CN215009983U - Rotating shaft feeding mechanism of motor rotor assembling machine - Google Patents

Abstract

The utility model discloses a pivot feed mechanism of electric motor rotor kludge, characterized by: the rotating shaft feeding mechanism comprises a storage bin, a lifting plate, a guide plate and a shaft guide lifting cylinder; the bottom wall of the storage bin is obliquely arranged, and an avoidance opening is formed in the position, corresponding to the lowest position, of the bottom wall of the storage bin; the lifting plate is matched on the avoidance opening, and the top surface of the lifting plate is obliquely arranged; the shaft guide-in lifting cylinder is located below the storage bin and is connected with the lifting plate to drive the lifting plate to move up and down, so that the rotating shaft at the lowest position is jacked up upwards, and the shaft guide-in groove is formed in the guide plate. The utility model discloses can be automatically with the leading-in iron core of pivot in, promote the convenience and the efficiency of equipment.

Description

Rotating shaft feeding mechanism of motor rotor assembling machine

Technical Field

The utility model relates to a pivot feed mechanism of motor rotor kludge.

Background

The motor rotor is a rotating part in the motor. At present, the structure of a rotor generally comprises an iron core, a rotating shaft inserted in the iron core, a snap spring clamped on the rotating shaft, a bearing sleeved on the rotating shaft, and the like. The motor rotor also needs to be magnetized, oiled and dedusted during the assembling process. In the prior art, the assembly and the operation of each part are completed by manual operation, so that the labor cost is high and the efficiency is low.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides a pivot feed mechanism of electric motor rotor kludge can promote the convenience and the efficiency of equipment in leading-in the iron core of pivot automatically.

In order to achieve the above purpose, the utility model provides a following technical scheme:

the utility model provides a pivot feed mechanism of electric motor rotor kludge which characterized by: the rotating shaft feeding mechanism comprises a storage bin, a lifting plate, a guide plate and a shaft guide lifting cylinder;

the bottom wall of the storage bin is obliquely arranged, and an avoidance opening is formed in the position, corresponding to the lowest position, of the bottom wall of the storage bin;

the lifting plate is matched on the avoidance opening, and the top surface of the lifting plate is obliquely arranged;

the shaft guide-in lifting cylinder is located below the storage bin and is connected with the lifting plate to drive the lifting plate to move up and down, so that the rotating shaft at the lowest position is jacked up upwards, and the shaft guide-in groove is formed in the guide plate.

Preferably, the face of lifter plate and the inner wall laminating of feed bin extreme lower position department.

Preferably, a baffle is arranged in the bin, the bottom surface of the baffle is isolated from the inner bottom wall of the bin and divides the interior of the bin into an upper bin and a discharge bin.

Preferably, the bottom surface of the baffle and the inner bottom wall of the bin are only provided with one rotating shaft to pass through.

Preferably, an adjusting plate is arranged in the storage bin, an adjusting rod is further connected to the adjusting plate, the adjusting rod is in circumferential rotatable axial limiting connection with the adjusting plate, and a rod body portion of the adjusting rod is in threaded fit with a nut fixed on the side wall of the storage bin.

The utility model has the advantages that: can be automatically with the leading-in iron core of pivot in, promote the convenience and the efficiency of equipment.

Drawings

Fig. 1 is a schematic view of a motor rotor assembling machine provided in this embodiment;

fig. 2 is a schematic view of a rotor handling robot according to the present embodiment;

FIG. 3 is a schematic view of a shaft guide apparatus provided in this embodiment;

fig. 4 is a schematic diagram of a storage bin provided in this embodiment;

fig. 5 is a schematic view of a shaft pressing device provided in this embodiment;

fig. 6 is a schematic view of a magnetizing apparatus provided in this embodiment;

fig. 7 is a schematic view of the snap spring press-fitting device provided in this embodiment;

fig. 8 is a schematic view of the rotor clamp spring positioning tool provided in this embodiment;

fig. 9 is a schematic view of a bearing press-fitting device provided in the present embodiment;

fig. 10 is another schematic view of the bearing press-fitting device provided in the present embodiment;

fig. 11 is a schematic view of an oiling device provided in the present embodiment;

fig. 12 is a schematic view of the dust removing device provided in this embodiment.

