedly connected to the cutting edge fixing frame (3-3), the cutting edge fixing frame (3-3) is fixedly connected between the two longitudinal limiting sliding seats (3-4) and longitudinally and slidably connected into the two limiting longitudinal sliding grooves (1-2), and the fixing threaded hole (3-5) is arranged at the middle end of the cutting edge fixing frame (3-3).

3. A micro-electro-mechanical machining apparatus as claimed in claim 2, wherein: the stator slot cutting regulator (4) comprises a fixed screw shaft (4-1), an articulated propulsion wheel (4-2), a plurality of articulated rods (4-3), a plurality of articulated propulsion sliding shafts (4-4), a plurality of cutting regulation sliding chutes (4-5), a fixed top disc (4-6), a plurality of spring shaft holes (4-7), a plurality of fixed platforms (4-8), a stator inner circle cutting edge (4-9) and a T-shaped slot cutting edge (4-10), wherein the fixed screw shaft (4-1) is connected in a fixed threaded hole (3-5) in a threaded fit manner, the lower end of the fixed screw shaft (4-1) is fixedly connected to the middle end of the fixed top disc (4-6), the articulated propulsion wheel (4-2) is fixedly connected to the fixed screw shaft (4-1), and the articulated propulsion wheel (4-2) is uniformly articulated with the plurality of articulated rods (4-3), the outer ends of the hinged rods (4-3) are hinged with a plurality of hinged propulsion sliding shafts (4-4) respectively, the hinged propulsion sliding shafts (4-4) are connected in cutting regulation sliding chutes (4-5) in a sliding mode, the cutting regulation sliding chutes (4-5) are evenly arranged on the fixed top disc (4-6), the lower end of each hinged propulsion sliding shaft (4-4) is fixedly connected with a T-shaped groove cutting edge (4-10), a plurality of spring shaft holes (4-7) are evenly arranged on the fixed top disc (4-6), a plurality of fixed tables (4-8) are evenly and fixedly connected at the lower end of the fixed top disc (4-6), and an inner circle cutting edge (4-9) of each stator is fixedly connected at the lower end of the corresponding fixed table (4-8).

4. A micro-electro-mechanical machining apparatus as claimed in claim 3, wherein: the cutting puller (5) comprises a puller disc (5-1), a plurality of spring shafts (5-2), a plurality of spring top seats (5-3) and a plurality of puller springs (5-4), wherein the puller disc (5-1) is fixedly connected to the lower ends of the spring shafts (5-2), the spring shafts (5-2) are slidably connected into the spring shaft holes (4-7) and the spring top seats (5-3), the spring top seats (5-3) are fixedly connected into the fixed top discs (4-6), and the puller springs (5-4) are sleeved in the spring shafts (5-2) and arranged between the spring top seats (5-3) and the fixed top discs (4-6).

5. A micro-electro-mechanical machining apparatus as claimed in claim 4, wherein: the inner circle cutting edge (4-9) of the stator is a circular edge with a right-angled outer wall and an inclined inner wall.

6. A micro-electro-mechanical machining apparatus as claimed in claim 5, wherein: the jacking disc (5-1) is arranged at the lower end of the inner circle cutting edge (4-9) of the stator; the stator inner circle cutting edges (4-9) are arranged at the lower ends of the plurality of T-shaped groove cutting edges (4-10).

7. A micro-electro-mechanical machining apparatus as claimed in claim 6, wherein: the side end of the fixed screw shaft (4-1) is connected with a thread matching adjusting screw which is meshed with the inner wall of the hinged propelling wheel (4-2).

8. A micro-electro-mechanical machining apparatus as claimed in claim 7, wherein: the height of the sliding pushing baffle (2-5) higher than the bearing plate (2-3) is the same as the thickness of the stator plate.