CN219611568U - Device for tightly supporting inner-attached magnetic type outer rotor magnetic shoe - Google Patents

Device for tightly supporting inner-attached magnetic type outer rotor magnetic shoe Download PDF

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Publication number
CN219611568U
CN219611568U CN202320069647.4U CN202320069647U CN219611568U CN 219611568 U CN219611568 U CN 219611568U CN 202320069647 U CN202320069647 U CN 202320069647U CN 219611568 U CN219611568 U CN 219611568U
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China
Prior art keywords
magnetic shoe
guide plate
hand
supporting
plate spring
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Inventor
武振宇
李忠泽
楼周侃
赵松文
谢轩
余桢慧
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Hangzhou Hehui Intelligent Equipment Co ltd
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Hangzhou Hehui Intelligent Equipment Co ltd
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02TCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
    • Y02T10/00Road transport of goods or passengers
    • Y02T10/60Other road transportation technologies with climate change mitigation effect
    • Y02T10/64Electric machine technologies in electromobility

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Abstract

The utility model discloses a device for tightly supporting an inner-pasting magnetic type outer rotor magnetic shoe. The side part of the magnetic shoe pasting mechanism is provided with a magnetic shoe expanding mechanism, the rotor assembly is arranged on the magnetic shoe pasting mechanism, and the magnetic shoe expanding mechanism drives the magnetic shoe pasting mechanism to work so as to realize the magnetic shoe expanding inside the magnetic shoe pasting mechanism; in the magnetic shoe pasting mechanism, a hand-supporting coaxial mounting flange and an annular rotating guide plate around the hand-supporting coaxial mounting flange are fixed on a mounting base; the magnetic shoe supporting hand is fixed on the top end surface of the coaxial mounting flange of the supporting hand, the periphery of the magnetic shoe supporting hand is provided with groove positions, each groove position is provided with a magnetic shoe plate spring, and the magnetic shoe is preloaded in the groove position and is adsorbed by the magnet; radial strip-shaped grooves are formed in the rotary guide plates, a rotatable displacement turntable is arranged between the rotary guide plates and the mounting base, spiral waist-shaped grooves are formed in the displacement turntable, and one side of the displacement turntable is hinged to the magnetic shoe expanding mechanism. The utility model has high degree of automation, improves the working efficiency, reduces the outflow probability of defective products, saves the labor cost, is stable and reliable, and is easy for later maintenance.

Description

Device for tightly supporting inner-attached magnetic type outer rotor magnetic shoe
Technical Field
The utility model relates to a rotor magnetic shoe assembling device, in particular to a device for tightly supporting an inner-pasting magnetic type outer rotor magnetic shoe.
Background
The existing mechanism is a semi-automatic magnetic shoe tensioning device. Including locating plate, straining device includes bottom plate, guide holder, locating base, latch segment, cylindric lock, elastic reset device and last mould, and locating base cover is located guide holder upper portion, and the guide holder upper end is equipped with outer cone portion, and the inside corresponding position of locating base is equipped with the second round hole, has seted up N square hole that is circumference equipartition on the lateral wall of second round hole upper end, inserts in the square hole and is equipped with the latch segment, can radially rectilinear movement with square hole formation and be connected, the latch segment inboard be equipped with outer cone portion matched with inner cone cambered surface, elastic reset device locates between locating base and the guide holder.
The upper die is driven to descend through the press, the upper die drives the workpiece to descend together with the positioning base, and the locking blocks are driven to simultaneously move downwards and outwards to tension the corresponding magnetic shoe.
The mechanism is a semi-automatic magnetic shoe tensioning mechanism, has lower efficiency in working, is easy to generate conditions such as abnormal neglected loading and the like, has longer manual processing time if the conditions occur, has no detection device, and has larger influence on subsequent procedures if the conditions such as abnormal neglected loading and the like are not found. And the damage to the mechanism is large, which is unfavorable for the later maintenance.
Disclosure of Invention
In order to solve the problems in the background technology, the utility model provides a full-automatic magnetic shoe tensioning mechanism. Through the design of optimizing the structure, the intensity and the life-span of each structure are precisely calculated, and a detection device is added. The working efficiency is improved, the failure rate of the machine is reduced, the condition of wrong assembly and neglected assembly is reduced, and the later maintenance is convenient.
