CN212102936U - High-frequency quenching device for motor shaft - Google Patents

Abstract

The utility model belongs to the technical field of machining of mechanical parts, in particular to a high-frequency quenching device of a motor shaft, which comprises a movable quenching mechanism, rotatory clamping mechanism and feed mechanism, remove quenching mechanism includes first motor, fixed mounting has the lead screw on the output shaft of first motor, the spiro union has the movable block on the lead screw, fixed mounting has quenching coil on the movable block, the hydraulic stem and the sliding block fixed connection of second pneumatic cylinder, the sliding block is located the U-shaped support, L shape spout has been seted up to U-shaped support side, L shape spout includes vertical groove and transverse groove, the slope is led to the groove has been seted up to the sliding block side, lift the part and include the slide bar, two recesses have been seted up to the slide bar outer wall, the recess corresponding part of slide bar wears to establish in the slope leads to the inslot, each fixed mounting of L shape spout is passed at the slide bar both ends has a bracing piece, the bracing piece free. The purpose is as follows: solves the problems of low quenching quality, large workload and high labor cost caused by the structural defects of the existing quenching device.

Description

High-frequency quenching device for motor shaft

Technical Field

The utility model belongs to the technical field of machine part processing, concretely relates to motor shaft high frequency guenching unit.

Background

At present, the motor shaft needs to be quenched in the production process, and the quenching is manual operation at present, namely: the quenching operation is completed by a worker moving with the workpiece, and the quenching operation mode mainly has the following defects:

1. the influence of human factors is large, the quenching time is uncontrollable, the quenching quality is difficult to ensure, waste products are easy to appear, and the raw material cost of enterprises is increased;

2. the manual operation is troublesome, the workload is large, and the fatigue is easy to occur;

3. when the production capacity is large, a plurality of workers are required to work together, and the labor cost of enterprises is increased.

SUMMERY OF THE UTILITY MODEL

The utility model aims at: aims to provide a high-frequency quenching device for a motor shaft, which is used for solving the problems of low quenching quality, large workload and high labor cost caused by the structural defects of the existing quenching device.

In order to realize the technical purpose, the utility model discloses a technical scheme as follows:

a high-frequency quenching device for a motor shaft comprises a movable quenching mechanism, a rotary clamping mechanism and a feeding mechanism, wherein the movable quenching mechanism comprises a first motor, a lead screw is fixedly installed on an output shaft of the first motor, a moving block is screwed on the lead screw, a quenching coil is fixedly installed on the moving block, a water spray pipe is installed on the outer side of the quenching coil by the moving block, the rotary clamping mechanism comprises a second motor and a first hydraulic cylinder, a first clamping rod is rotatably installed on an output shaft of the second motor, a second clamping rod is rotatably installed on a hydraulic rod of the first hydraulic cylinder, the axial lead of the quenching coil, the axial lead of the first clamping rod and the axial lead of the second clamping rod are coincided, the feeding mechanism comprises a second hydraulic cylinder, a U-shaped support, a sliding block and a lifting part, and the second hydraulic cylinder is fixedly connected with the U-shaped support, the hydraulic stem and the sliding block fixed connection of second pneumatic cylinder, the sliding block is located the U-shaped support, L shape spout has been seted up to U-shaped support side, L shape spout includes vertical groove and transverse groove, vertical groove and transverse groove communicate with each other, the slope is seted up to the sliding block side and is led to the groove, it includes slide bar and V-arrangement supporting shoe to lift the part, two recesses have been seted up to the slide bar outer wall, the recess corresponding part of slide bar wears to establish in the groove that inclines, the slide bar both ends pass corresponding L shape spout respectively, and respectively fixed mounting has a bracing piece in the outside of L shape spout, the free end at the bracing piece is installed to the V-arrangement supporting shoe.

Further, the moving blocks are respectively provided with a water spray pipe at two opposite sides of the quenching coil. The two water spray pipes are separately controlled, when the quenching coil moves leftwards, the water spray pipe on the right side sprays water, and vice versa. Due to the structural design, after one motor shaft is quenched, the first motor does not need to be controlled to rotate reversely, the moving block is reset, the moving block directly moves reversely, the next motor shaft is quenched, and the quenching efficiency is improved.