Detailed Description

The rotating shaft feeding mechanism of the motor rotor assembling machine of the present invention is further described with reference to fig. 1 to 12.

The utility model provides an electric motor rotor kludge which characterized by: the device comprises a machine table 100, a rotor carrying manipulator 3 arranged on the machine table 100, an iron core feeding device 1 sequentially arranged along the carrying line of the rotor carrying manipulator 3, a shaft guiding device 2 for inserting a rotating shaft into a through hole of the iron core, a shaft pressing device 4 for accurately pressing the position of the rotating shaft on the iron core, a magnetizing device 5 for magnetizing the iron core with the rotating shaft, a clamping and pressing device 6 for clamping and pressing a clamp spring on the left side and the right side of the iron core corresponding to a bearing, a bearing pressing device 7 for pressing and pressing the bearing on the rotating shaft, an oiling device 8 for coating lubricating oil on the circumferential surface of the bearing, a dust removal device 9 for removing dust on the circumferential surface of the rotor and a rotor discharging device 10 for discharging the assembled rotor.

The iron core feeding device 1 is a feeding conveying line on the existing market, a sensor is arranged on the feeding conveying line, and when the sensor senses the fed iron core, the carrying manipulator grabs the next station to operate.

Specifically, as shown in fig. 2, the rotor carrying manipulator 3 includes a cross beam 31, a plurality of groups of manipulators horizontally sliding-fitted on the cross beam, and a ball screw pair 32 simultaneously fitted with the plurality of groups of manipulators and driving the plurality of groups of manipulators to move synchronously, each group of manipulators includes a slide plate 33 horizontally sliding-fitted on the cross beam and fitted with the ball screw pair 32, a vertical carrying cylinder 34 vertically mounted on the slide plate 33, and a finger cylinder 35 mounted on the vertical carrying cylinder 34, and the finger cylinder 35 is used for clamping the rotor 200 to drive the rotor to move to a next assembly station.

As shown in fig. 1, the shaft guide-in device 2 includes an iron core positioning tool 24, a shaft guide-in pushing mechanism 22 located on one side of the iron core positioning tool 24 and pushing the rotating shaft to the iron core positioning tool 24, and a shaft guide-in positioning mechanism 23 located on the other side of the iron core positioning tool 24 and supporting the iron core.

Specifically, as shown in fig. 3 and 4, the iron core positioning tool 24 includes a base 241 and an arc groove 242 located on the top surface of the base 241 and used for placing and positioning the iron core. The shaft guiding and pushing mechanism 22 comprises a shaft guiding rodless cylinder 221 mounted on the machine table surface, a positioning seat 222 fixed on a sliding block of the shaft guiding rodless cylinder 221, a shaft guiding push rod 223 inserted on the positioning seat 222, and a rotating shaft groove 224 positioned on a pushing line of the shaft guiding push rod 223. The shaft guiding and positioning mechanism 23 includes a shaft guiding and positioning cylinder 231 located on the other side of the base 241 opposite to the shaft guiding and pushing mechanism 22, a positioning block 233 fitted on a slider of the shaft guiding and positioning cylinder 231, and a shaft guiding and positioning rod 232 inserted in front of the positioning block 233. Based on the above structure, store the pivot in the pivot groove 224, the axle is gone into no pole cylinder 221 and is driven the axle and is gone into the push rod 223 and promote the pivot orientation in the pivot groove 224 and move towards the iron core that is located the circular arc groove 242, and axle is gone into the positioning cylinder 231 and is driven axle and is led into the locating lever 232 and lean on the iron core simultaneously to this can be with leading-in the through-hole of iron core smoothly with the pivot. An avoiding hole into which the rotating shaft extends is formed at the end of the shaft guide positioning rod 232.