The technical scheme adopted by the utility model is as follows:
the main structure of the device is a magnetic shoe pasting mechanism and a magnetic shoe expanding mechanism; the side part of the magnetic shoe mechanism is provided with a magnetic shoe expanding mechanism, the rotor assembly is arranged on the magnetic shoe mechanism, and the magnetic shoe expanding mechanism drives the magnetic shoe mechanism to work so as to realize the magnetic shoe expanding inside the magnetic shoe mechanism.
The magnetic shoe pasting mechanism comprises a mounting base, a magnet, a magnetic shoe pasting plate spring, a rotary guide plate, a magnetic shoe supporting hand, a turntable locating pin, a displacement turntable and a supporting hand coaxial mounting flange; the hand-supporting coaxial mounting flange is fixed at the center of the mounting base, and the annular rotary guide plate is fixedly mounted on the mounting base around the hand-supporting coaxial mounting flange through a rotary disc positioning pin and a supporting shaft sleeve at the peripheral edge; the magnetic shoe support hand is fixed on the top end surface of the support hand coaxial mounting flange, N groove positions for mounting the magnet tile plate springs are formed in the peripheral surface of the magnetic shoe support hand, a magnet, one magnet tile plate spring and one magnetic shoe of the rotor assembly are mounted in each groove position, and the magnetic shoe of the rotor assembly is pre-mounted in the groove positions and is adsorbed by the magnet;
the device comprises a rotating guide plate, a plurality of N radial strip-shaped grooves which are uniformly distributed along the circumference at intervals and used for the passing and guiding movement of the magnetic shoe plate springs, a rotatable displacement turntable which is arranged between the rotating guide plate and a mounting base, N spiral waist-shaped grooves which are uniformly distributed along the circumference at intervals and used for the passing and guiding rotation of the magnetic shoe plate springs, and a radial extension arm which is fixedly arranged on one side of the displacement turntable and hinged to a magnetic shoe stretching mechanism.
The rotary guide plate is positioned and installed through a rotary table locating pin installation base at the peripheral edge, a supporting shaft sleeve is sleeved outside the rotary table locating pin between the rotary guide plate and the installation base, and the upper end and the lower end of the supporting shaft sleeve are respectively connected with the bottom surface of the rotary guide plate and the top surface of the installation base and are used for supporting and installing the rotary guide plate.
In the groove position, the magnet tile plate spring is arranged in the middle, and magnets for magnetically adsorbing the magnet tiles of the rotor assembly are arranged on two sides of the magnet tile plate spring.
The magnetic shoe plate spring is L-shaped, one L-shaped end of the magnetic shoe plate spring is horizontally arranged at the bottom end, one L-shaped end of the magnetic shoe plate spring is vertically arranged at the top end, the top end of the magnetic shoe plate spring can be horizontally movably embedded in a groove of a magnetic shoe bracket, the top end of the magnetic shoe plate spring is provided with a magnetic shoe contact elastic spring structure used for being in contact with a rotor assembly on the radially outward side face, the bottom end of the magnetic shoe plate spring can be horizontally movably embedded in a radial strip-shaped groove of a rotating guide plate, the bottom end of the magnetic shoe plate spring is fixedly provided with a guide plate rotating shaft through a bolt, and the guide plate rotating shaft is hinged in a spiral waist-shaped groove of a displacement turntable through an oilless bushing.
The rotary guide plate is also fixedly provided with an annular guide plate cover plate, and the guide plate cover plate is used for preventing the bottom of the magnetic shoe plate spring from falling out of the radial strip-shaped groove of the rotary guide plate.
The inner periphery of the guide plate cover plate is also provided with a magnetic shoe holding flange seat, and N radial strip-shaped grooves which are uniformly distributed at intervals in the circumferential direction are formed in the same way as the rotary guide plate for the magnetic shoe holding flange seat to pass through and guide and move; meanwhile, an annular step for positioning the installation of the shell of the rotor assembly is arranged at the outer edge of the upper end surface of the magnetic shoe bracket flange seat.
The magnetic shoe support hand is unable to be rotatably installed on the top end face of the support hand coaxial installation flange through the first shell locating pin, and the shell of the rotor assembly is unable to be rotatably installed on the magnetic shoe support hand through the second shell locating pin.