Further inject, first clamp rod and second clamp rod are ceramic rod, the first metal pole of second clamp rod one end fixedly connected with is kept away from to first clamp rod, fixed mounting has first tapered roller bearing on the first metal pole, rotatory clamping mechanism still includes the base, second motor fixed mounting is on the base, still fixed mounting has first bearing frame on the base, first metal pole rotates through first tapered roller bearing and installs on first bearing frame, the output shaft and the first metal pole transmission of second motor are connected. Due to the structural design, when the motor shaft is clamped through the first clamping rod and the second clamping rod, the first clamping rod and the second clamping rod are positioned in the stroke range of the quenching coil through the ceramic rod, so that the problem of deformation caused by repeated heating of the first clamping rod and the second clamping rod by the quenching coil is avoided; the first metal rod is supported and fixed through the first tapered roller bearing, and meanwhile, the output shaft of the second motor is in transmission connection with the first metal rod, so that axial thrust can be avoided from being caused to the output shaft of the second motor when the second clamping rod drives the motor shaft to push and press leftwards, and the second motor is damaged.

Further inject, first tight pole one end fixedly connected with second metal pole of clamp is kept away from to the second tight pole of clamp, fixed mounting has second tapered roller bearing on the second metal pole, rotary clamping mechanism still includes the shape mount pad of falling C, first pneumatic cylinder is installed on the shape mount pad of falling C, first pneumatic cylinder is connected with the second bearing seat, the second metal pole rotates through second tapered roller bearing and installs on the second bearing seat, the dovetail has transversely been seted up to the shape mount pad inner wall of falling C, second bearing seat outer wall fixed mounting has the dovetail, the dovetail is worn to establish in the dovetail. Through the structural design, the second tapered roller bearing, the dovetail block and the dovetail groove are matched with each other, so that the hydraulic rod of the first hydraulic cylinder can be prevented from rotating along with the motor shaft.

Further inject, first pneumatic cylinder is close to the fixed ejector pad that is equipped with of second bearing frame one end, ejector pad and second bearing frame sliding connection, install the spring between ejector pad and the second bearing frame, still fixed mounting has the button on the ejector pad, button electric connection has control module, control module and first motor, second motor, first pneumatic cylinder and second pneumatic cylinder electric connection. When the quenching device is used, the first hydraulic cylinder is started, the hydraulic rod of the first hydraulic rod extends out to drive the second clamping rod to move leftwards until the motor shaft is driven to abut against the first clamping rod, the hydraulic rod of the first hydraulic rod continues to extend out to overcome the pressure of the spring, so that the button is pressed by the second bearing seat, after the button is pressed, a signal is sent to the control module, at the moment, the hydraulic rod of the second hydraulic cylinder is controlled to retract, the V-shaped supporting block vertically moves downwards firstly, and the motion track of the quenching coil is made; after the second hydraulic cylinder moves down and targets in place, the first motor and the second motor are controlled to start rotating through the control module, the hydraulic rod of the first hydraulic rod is controlled to stop extending out, the position is kept, the motor shaft starts to be heated, and due to the structural design, the degree of automation is higher, and the operation is more convenient.

Further, the V-shaped supporting block is detachably connected with the supporting rod. By the structural design, different V-shaped supporting blocks can be replaced according to motor shafts with different diameters, so that the axial lead of the motor shaft placed on the V-shaped supporting blocks is coincided with the axial leads of the first clamping rod and the second clamping rod.

Further inject, the bracing piece free end is fixed and is equipped with the diaphragm, evenly set up a plurality of shape of falling T recesses on the diaphragm, V-arrangement supporting shoe integrated into one piece has the shape of falling T fixture block, the shape of falling T fixture block card is established in the shape of falling T recess, V-arrangement supporting shoe still integrated into one piece has the dog in the shape of falling T fixture block top. Due to the structural design, the V-shaped supporting block and the supporting rod are mutually clamped with the inverted T-shaped groove through the inverted T-shaped clamping block to complete detachable connection, the structure is simple, the replacement is convenient, and the stop block plays a limiting role in the detachable connection; the reverse T-shaped grooves are multiple, the positions of the V-shaped supporting blocks on the supporting rods can be adjusted according to different positions of the step platforms on the motor shaft, and the situation that the stepped motor shaft cannot be pushed by the second clamping rod after being placed on the V-shaped supporting blocks is avoided.

Further defined, the free ends of the first and second clamping bars are conical. Such structural design, when the motor shaft that all offers the blind hole on the axis to both ends quenches, the cooperation of accessible cone end and blind hole adjusts the axial lead of motor shaft to the axial lead coincidence with first clamp lever and second clamp lever automatically, when quenching to the motor shaft that the diametral dimension differs little, need not to change new V-arrangement supporting shoe, reduces the manufacturing of the frock of V-arrangement supporting shoe, and it is more convenient to use.