Further, the shaft guide device further comprises a rotating shaft feeding mechanism 21, and the rotating shaft feeding mechanism 21 comprises a storage bin 211, a lifting plate 215, a guide plate 217 and a shaft guide lifting cylinder 216. The bottom wall of the storage bin is obliquely arranged, and an avoidance opening is formed in the position, corresponding to the lowest position, of the bottom wall of the storage bin; the lifting plate 215 is matched on the avoidance opening, and the top surface of the lifting plate 215 is inclined 2151; the shaft guide lifting cylinder 216 is located below the stock bin 211 and is installed on the machine table, and is connected with the lifting plate 215 to drive the lifting plate 215 to move up and down, so as to jack up the rotating shaft at the lowest position upwards, and is guided into the rotating shaft groove 224 through the guide plate 217.

The plate surface of the lifting plate 215 is attached to the inner wall 2113 at the lowest position of the bin, so that after the lifting plate 215 jacks up the rotating shaft upwards, the jacked rotating shaft can automatically roll out of the bin through the inclined top surface of the lifting plate 215 and enter the rotating shaft groove 224 through the guide plate 217.

A barrier 212 is provided in the silo 211, the bottom surface of the barrier 212 is isolated from the inner bottom wall of the silo and only one rotating shaft passes through, and the interior of the silo 211 is divided into an upper silo 2111 and a discharge silo 2112 by the barrier 212. During the material loading, in the feed bin 2111 was put into to the material loading personnel, because the diapire of feed bin 211 is the tilting gearing, and goes out feed bin 2112 and be in low level department, consequently go up the interior pivot of feed bin 2111 and can roll into out feed bin 2112 automatically to be ejecting by lifter plate 215. Meanwhile, only one rotating shaft passes through the space between the baffle 212 and the bottom wall of the storage bin 211, so that the situation that the lifting plate 215 pushes two rotating shafts to discharge materials at the same time can be avoided.

An adjusting plate 213 is arranged in the stock bin 211, the adjusting plate 213 is perpendicular to the baffle 212, a guide opening for the baffle 212 to pass through is formed in the adjusting plate 213, an adjusting rod 214 is further connected to the adjusting plate 213, the adjusting rod 214 and the adjusting plate 213 are in circumferential rotatable axial limiting connection, and a rod body part of the adjusting rod is in threaded fit with a nut fixed on the side wall of the stock bin 211. After the adjusting rod 214 is rotated, the adjusting rod 214 is axially displaced to drive the adjusting plate 213 to move, so as to accommodate rotating shafts with different sizes.

As shown in fig. 5, the shaft press-fitting device 4 includes a rotor press-fitting positioning tool 42, a press-fitting pushing mechanism 41 located on one side of the rotor press-fitting positioning tool 42 and pushing the rotor shaft, and an iron core pushing mechanism 43 mounted on the shaft press-fitting pushing mechanism 41 and pushing the iron core to move relative to the shaft.

Specifically, the rotor press-fitting positioning tool 42 includes a sliding seat 422, a base 423, a limiting plate 425 and a positioning cylinder 424. The slide 422 is a sliding fit on the slide rail 101 on the table top. The base 423 is fixed to the slider 422, and a rotor groove 421 into which a rotor is fitted is formed on the top surface of the base 423. A limit plate 425 is fixed on the slider 422 and is located on an end of the rotor groove 421. The positioning cylinder 424 is installed on the machine 100 to pull the slide 422 to a desired position. The shaft press-fitting pushing mechanism 41 comprises a press-fitting sliding seat 411, a ball screw pair 435 and a positioning seat 413. The press-fitting sliding seat 411 is in sliding fit with the sliding rail 101, and the ball screw pair 435 is arranged between the machine table and the press-fitting sliding seat 411 to drive the press-fitting sliding seat 411 to move towards or back to the base 423; a press head 412 is provided on the press-fitting slider 411. The positioning seat 413 is located on a side of the base 423 facing away from the press-fitting slider 411, and has a positioning block 414. The iron core pushing mechanism 43 comprises a stroke readable cylinder 431 and a press fitting sleeve 432. The stroke readable cylinder 431 is installed on the press-fitting sliding seat 411, and a piston rod of the stroke readable cylinder 431 is connected with a press-fitting sleeve 432, and meanwhile, the press-fitting sleeve 432 is in sliding fit with the press head 412. During specific work, a rotor needing to be pressed with the rotating shaft is placed in the rotor groove 421; the positioning cylinder 424 pulls the sliding seat 422 to move towards the positioning seat 413, so that the rotating shaft of the rotor abuts against the positioning block 414 on the positioning seat 413; the ball screw pair 435 drives the press-fitting sliding seat 411 to move towards the rotor, so that one end of the rotating shaft, which is opposite to the positioning block 414, passes through the press-fitting sleeve 432 and abuts against the press head 412; the stroke readable cylinder 431 drives the press-fitting sleeve 432 to push the iron core of the rotor so as to push the iron core to move, so that the iron core is pushed to a required position, and therefore accurate installation of the rotating shaft on the iron core is achieved. After press fitting is completed, the ball screw pair 435 drives the press fitting base 423 to reset, meanwhile, the stroke readable cylinder 431 drives the press fitting sleeve 432 to move back, and the positioning cylinder 424 drives the sliding seat to move, so that the sliding seat moves to the position right below the manipulator for grabbing.