The magnetic shoe stretching mechanism comprises an air cylinder, a rotating head, a limiting seat and a limiting bolt, wherein the air cylinder is fixedly arranged, and a cylinder rod of the air cylinder is connected with the magnetic shoe pasting mechanism through the rotating head; the front of the rotating head is also provided with a limiting seat and a limiting bolt for limiting movement, the limiting seat is fixedly arranged, the limiting bolt is arranged on the limiting seat through threads, and the limiting bolt and a cylinder rod of the cylinder are positioned on the same straight line.
And the magnetic shoe pasting mechanism and the rotating head are respectively provided with a stud hole, and the stud holes are respectively inserted with a stud.
Aiming at the problems that the magnetic shoe A2 to be installed is relatively fragile, the installation is not in place, the yield is low and the like, the existing rotor magnetic shoe is usually tightly supported, and the problems and the defects of uncontrollable installation pressing force, high failure rate, inconvenient maintenance and the like exist.
However, the structure skillfully realizes fine adjustment of motion by changing rotation into radial movement with small path change, and the problem that the magnetic shoe A2 is fragile and easy to break is also prevented by combining the plate spring, so that the problem that the magnetic shoe A2 is easy to break when being tightly supported is prevented, products are effectively protected, and the yield is remarkably improved.
The beneficial effects of the utility model are as follows:
the utility model has high degree of automation and improves the working efficiency. The rigidity strength of part parts is enhanced, so that the whole service life of the mechanism is prolonged. The detection device is added, the outflow probability of defective products is reduced, and the labor cost is saved.
The device has simple structure, stability and reliability and is easy for later maintenance.
Drawings
FIG. 1 is a schematic diagram of a magnetic shoe tensioning mechanism of the present utility model.
Fig. 2 is an exploded view of the magnetic shoe tensioning mechanism of the present utility model.
FIG. 3 is a schematic view of a rotor assembly of the present utility model.
Fig. 4 is a schematic view of the distracting mechanism of the present utility model.
Fig. 5 is a schematic diagram of a magnetic shoe mechanism according to the present utility model.
Fig. 6 is an exploded view of the magnetic shoe attachment mechanism of the present utility model.
Fig. 7 is a schematic illustration of the 8-piece magnetic shoe of the present utility model placed on a magnetic shoe attachment mechanism.
Fig. 8 is a schematic view of the positioning of the housing of the present utility model.
Fig. 9 is a schematic view of the rotary guide structure of the present utility model.
Fig. 10 is a schematic view of a rotary motion slot structure according to the present utility model.
FIG. 11 is a schematic view of the Z-directional positioning of the housing and magnetic shoe of the present utility model.
Fig. 12 is a diagram showing the conversion of the motion pattern according to the present utility model.
Fig. 13 is a schematic structural view of the leaf spring B3 of the present utility model.
Fig. 14 is a schematic cross-sectional view of a magnetic shoe mechanism of the present utility model.
FIG. 15 is a schematic partial cross-sectional view of a portion of a magnetic shoe mechanism according to the present utility model.
FIG. 16 is a second schematic partial cross-sectional view of a portion of a part of the magnetic shoe mechanism of the present utility model.
FIG. 17 is a partial schematic view of the mating relationship of the parts of the magnetic shoe mechanism of the present utility model.
FIG. 18 is a second partial schematic view of the mating relationship of parts of the magnetic shoe mechanism of the present utility model.
FIG. 19 is a 1/4 perspective cross-sectional view of the magnetic shoe mechanism of the present utility model.
In the drawing the view of the figure,
a0, a rotor assembly, A1, a shell, A2 and a magnetic shoe;
b0, a magnet tile attaching mechanism, B1, an installation base, B2, a magnet, B3, a magnet tile attaching plate spring, B4, a guide plate rotating shaft, B5, an oilless bushing, B6, a guide plate cover plate, B7, a rotating guide plate, B8, a magnet tile hand support, B9, a magnet tile hand support flange seat, B10, a turntable locating pin, B11, a locating sleeve, B12, a displacement turntable, B13, a handle, B14, a hand support coaxial installation flange, B15, a support shaft sleeve, B16, a first shell locating pin, B17 and a second shell locating pin;
c0, magnetic shoe struts mechanism, C1, cylinder fixing base, C2, cylinder, C3, rotating head, C4, pin, C5, spacing seat, C6, spacing bolt.