Adopt above-mentioned technical scheme's utility model, have following advantage:

1. the quenching speed of the utility model is completely controlled by the rotating speed of the first motor, the speed is uniform and controllable, and the quenching quality can be effectively improved;

2. the operation is simple, the workload of workers is reduced, and meanwhile, the operation can be completed by only one worker, so that the labor cost is reduced;

3. through the two-section displacement of the lifting part, when the quenching coil moves vertically, the motion trail of the quenching coil is avoided, and meanwhile, the motor shaft clamped by the first clamping rod and the second clamping rod is not interfered, so that the problem of shaft axis deviation caused by interference after the motor shaft is clamped is avoided; the transverse displacement can enable the lifting part to avoid the falling track of the motor shaft, and the falling motor shaft is prevented from impacting the feeding machine.

Drawings

The present invention can be further illustrated by the non-limiting examples given in the accompanying drawings;

FIG. 1 is a first schematic structural view of an embodiment of a high-frequency quenching device for a motor shaft according to the present invention;

FIG. 2 is a first schematic structural diagram of a feeding mechanism in an embodiment of the high-frequency quenching device for the motor shaft of the present invention;

FIG. 3 is a second schematic structural view of a feeding mechanism in an embodiment of the high-frequency quenching device for the motor shaft of the present invention;

FIG. 4 is a third schematic structural view of a feeding mechanism in an embodiment of the high-frequency quenching device for the motor shaft of the present invention;

FIG. 5 is a schematic structural view of a lift member in an embodiment of a high-frequency quenching apparatus for a motor shaft according to the present invention;

FIG. 6 is a schematic structural view of a V-shaped support block in an embodiment of the high-frequency quenching device for a motor shaft of the present invention;

FIG. 7 is a schematic structural view of a motor shaft high-frequency quenching apparatus according to an embodiment of the present invention;

FIG. 8 is an enlarged view of the structure at A in FIG. 7;

FIG. 9 is an enlarged view of the structure at B in FIG. 7;

FIG. 10 is a schematic structural diagram II of an embodiment of the high-frequency quenching device for the motor shaft of the present invention;

FIG. 11 is an enlarged view of the structure of FIG. 10 at C;

FIG. 12 is a third schematic structural view of an embodiment of the high-frequency quenching device for a motor shaft of the present invention;

FIG. 13 is a fourth schematic structural view of an embodiment of the high-frequency quenching device for a motor shaft of the present invention;

the main element symbols are as follows:

a moving quenching mechanism 1, a first motor 11, a screw rod 12, a moving block 13, a quenching coil 14, a water spray pipe 15,

The rotary clamping mechanism 2, the base 20, the first bearing seat 201, the second motor 21, the first clamping rod 210, the first metal rod 211, the first tapered roller bearing 212, the first hydraulic cylinder 22, the second clamping rod 220, the second metal rod 221, the second tapered roller bearing 222, the second bearing seat 223, the push block 224, the spring 225, the button 226, the inverted-C-shaped mounting seat 29, the dovetail groove 291, the dovetail block 292, the second tapered roller bearing 222, the push block 224, the spring 225, the push button 226, the inverted-C-shaped mounting seat 29, the dovetail groove 291, the,

The feeding mechanism 3, the second hydraulic cylinder 31, the U-shaped support 32, the L-shaped sliding groove 320, the vertical groove 321, the horizontal groove 322, the inclined through groove 331, the sliding block 33, the lifting part 34, the sliding rod 341, the groove 3410, the inclined through groove 331, the supporting rod 342, the V-shaped supporting block 343, the inverted T-shaped fixture block 3431, the stop block 3432, the horizontal plate 344, and the inverted T-shaped groove 345.

Detailed Description

The present invention will be described in detail with reference to the drawings and specific embodiments, wherein like reference numerals are used for similar or identical parts in the drawings or the description, and implementations not shown or described in the drawings are known to those of ordinary skill in the art. In addition, directional terms, such as "upper", "lower", "top", "bottom", "left", "right", "front", "rear", and the like, used in the embodiments are only directions referring to the drawings, and are not intended to limit the scope of the present invention.