As shown in fig. 6, the magnetizing device 5 includes a rotor magnetizing and positioning tool 54, a magnetizing coil 52 located on one side of the rotor magnetizing and positioning tool 54, and a rotor magnetizing and transferring mechanism capable of clamping the rotor on the rotor magnetizing and positioning tool 54 and driving the rotor to enter and exit from a magnetizing hole of the magnetizing coil 52. The rotor magnetizing and positioning tool 54 includes a base 541, and the base 541 has an arc groove 542 for placing the rotor therein. The rotor magnetizing and transferring mechanism comprises a left clamping assembly 53 and a right clamping assembly 51, wherein the left clamping assembly 53 comprises a sliding seat 534 matched with the upper surface of the machine platform in a sliding way, a ball screw pair 531 driving the sliding seat 534 to move towards or back to the base 541, and a magnetizing and positioning pipe 532 arranged on the sliding seat 534. The right clamping assembly 51 comprises a sliding base 514 slidably fitted on the sliding rail 102 on the surface of the machine table, a ball screw pair 513 mounted between the machine table and the sliding base and driving the sliding base 514 to move towards or away from the base 541, and a magnetizing positioning shaft 511 mounted on the sliding base 514. When magnetizing, the two ball screw pairs 531/513 drive the two slide carriages 534/514 to move in opposite directions, so that the magnetizing positioning tube 511 and the magnetizing positioning shaft 532 are pressed against the two ends of the rotating shaft on the arc groove 542, the two ball screw pairs 531/513 rotate synchronously to drive the two slide carriages 534/514 to move in the same direction, and accordingly, the clamped rotor is driven to enter the magnetizing hole of the magnetizing coil 52. After the magnetizing is completed, the two ball screw pairs 531/513 rotate reversely to drive the two slide seats 534/514 to move, so that the magnetized rotor moves out of the magnetizing hole and is placed on the arc groove 542 again. The two ball screw pairs 531/513 move reversely, so that the magnetizing positioning tube 532 and the magnetizing positioning shaft 511 move back to release the rotor, and the rotor is grabbed by the manipulator and conveyed to the next station.