Detailed Description
The utility model will be described in further detail with reference to the accompanying drawings and specific examples.
As shown in fig. 1 and 2, the main structure of the device is a magnetic shoe pasting mechanism B0 and a magnetic shoe expanding mechanism C0; the rotor assembly A0 is an acting object of the device, and as shown in fig. 3, the rotor assembly A0 comprises a magnetic shoe A2 and a shell A1, and the magnetic shoe A2 is stretched out and tightly supported to the inner wall of the shell A1. The side part of the magnetic shoe pasting mechanism B0 is provided with a magnetic shoe expanding mechanism C0, the rotor assembly A0 is arranged on the magnetic shoe pasting mechanism B0, and the magnetic shoe expanding mechanism C0 drives the magnetic shoe pasting mechanism B0 to work so as to realize the magnetic shoe expanding inside the magnetic shoe pasting mechanism B0.
As shown in fig. 14 to 19, the magnetic shoe mechanism B0 comprises a mounting base B1, a magnet B2, a magnetic shoe plate spring B3, a rotary guide plate B7, a magnetic shoe hand-support B8, a rotary disc positioning pin B10, a displacement rotary disc B12 and a hand-support coaxial mounting flange B14;
the hand-supporting coaxial mounting flange B14 is fixed at the center of the mounting base B1, and the annular rotary guide plate B7 is fixedly mounted on the mounting base B1 around the hand-supporting coaxial mounting flange B14 through a rotary disc positioning pin B10 and a supporting shaft sleeve B15 at the peripheral edge; the rotary guide plate B7 is positioned around the hand-supporting coaxial mounting flange B14, and a gap is formed between the rotary guide plate B7 and the hand-supporting coaxial mounting flange B14, and the rotary guide plate B7 is not contacted or connected. The magnetic shoe supporting hand B8 is fixed on the top end surface of the supporting hand coaxial mounting flange B14, N groove positions for mounting the magnet tile plate spring B3 are formed in the peripheral surface of the magnetic shoe supporting hand B8, a magnet B2, a magnet tile plate spring B3 and a magnetic tile A2 of the rotor assembly A0 are mounted in each groove position, and the magnetic tile A2 of the rotor assembly A0 is pre-mounted in the groove positions and is adsorbed by the magnet B2;
n radial strip-shaped grooves which are uniformly distributed along the circumference and used for the passing and guiding movement of the magnetic shoe plate spring B3 are arranged on the rotating guide plate B7 along the circumference at intervals to serve as precise matching notches, the radial strip-shaped grooves are all arranged along the radial direction, a rotatable displacement rotary table B12 is arranged between the rotating guide plate B7 and the mounting base B1, N spiral waist-shaped grooves which are uniformly distributed along the circumference and used for the passing and guiding rotation of the magnetic shoe plate spring B3 are arranged on the displacement rotary table B12 along the circumference at intervals to serve as rotating motion notches, and as shown in fig. 10, the spiral waist-shaped grooves are arc-shaped sections along plane threads, and the spiral directions of the N spiral waist-shaped grooves are identical. A radial extension arm is fixedly arranged on one side of the displacement turntable B12, and extends out of a rotating head C3 hinged to the magnetic shoe expanding mechanism C0 from a position between the rotating guide plate B7 and the mounting base B1.
The rotary guide plate B7 is positioned and installed through the rotary plate locating pin B10 and the base B1 at the peripheral edge, the rotary plate locating pin B10 between the rotary guide plate B7 and the base B1 is sleeved with the supporting shaft sleeve B15, and the upper end and the lower end of the supporting shaft sleeve B15 are respectively connected with the bottom surface of the rotary guide plate B7 and the top surface of the base B1 and are used for supporting and installing the rotary guide plate B7.
A magnet tile plate spring B3 is arranged in a radial strip-shaped groove and a spiral waist-shaped groove, and N magnet tile plate springs B3 are arranged in total of N radial strip-shaped grooves and N spiral waist-shaped grooves.
In the groove position, a magnet tile plate spring B3 is arranged in the middle, and magnets B2 used for magnetically adsorbing a magnet tile A2 of the rotor assembly A0 are arranged on two sides of the magnet tile plate spring B3.