As shown in fig. 1-13, the utility model discloses a high-frequency quenching device for motor shaft, including removing quenching mechanism 1, rotary clamping mechanism 2 and feed mechanism 3, remove quenching mechanism 1 and include first motor 11, fixed mounting has lead screw 12 on the output shaft of first motor 11, and threaded connection has movable block 13 on lead screw 12, and fixed mounting has quenching coil 14 on movable block 13, and spray pipe 15 is installed in quenching coil 14 outside to movable block 13. The rotary clamping mechanism 2 includes a second motor 21 and a first hydraulic cylinder 22, a first clamping rod 210 is rotatably mounted on an output shaft of the second motor 21, a second clamping rod 220 is rotatably mounted on a hydraulic rod of the first hydraulic cylinder 22, an axial lead of the quenching coil 14, an axial lead of the first clamping rod 210 and an axial lead of the second clamping rod 220 coincide, the feeding mechanism 3 includes a second hydraulic cylinder 31, a U-shaped support 32, a sliding block 33 and a lifting member 34, the second hydraulic cylinder 31 is fixedly connected with the U-shaped support 32 (not shown in the figure), in practical use, only a support needs to be fixedly mounted on the U-shaped support 32, and the second hydraulic cylinder 31 is fixedly mounted on the support, which belongs to a conventional fixing mode in the field, so the utility model discloses not too many, a hydraulic rod of the second hydraulic cylinder 31 is fixedly connected with the sliding block 33, the sliding block 33 is located in the U-shaped support 32, the side of the U-shaped support 32 is provided with an L-shaped sliding groove 320, the L-shaped sliding groove 320 comprises a vertical groove 321 and a horizontal groove 322, the vertical groove 321 is communicated with the horizontal groove 322, the side of the sliding block 33 is provided with an inclined through groove 331, the lifting part 34 comprises a sliding rod 341 and a V-shaped supporting block 343, the outer wall of the sliding rod 341 is provided with two grooves 3410, corresponding parts of the grooves 3410 of the sliding rod 341 penetrate through the inclined through groove 331, two ends of the sliding rod 341 respectively penetrate through the corresponding L-shaped sliding grooves 320, a supporting rod 342 is fixedly mounted on the outer side of the L-shaped sliding groove 320, and the V-shaped supporting block 343 is mounted at the free.

The moving block 13 is provided with a water spray pipe 15 on each of opposite sides of the quenching coil 14. The two water spray pipes 15 are controlled separately, and when the quenching coil 14 is moved to the left, the water spray pipe 15 on the right side sprays water, and vice versa. After the quenching of one motor shaft 10 is finished, the first motor 11 does not need to be controlled to rotate reversely, the moving block 13 is reset, the moving block 13 directly moves reversely, the next motor shaft 10 is quenched, and the quenching efficiency is improved.

First clamp rod 210 and second clamp rod 220 are ceramic rod, first clamp rod 210 is kept away from the first metal pole 211 of second clamp rod 220 one end fixedly connected with, fixed mounting has first tapered roller bearing 212 on the first metal pole 211, rotary clamping mechanism 2 still includes base 20, second motor 21 fixed mounting is on base 20, still fixed mounting has first bearing frame 201 on base 20, first metal pole 211 rotates through first tapered roller bearing 212 and installs on first bearing frame 201, the output shaft and the first metal pole 211 transmission of second motor 21 are connected. When the motor shaft 10 is clamped by the first clamping rod 210 and the second clamping rod 220, the first clamping rod 210 and the second clamping rod 220 are located in the stroke range of the quenching coil 14 by ceramic rods, so that the problem of deformation caused by multiple times of heating of the first clamping rod 210 and the second clamping rod 220 by the quenching coil 14 is avoided; the first metal rod 211 is supported and fixed through the first tapered roller bearing 212, and meanwhile, the output shaft of the second motor 21 is in transmission connection with the first metal rod 211, so that axial thrust to the output shaft of the second motor 21 can be avoided when the second clamping rod 220 drives the motor shaft 10 to push and press leftwards, and the second motor 21 is damaged.

Second clamp rod 220 keeps away from first clamp rod 210 one end fixedly connected with second metal pole 221, fixed mounting has second tapered roller bearing 222 on the second metal pole 221, rotary clamping mechanism 2 still includes the shape of falling C mount pad 29, first pneumatic cylinder 22 is installed on the shape of falling C mount pad 29, first pneumatic cylinder 22 is connected with second bearing frame 223, second metal pole 221 rotates through second tapered roller bearing 222 and installs on second bearing frame 223, dovetail 291 has transversely been seted up to the shape of falling C mount pad 29 inner wall, second bearing frame 223 outer wall fixed mounting has dovetail block 292, dovetail block 292 wears to establish in dovetail 291. By the cooperation of the second tapered roller bearing 222, the dovetail block 292, and the dovetail groove 291, the hydraulic rod of the first hydraulic cylinder 22 is prevented from rotating together with the motor shaft 10.