As shown in fig. 7 and 8, the snap spring press-fitting device 6 includes a rotor snap spring positioning tool 61, a snap spring feeding mechanism 62, and a snap spring snapping mechanism 63 for snapping the snap spring positioned at the discharge port of the snap spring feeding mechanism 62 onto the rotor 210 positioned at the rotor snap spring positioning tool 61. The rotor clamp spring positioning tool 61 comprises a sliding seat 613 slidably fitted on the slide rail 103 of the machine table surface, a ball screw pair 611 arranged between the sliding seat 613 and the machine table surface, and a base 612 installed on the sliding seat 613, wherein an arc groove for placing an iron core of a rotor is formed in the top surface of the base 612, positioning plates 6121 are arranged at two ends of the sliding seat 613, which correspond to the arc groove, and a positioning groove for placing a rotating shaft of the rotor 210 is formed in the positioning plates 6121. The clamp spring feeding mechanism 62 is a clamp spring feeding rail extending downward from the bottom, and the upper end and the lower end of the clamp spring feeding rail are not horizontally arranged so as to facilitate feeding and discharging of the clamp spring. The snap spring clamping mechanism 63 comprises a frame body 631 installed on a machine table, a sliding plate 632 installed on the frame body 631, a horizontal cylinder 633 installed between the frame body 631 and the sliding plate 632 and driving the sliding plate 632 to slide on the frame body 631, a vertical cylinder 634 vertically installed on the sliding plate 632, a clamping block 635 installed on a piston rod of the vertical cylinder 634 and provided with a clamping opening 6351 at the lower end, a limiting block 636 installed on the machine table top and located at the discharge end of the snap spring feeding rail, a supporting plate 637 vertically and slidably fitted on the limiting block 636, and a lifting driving cylinder 638 installed on the limiting block 636 and connected with the supporting plate 637 to drive the supporting plate 637 to move up and down. When the snap spring press-fitting device 6 works specifically, the manipulator places the rotor 210 in the arc groove of the base 612, and the ball screw pair 611 drives the sliding seat 613 and the base 612 to move towards the frame body 631; the horizontal cylinder 633 drives the sliding plate 632 and the clamping block 635 to move towards the discharge end of the clamp spring feeding track, so that the bayonet 6351 of the clamping block 635 is positioned right above the clamp spring 300 at the discharge end of the clamp spring feeding track, meanwhile, the lifting driving cylinder 638 drives the supporting plate 637 to move upwards to support the clamp spring, and the vertical cylinder 634 drives the clamping block 635 to move downwards, so that the clamp spring 300 at the discharge end of the clamp spring feeding track is clamped into the bayonet 6351; the vertical cylinder 634 drives the clamping block and the clamp spring 300 to move upwards; the horizontal cylinder 633 drives the sliding plate 632 and the fixture block 635 to move, so that the fixture block 635 moves to a position right above a position where the rotor 210 needs to be clamped with the clamp spring; the vertical cylinder 634 drives the clamping block 635 to press downwards, the clamp spring is clamped on a rotating shaft of the rotor, the vertical cylinder 634 drives the clamping block 635 to move upwards, the bayonet 6351 is separated from the clamp spring, and therefore the clamp spring is clamped on the rotor. In this embodiment, two clamp springs need to be clamped on the rotating shaft rod bodies located at two sides of the iron core, the two clamp springs are clamped, and the position where the rotor is driven by the ball screw pair 611 and the clamp springs need to be clamped corresponds to the bayonet 6351. After the clamping is completed, the ball screw assembly 611 drives the rotor to move to the original station, namely, under the manipulator, so that the rotor carrying manipulator can grab and transfer the rotor to the next process.

As shown in fig. 1, 9 and 10, the bearing press-fitting device 7 includes a bearing press-fitting rotor positioning tool 73, two bearing feeding mechanisms 71/72 located at two sides of the bearing press-fitting rotor positioning tool 73, and a bearing press-fitting mechanism 74 for press-fitting the bearing at the discharge position of the two bearing feeding mechanisms 71/72 onto the rotor. The bearing press-fitting rotor positioning tool 73 comprises a sliding seat 731 which is in sliding fit with the slide rail 104 on the machine table top, a base 732 which is fixed on the sliding seat 731 and has a rotor groove on the top surface, and a limiting plate 733 which is installed on the sliding seat 731 and is located at two ends of the rotor groove. The bearing press-in mechanism 74 includes a press-in slide 741 slidably engaged with the slide rail 104, a ball screw pair 744 disposed between the press-in slide 741 and the machine and driving the press-in slide 741 to move toward or away from the slide 731, and a first bearing slot 742 is disposed at an end of the press-in slide 741 facing the base 732; the bearing press-fitting mechanism 74 further includes a fixing base 743 provided on a side of the base 732 opposite to the press-fitting base 732, and the fixing base 743 has a second bearing groove 745. Both bearing feeding mechanisms 71/72 are vibrating disks as shown in fig. 1, and both vibrating disks feed into the first bearing groove 742 and the second bearing groove 745 through their own feed channels 711/721. During specific work, a rotor needing to be pressed with a bearing is placed in a rotor groove of the base 732, and the rotating shaft is limited through a clamp spring of the body and a V-shaped groove in a limiting plate; the ball screw pair 744 drives the first bearing groove of the press-in slide 741 to move to the corresponding channel discharge port of the vibrating disk 711, and the two vibrating disks respectively provide bearings for the first bearing groove 742 and the second bearing groove 745. The ball screw pair 744 drives the press-in slide 741 provided with a bearing to move towards the rotor on the base 732, and the bearing in the first bearing groove 742 corresponds to the rotating shaft of the rotor and is sleeved on the rotating shaft; after the bearings are mounted on the rotor, the press-in slide 741 drives the slide 731 to move together toward the fixing seat 743, so as to press-fit the bearings located in the second bearing slots 745 of the fixing seat 743 onto the other end of the rotor, thereby achieving the press-fitting of the two bearings onto the two ends of the rotor.