As shown in fig. 13, 17 and 18, the magnetic shoe plate spring B3 is L-shaped, one end of the L-shape of the magnetic shoe plate spring B3 is horizontally arranged as a bottom end, one end of the L-shape of the magnetic shoe plate spring B3 is vertically arranged as a top end, the top end of the magnetic shoe plate spring B3 passes through the magnetic shoe support flange seat B9 and can be horizontally movably embedded in the groove position of the magnetic shoe support handle B8, the top end of the magnetic shoe plate spring B3 is provided with a magnetic shoe A2 contact elastic spring structure for contacting with the rotor assembly A0 on the radially outward side surface, the bottom end of the magnetic shoe plate spring B3 can be horizontally movably embedded in a radial strip-shaped groove of the rotary guide plate B7, the bottom end of the magnetic shoe plate spring B3 is fixedly provided with a guide plate rotary shaft B4 through a bolt, the guide plate rotary shaft B4 is hinged in a spiral waist-shaped groove of the displacement rotary plate B12 through the oil-free bushing B5, and is driven to move by the displacement rotary plate B12.
As shown in fig. 14 and 6, an annular guide plate cover plate B6 is also fixedly arranged on the rotary guide plate B7, and the guide plate cover plate B6 is used for preventing the bottom of the magnetic shoe plate spring B3 from falling out of a radial strip-shaped groove of the rotary guide plate B7.
The inner periphery of the guide plate cover plate B6 is also provided with a magnetic shoe hand-supporting flange seat B9, and N radial strip-shaped grooves which are uniformly distributed at intervals in the circumferential direction are formed in the same way as the rotary guide plate B7 in the magnetic shoe hand-supporting flange seat B9 and are used for penetrating and guiding the magnetic shoe plate spring B3 to move; as shown in fig. 11, the outer edge of the upper end surface of the magnetic shoe holder flange seat B9 is provided with an annular step for positioning the installation of the housing A1 of the rotor assembly A0, and the housing A1 of the rotor assembly A0 is sleeved on the annular step of the magnetic shoe holder flange seat B9. The magnetic shoe holder flange seat B9 is not contacted with the magnetic shoe holder B8.
The magnetic shoe hand support B8 is non-rotatably mounted on the top end surface of the hand support coaxial mounting flange B14 by a first housing locating pin B16, and the housing A1 of the rotor assembly A0 is non-rotatably mounted on the magnetic shoe hand support B8 by a second housing locating pin B17. The shell A1 of the rotor assembly A0 is sleeved on the annular step of the magnetic shoe bracket flange seat B9, and a second shell locating pin B17 is inserted through pin holes on the shell A1 and the magnetic shoe bracket B8, so that the shell A1 is kept circumferentially located and fixed.
The two sides of the installation base B1 are also provided with handles B13 which are convenient to lift.
The mounting base B1 is also provided with a positioning sleeve B11 for being mounted on external equipment.
As shown in fig. 4, the magnetic shoe spreading mechanism C0 comprises a cylinder C2, a rotating head C3, a limiting seat C5 and a limiting bolt C6, wherein the cylinder C2 is fixedly installed through a cylinder fixing seat C1, and a cylinder rod of the cylinder C2 is connected with the magnetic shoe pasting mechanism B0 through the rotating head C3; the front of the rotating head C3 is also provided with a limiting seat C5 and a limiting bolt C6 for limiting the movement of the rotating head C3, the limiting seat C5 is fixedly installed, the limiting bolt C6 is installed on the limiting seat C5 through threads, and the limiting bolt C6 and a cylinder rod of the cylinder C2 are positioned on the same straight line and used for propping up the limiting position movement of the rotating head C3.
The radial extension arm and the rotating head C3 of the displacement turntable B12 of the magnetic shoe pasting mechanism B0 are respectively provided with a pin hole, and the pin holes on the radial extension arm and the rotating head C3 are respectively inserted with a pin C4, so that the radial extension arm of the displacement turntable B12 is hinged with the rotating head C3.