The first hydraulic cylinder 22 is fixedly provided with a push block 224 near one end of the second bearing block 223, the push block 224 is slidably connected with the second bearing block 223, a spring 225 is installed between the push block 224 and the second bearing block 223, a button 226 is further fixedly installed on the push block 224, the button 226 is electrically connected with a control module, and the control module is electrically connected with the first motor 11, the second motor 21, the first hydraulic cylinder 22 and the second hydraulic cylinder 31. When the quenching device is used, the first hydraulic cylinder 22 is started, the hydraulic rod of the first hydraulic rod 22 extends out to drive the second clamping rod 220 to move leftwards until the motor shaft 10 is driven to abut against the first clamping rod 210, the hydraulic rod of the first hydraulic rod 22 continues to extend out to overcome the pressure of the spring 225, so that the button 226 is pressed by the second bearing seat 223, after the button 226 is pressed, a signal is sent to the control module, at the moment, the hydraulic rod of the second hydraulic cylinder 31 is controlled to retract, the V-shaped supporting block 343 moves vertically downwards first, and the motion track of the quenching coil 14 is given out; after the second hydraulic cylinder 31 moves downwards to the right position, the first motor 11 and the second motor 21 are controlled by the control module to start rotating, meanwhile, the hydraulic rod of the first hydraulic rod 22 is controlled to stop extending out and is kept at the position, the motor shaft 10 starts to be heated, the automation degree is higher, and the operation is more convenient.

The V-shaped support block 343 is detachably connected to the support rod 342. The different V-shaped support blocks 343 may be replaced according to motor shafts 10 of different diameters such that the axial lines of the motor shafts 10 placed on the V-shaped support blocks 343 coincide with the axial lines of the first and second clamping bars 210 and 220.

A transverse plate 344 is fixedly arranged at the free end of the supporting rod 342, a plurality of inverted T-shaped grooves 345 are uniformly formed in the transverse plate 344, an inverted T-shaped block 3431 is integrally formed on the V-shaped supporting block 343, the inverted T-shaped block 3431 is clamped in the inverted T-shaped grooves 345, and a block 3432 is further integrally formed at the top end of the inverted T-shaped block 3431 on the V-shaped supporting block 343. The V-shaped supporting block 343 and the supporting rod 342 are mutually clamped with the inverted T-shaped groove 345 through the inverted T-shaped clamping block 3431 to complete detachable connection, the structure is simple, the replacement is convenient, and the stop block 3432 plays a limiting role in the detachable connection; the inverted T-shaped grooves 345 are multiple, and the position of the V-shaped support block 343 on the support rod 342 can be adjusted according to the position of the step on the motor shaft 10, so as to avoid the situation that the stepped motor shaft 10 cannot be pushed by the second clamping rod 220 after being placed on the V-shaped support block 343.

The free ends of the first clamping bar 210 and the second clamping bar 220 are conical. When the motor shaft 10 with the blind holes formed in the axial lines at the two ends is quenched, the axial line of the motor shaft 10 can be automatically adjusted to be coincident with the axial lines of the first clamping rod 210 and the second clamping rod 220 through the matching of the conical end and the blind holes, when the motor shaft 10 with a small diameter difference is quenched, the new V-shaped supporting block 343 does not need to be replaced, the manufacturing of the tool for the V-shaped supporting block 343 is reduced, and the use is more convenient.

In this embodiment, when the feeding mechanism is used, the state of the feeding mechanism is in the state shown in fig. 4 and 13, at this time, the sliding rod 341 is located at the lowermost end of the inclined through slot 331 and at the foremost end of the transverse slot 322, at this time, after the motor shaft is placed on the V-shaped supporting block 343, the second hydraulic cylinder 31 is started and started, so that the hydraulic rod of the second hydraulic cylinder 31 extends, the lifting member 34 is driven to move transversely along the transverse slot 322 (as shown in fig. 3), the hydraulic rod of the second hydraulic cylinder 31 continues to extend, the lifting member 34 is driven to move vertically and upwardly along the vertical slot 321, until the sliding rod 341 moves to the uppermost end of the vertical slot 321 (as shown in fig. 2);