The bottom walls of the first bearing groove 742 and the second bearing groove 745 are provided with rotor avoiding grooves, when the bearing in the first bearing groove 742 or the second bearing groove 745 is sleeved on the rotor, the bearing is positioned in the bearing groove, the rotor extends into the rotor avoiding grooves, the depth of the rotor avoiding grooves is the distance between the bearing and the corresponding end part, and therefore the position accuracy of the bearing in press mounting on the rotor is guaranteed.

A pull rod 75 is arranged between the press-in sliding seat 741 and the sliding seat 731, one end of the pull rod is fixed on the press-in sliding seat 741, the other end of the pull rod is in sliding fit with the guide plate 76 of the sliding seat 731, and meanwhile, the other end of the pull rod is provided with a limit block. After the bearing is pressed in place, the ball screw pair 744 drives the pressing-in sliding seat 741 to move back to the base 732, after the bearing is moved to a certain distance, the limiting block abuts against the guide plate to pull the sliding seat 731 to move together, after the sliding seat 731 touches a stroke to open, the ball screw pair 744 stops working and resets in place at the same time, and the next bearing pressing-in process can be carried out.

As shown in fig. 11, the oiling device 8 includes a bearing oiling positioning tool 82, an oil storage mechanism 83, an oiling wheel mechanism 84 rotating through the oil storage mechanism 83, and an oiling conveying mechanism 81 for installing the bearing oiling positioning tool 82 and driving the bearing oiling positioning tool 82 to move toward the oiling wheel mechanism 84. The oiling conveying mechanism 81 comprises an oiling sliding plate 812 and a transverse cylinder 811, the oiling sliding plate 812 is horizontally matched with the sliding rail 105 in the machine table in a sliding mode, and the transverse cylinder 811 is connected with the oiling sliding plate 812 and drives the oiling sliding plate 812 to horizontally move on the sliding rail 105. The bearing oiling positioning tool comprises a vertical cylinder 821 installed on an oiling sliding plate 812, and a positioning pipe 822 installed on a piston rod 8211 of the vertical cylinder 821 and in a vertical state. The oil storage mechanism 83 includes a frame body 831 mounted on the machine base and two oil storage chambers 833/832 provided on the frame body 831 and distributed vertically. The oiling wheel mechanism 84 includes an oiling wheel 843/841 and a motor 844/842, the motor 844/842 being mounted on the frame 831 and connected to the oiling wheel 843/841 to rotate the oiling wheel 843/841. The oiling wheel 843/841 fits over an opening in the side of oil reservoir chamber 833/832, i.e., half of the oiling wheel is inside oil reservoir chamber 833/832 and half is outside oil reservoir chamber 833/832. During the oiling, the rotor 230 that will need the oiling is carried to the top of registration arm 822 through the manipulator to rotate the rotor 90 degrees, it should be noted that, the manipulator that corresponds with the oiling station has 90 degrees upset functions, in order to overturn horizontal rotor for vertical rotor. The vertical cylinder 821 drives the positioning tube 822 to ascend, so that the rotating shaft of the rotor is inserted into the positioning tube 822, and meanwhile, two bearings of the rotor are located outside the positioning tube 822. The transverse cylinder 811 drives the positioning tube 822 and the rotor to move towards the oil coating wheel, so that the oil coating surface of the oil coating wheel is attached to the bearing, and the oil coating operation of the two bearings is realized.