As shown in FIG. 1, the implementation includes that the hand-supporting coaxial mounting flange B14 is fixed on the B1 according to the characteristic of the central positioning cylinder, the displacement turntable B12 is sleeved into the largest outer circle of the hand-supporting coaxial mounting flange B14, and the displacement turntable B12 and the hand-supporting coaxial mounting flange B14 can be rotatably connected and can perform rotary motion around the hand-supporting coaxial mounting flange B14.
The oil-free bushing B5 is arranged in the rotary motion notch of the displacement turntable B12, and the oil-free bushing B5 is made of brass, so that friction can be reduced, and the hardness is low and the lubricity is good. The oilless bushing B5 is internally inserted with a guide plate rotating shaft B4, the guide plate rotating shaft B4 is fixedly arranged with the magnetic shoe plate spring B3, and the rotary guide plate B7 is fixed on the support shaft sleeve B15 according to the clamping groove position. As shown in fig. 16, the height of the supporting shaft sleeve B15 is 0.02mm to 0.04mm greater than the thickness of the displacement turntable B12, which ensures that the displacement turntable B12 is not pressed by the rotation guide plate B7 to be unable to rotate and can press the displacement turntable B12 to have no movement in the Z direction although between the rotation guide plate B7 and the mounting base B1.
As shown in fig. 9, the width of the clamping groove of the rotary guide plate B7 is in plane precise fit with the width of the magnetic shoe plate spring B3, the gap is between 0.02mm and 0.05mm, and the magnetic shoe plate spring B3 is restrained in the clamping groove of the rotary guide plate B7 to do linear motion only along the clamping groove and cannot deviate left and right. The guide plate cover plate B6 is fixed on the rotary guide plate B7, and the magnetic shoe plate spring B3 is pressed and cannot deviate and deflect up and down in the moving process.
The cylinder C2 is fixed on the cylinder fixing seat C1 through the rotating shaft at the tail part of the cylinder C2, and the cylinder C2 can rotate around the rotating shaft due to the action of the rotating shaft, so that the cylinder C2 is prevented from being blocked by radial force in the moving process. The rotating head C3 is connected with the displacement turntable B12 through the pin C4, so that the rotating head C3 and the displacement turntable B12 can rotate relatively, and the linear motion of the rotating head C3 is converted into the rotary motion of the displacement turntable B12.
The magnetic shoe plate spring B3 is made of 65Mn material, and the unique spring structure is obtained by calculating the pressure required by bonding between the magnetic shoe A2 and the shell A1, and the structure is shown in FIG. 13. Therefore, the magnetic shoe A2 and the shell A1 can be guaranteed to be subjected to expected pressure values in the attaching process, and the rigid body structure of the magnetic shoe A2 and the shell A1 cannot be damaged due to overlarge pressure values.
The specific operation process of the utility model is as follows:
as shown in FIG. 7, eight magnetic shoes A2 are respectively arranged in the groove positions of the magnetic shoe supporting hand B8 in advance, two sides of each groove position of the magnetic shoe supporting hand B8 are respectively provided with a magnet B2, and the magnets B2 provide magnetic attraction to the magnetic shoes A2 so as to prevent the A2 from toppling.
As shown in fig. 8, the housing A1 is positioned and placed on the magnetic shoe mechanism B0 by the first housing positioning pin B16 and the second housing positioning pin B17;
as shown in fig. 11, the Z-direction drop between the magnetic shoe A2 and the housing A1 is ensured by the step of the magnetic shoe holder flange B9, the housing A1 is located on the outer step of the magnetic shoe holder flange B9, the magnetic shoe A2 is located on the inner step of the magnetic shoe holder flange B9, and the difference in the height of the inner and outer steps of the magnetic shoe holder flange B9 is the Z-direction distance between the magnetic shoe A2 and the housing A1.
After assembly, as shown in fig. 5.
As shown in fig. 12, after the magnetic shoe A2 and the housing A1 are placed, the cylinder C2 extends to push the rotary head C3 to move forward, so as to drive the displacement turntable B12 to rotate around the supporting-hand coaxial mounting flange B14, and the guide-plate rotating shaft B4 is driven to move through the relationship between the rotating movement notch of the displacement turntable B12 and the guide-plate rotating shaft B4, so as to drive the magnetic shoe plate spring B3 to move, and since the magnetic shoe plate spring B3 is limited by the precisely matched notch of the rotating guide plate B7, the rotating movement is converted into the linear movement of the magnetic shoe plate spring B3, and then the magnetic shoe plate spring B3 can move radially outwards or inwards, and the linear movement of the magnetic shoe plate spring B3 is also ensured by the precisely matched notch of the rotating guide plate B7.