As shown in fig. 12, the dust removing device 9 is disposed on the discharging device 10 and includes a rubber feeding roller 91, a rubber collecting roller 92, and an ejecting mechanism 93 for ejecting a rubber belt between the rubber feeding roller 91 and the rubber collecting roller 92 to a position where the rotor moves along with the bearing oiling positioning tool 82. During specific work, the adhesive tape is sleeved on the adhesive tape sending roller 91, the starting end of the adhesive tape is wound on the adhesive collecting roller 92, and the adhesive collecting roller 92 is connected with a motor to drive the adhesive collecting roller 92 to rotate, so that the adhesive tape on the adhesive tape sending roller 91 is wound on the adhesive collecting roller 92 gradually. The ejecting mechanism 93 comprises an air cylinder 931 and a pin shaft 932, the air cylinder 931 ejects the adhesive tape between the rubber feeding roller 91 and the rubber collecting roller 92 to the moving line of the rotor 230 through the pin shaft 932, therefore, when the rotor 230 moves along with the positioning pipe 822, the iron core of the rotor contacts with the bonding surface of the adhesive tape, and therefore the ash layer on the iron core can be adhered and removed by the adhesive tape.

The discharging mechanism comprises a frame body and two conveyor belts 101/102 arranged on the frame body, and the two conveyor belts 101/102 are arranged in an isolated mode. The transverse cylinder 811 conveys the positioning pipe 822 between the two conveyor belts 101/102, and the vertical cylinder 821 moves downwards, so that the positioning pipe 822 is separated from the rotor 230, and simultaneously, the iron core of the rotor 230 is supported on the two conveyor belts 101/102, and the discharge after the rotor is assembled is realized.

It should be noted that, in each of the above operation processes, an automatic operation is realized by the sensing of the sensor.

Unless otherwise specified, in the present invention, if the terms "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential" and the like indicate an orientation or positional relationship based on the orientation or positional relationship shown in the drawings, it is only for convenience of describing the present invention and simplifying the description, rather than to indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, therefore, the terms describing orientation or positional relationship in the present invention are used for illustrative purposes only, and should not be construed as limiting the present patent, specific meanings of the above terms can be understood by those of ordinary skill in the art in light of the specific circumstances in conjunction with the accompanying drawings.

Unless expressly stated or limited otherwise, the terms "disposed," "connected," and "connected" are used broadly and encompass both fixed and removable connections, or integral connections; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

It is above only the utility model discloses a preferred embodiment, the utility model discloses a scope of protection does not only confine above-mentioned embodiment, the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (5)

1. The utility model provides a pivot feed mechanism of electric motor rotor kludge which characterized by: the rotating shaft feeding mechanism comprises a storage bin, a lifting plate, a guide plate and a shaft guide lifting cylinder;

the bottom wall of the storage bin is obliquely arranged, and an avoidance opening is formed in the position, corresponding to the lowest position, of the bottom wall of the storage bin;

the lifting plate is matched on the avoidance opening, and the top surface of the lifting plate is obliquely arranged;

the shaft guide-in lifting cylinder is located below the storage bin and is connected with the lifting plate to drive the lifting plate to move up and down, so that the rotating shaft at the lowest position is jacked up upwards, and the shaft guide-in groove is formed in the guide plate.

2. The rotating shaft feeding mechanism of the motor rotor assembling machine according to claim 1, wherein: the face of lifter plate and the inner wall laminating of feed bin extreme lower position department.

3. The rotating shaft feeding mechanism of the motor rotor assembling machine according to claim 1, wherein: the feed bin is internally provided with a baffle, the bottom surface of the baffle is isolated from the inner bottom wall of the feed bin and divides the interior of the feed bin into an upper feed bin and a discharge bin.

4. The rotating shaft feeding mechanism of the motor rotor assembling machine according to claim 3, wherein: the bottom surface of the baffle and the inner bottom wall of the storage bin are only used for one rotating shaft to pass through.

5. The rotating shaft feeding mechanism of the motor rotor assembling machine according to claim 1, wherein: the adjusting plate is arranged in the storage bin, the adjusting rod is further connected onto the adjusting plate, the adjusting rod is in circumferential rotatable axial limiting connection with the adjusting plate, and the rod body part of the adjusting rod is in threaded fit with a nut fixed on the side wall of the storage bin.

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