If the extending/retracting direction of the cylinder C2 and the spiral direction of the rotating movement notch of the displacement turntable B12 are adjusted and set, the magnetic shoe plate spring B3 can be driven to push the magnetic shoe A2 outwards so that the magnetic shoe A2 is clung to the inner wall of the shell A1.
After the bonding is completed, the cylinder C2 is retracted, and the magnetic shoe plate spring B3 is reset along the motion transmission path; finally, the rotor assembly A0 flows out of the device to finish the cycle, and the next cycle is started.

Claims (10)

1. The utility model provides a device with interior subsides magnetic type external rotor magnetic shoe support tightly which characterized in that:
the main structure of the device is a magnetic shoe pasting mechanism (B0) and a magnetic shoe expanding mechanism (C0); the side part of the magnetic shoe pasting mechanism (B0) is provided with a magnetic shoe stretching mechanism (C0), the rotor assembly (A0) is arranged on the magnetic shoe pasting mechanism (B0), and the magnetic shoe stretching mechanism (C0) drives the magnetic shoe pasting mechanism (B0) to work so as to realize the stretching of the magnetic shoe inside the magnetic shoe pasting mechanism (B0).
2. The device for tightening the inner magnet type outer rotor magnetic shoe according to claim 1, wherein: the magnetic shoe mechanism (B0) comprises a mounting base (B1), a magnet (B2), a magnetic shoe plate spring (B3), a rotary guide plate (B7), a magnetic shoe hand support (B8), a rotary disc locating pin (B10), a displacement rotary disc (B12) and a hand support coaxial mounting flange (B14); the hand-supporting coaxial mounting flange (B14) is fixed at the center of the mounting base (B1), and the annular rotary guide plate (B7) is fixedly mounted on the mounting base (B1) around the hand-supporting coaxial mounting flange (B14) through a rotary disc positioning pin (B10) and a supporting shaft sleeve (B15) at the peripheral edge; the magnetic shoe supporting hand (B8) is fixed on the top end face of the supporting hand coaxial mounting flange (B14), N groove positions for mounting the magnetic shoe plate springs (B3) are formed in the peripheral face of the magnetic shoe supporting hand (B8), a magnet (B2), the magnetic shoe plate springs (B3) and a magnetic shoe (A2) of the rotor assembly (A0) are mounted in each groove position, and the magnetic shoe (A2) of the rotor assembly (A0) is pre-mounted in the groove positions and is adsorbed by the magnet (B2);
the magnetic shoe plate spring rotating device comprises a rotating guide plate (B7), N radial strip-shaped grooves which are uniformly distributed along the circumference at intervals and used for enabling a magnetic shoe plate spring (B3) to penetrate through and guide to move, a rotatable displacement rotary table (B12) is arranged between the rotating guide plate (B7) and a mounting base (B1), N spiral strip-shaped grooves which are uniformly distributed along the circumference at intervals and used for enabling the magnetic shoe plate spring (B3) to penetrate through and guide to rotate are formed in the displacement rotary table (B12), and radial extending arms are fixedly arranged on one side of the displacement rotary table (B12) and hinged to a magnetic shoe supporting mechanism (C0).
3. The device for tightening the inner magnet type outer rotor magnetic shoe according to claim 2, wherein: the rotary guide plate (B7) is installed through the positioning of the rotary plate locating pin (B10) installation base (B1) at the peripheral edge, the rotary plate locating pin (B10) between the rotary guide plate (B7) and the installation base (B1) is sleeved with the support shaft sleeve (B15), and the upper end and the lower end of the support shaft sleeve (B15) are respectively connected with the bottom surface of the rotary guide plate (B7) and the top surface of the installation base (B1) and are used for supporting and installing the rotary guide plate (B7).
4. The device for tightening the inner magnet type outer rotor magnetic shoe according to claim 2, wherein: in the groove position, the magnet tile plate spring (B3) is arranged in the middle, and magnets (B2) used for magnetically adsorbing the magnet tiles (A2) of the rotor assembly (A0) are arranged on two sides of the magnet tile plate spring (B3).
5. The device for tightening the inner magnet type outer rotor magnetic shoe according to claim 2, wherein: the magnetic shoe plate spring (B3) is L-shaped, one L-shaped end of the magnetic shoe plate spring (B3) is horizontally arranged to be the bottom end, one L-shaped end of the magnetic shoe plate spring (B3) is vertically arranged to be the top end, the top end of the magnetic shoe plate spring (B3) can be horizontally movably embedded in a groove position of a magnetic shoe holder (B8), the top end of the magnetic shoe plate spring (B3) is provided with a magnetic shoe (A2) contact elastic spring structure used for contacting with a rotor assembly (A0) on the radially outward side surface, the bottom end of the magnetic shoe plate spring (B3) can be horizontally movably embedded in a radial strip groove of a rotary guide plate (B7), a guide plate rotating shaft (B4) is fixed at the bottom end of the magnetic shoe plate spring (B3) through a bolt, and the guide plate rotating shaft (B4) is hinged in a spiral waist groove of a displacement turntable (B12) through an oil-free bushing (B5).
6. The device for tightening the inner magnet type outer rotor magnetic shoe according to claim 2, wherein: the rotary guide plate (B7) is also fixedly provided with an annular guide plate cover plate (B6), and the guide plate cover plate (B6) is used for preventing the bottom of the magnetic shoe plate spring (B3) from falling out of a radial strip-shaped groove of the rotary guide plate (B7).
7. The device for tightening the inner magnet type outer rotor magnetic shoe according to claim 6, wherein: the inner periphery of the guide plate cover plate (B6) is also provided with a magnetic shoe support flange seat (B9), N radial strip-shaped grooves which are uniformly distributed at intervals in the circumferential direction are formed in the same way as the rotary guide plate (B7) in the magnetic shoe support flange seat (B9), and the N radial strip-shaped grooves are used for the passing through and guiding movement of the magnetic shoe plate spring (B3); meanwhile, an annular step for installing a shell (A1) for positioning the rotor assembly (A0) is arranged at the outer edge of the upper end surface of the magnetic shoe support flange seat (B9).
8. The device for tightening the inner magnet type outer rotor magnetic shoe according to claim 2, wherein: the magnetic shoe hand (B8) is non-rotatably mounted on the top end surface of the hand coaxial mounting flange (B14) through a first shell locating pin (B16), and the shell (A1) of the rotor assembly (A0) is non-rotatably mounted on the magnetic shoe hand (B8) through a second shell locating pin (B17).
9. A device for tightening magnetic shoes of an inner magnet type outer rotor according to claim 1 or 2, characterized in that: the magnetic shoe stretching mechanism (C0) comprises an air cylinder (C2), a rotating head (C3), a limiting seat (C5) and a limiting bolt (C6), wherein the air cylinder (C2) is fixedly installed, and a cylinder rod of the air cylinder (C2) is connected with the magnetic shoe pasting mechanism (B0) through the rotating head (C3); the front of the rotating head (C3) is also provided with a limiting seat (C5) and a limiting bolt (C6) for limiting movement, the limiting seat (C5) is fixedly installed, the limiting bolt (C6) is installed on the limiting seat (C5) through threads, and the limiting bolt (C6) and a cylinder rod of the cylinder (C2) are on the same straight line.
10. The device for tightening the inner magnet type outer rotor magnetic shoe according to claim 9, wherein: and the magnetic shoe pasting mechanism (B0) and the rotating head (C3) are respectively provided with a stud hole, and the stud holes are respectively inserted with a stud (C4).
CN202320069647.4U 2023-01-10 2023-01-10 Device for tightly supporting inner-attached magnetic type outer rotor magnetic shoe Active CN219611568U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202320069647.4U CN219611568U (en) 2023-01-10 2023-01-10 Device for tightly supporting inner-attached magnetic type outer rotor magnetic shoe

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202320069647.4U CN219611568U (en) 2023-01-10 2023-01-10 Device for tightly supporting inner-attached magnetic type outer rotor magnetic shoe

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CN219611568U true CN219611568U (en) 2023-08-29

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CN202320069647.4U Active CN219611568U (en) 2023-01-10 2023-01-10 Device for tightly supporting inner-attached magnetic type outer rotor magnetic shoe

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