then, the first hydraulic cylinder 22 is started, so that the hydraulic rod of the first hydraulic cylinder 22 extends to drive the second clamping rod 220 to move leftward until the motor shaft 10 is driven to abut against the first clamping rod 210, the hydraulic rod of the first hydraulic cylinder 22 continues to extend to overcome the pressure of the spring 225, so that the button 226 is pressed by the second bearing seat 223, and after the button 226 is pressed, a signal is sent to the control module, at this time, the hydraulic rod of the second hydraulic cylinder 31 is controlled to retract, and the V-shaped support block 343 moves vertically downward first, so that the movement track of the quenching coil 14 is made (as shown in fig. 12); after the second hydraulic cylinder 31 moves downwards to the right position, the control module controls the first motor 11 and the second motor 21 to start rotating, and controls the hydraulic rod of the first hydraulic rod 22 to stop extending and to be kept at the position, and the motor shaft 10 starts to be heated;

the second hydraulic cylinder 31 continues to retract after controlling the V-shaped support block 343 to move vertically downward to give way to the motion track of the quenching coil 14 until the sliding rod 341 moves to the lowest end of the inclined through slot 331 and the foremost end of the transverse slot 322 (as shown in fig. 13);

the first motor 11 drives the screw rod 12 to rotate, and further drives the quenching coil 14 to move from left to right to heat the motor shaft 10, and meanwhile, the water spray pipe 15 on the right side of the quenching coil 14 sprays water to finish quenching on the motor shaft 10;

the second motor 21 drives the motor shaft 10 to rotate, so that the position of the motor shaft 10 sprayed with water is spiral, and the quenching is more uniform;

after the quenching of one motor shaft 10 is completed, the first motor 11 and the second motor 21 stop operating, the hydraulic rod of the first hydraulic cylinder 22 retracts, and at the moment, the motor shaft 10 is in a suspended state, and directly falls off under the action of gravity to separate from the quenching device.

The high-frequency quenching device for the motor shaft provided by the utility model is described in detail. The description of the specific embodiments is only intended to facilitate an understanding of the method of the invention and its core ideas. It should be noted that, for those skilled in the art, without departing from the principle of the present invention, the present invention can be further modified and modified, and such modifications and modifications also fall within the protection scope of the appended claims.

Claims (8)

1. A high-frequency quenching device for a motor shaft is characterized in that: the quenching device comprises a movable quenching mechanism (1), a rotary clamping mechanism (2) and a feeding mechanism (3), wherein the movable quenching mechanism (1) comprises a first motor (11), a lead screw (12) is fixedly installed on an output shaft of the first motor (11), a movable block (13) is connected onto the lead screw (12) in a threaded manner, a quenching coil (14) is fixedly installed on the movable block (13), a water spray pipe (15) is installed on the outer side of the quenching coil (14) on the movable block (13), the rotary clamping mechanism (2) comprises a second motor (21) and a first hydraulic cylinder (22), a first clamping rod (210) is rotatably installed on the output shaft of the second motor (21), a second clamping rod (220) is rotatably installed on a hydraulic rod of the first hydraulic cylinder (22), and the axial lead of the quenching coil (14), the axial lead of the first clamping rod (210) and the axial lead of the second clamping rod (220) coincide, the feeding mechanism (3) comprises a second hydraulic cylinder (31), a U-shaped support (32), a sliding block (33) and a lifting component (34), the second hydraulic cylinder (31) is fixedly connected with the U-shaped support (32), a hydraulic rod of the second hydraulic cylinder (31) is fixedly connected with the sliding block (33), the sliding block (33) is positioned in the U-shaped support (32), an L-shaped sliding groove (320) is formed in the side surface of the U-shaped support (32), the L-shaped sliding groove (320) comprises a vertical groove (321) and a transverse groove (322), the vertical groove (321) is communicated with the transverse groove (322), an inclined through groove (331) is formed in the side surface of the sliding block (33), the lifting component (34) comprises a sliding rod (341) and a V-shaped support block (343), two grooves (3410) are formed in the outer wall of the sliding rod (341), and corresponding parts of the grooves (3410) of the sliding rod (341) are arranged in the inclined through groove (331) in a penetrating manner, two ends of the sliding rod (341) respectively penetrate through the corresponding L-shaped sliding grooves (320), a supporting rod (342) is fixedly installed on the outer side of each L-shaped sliding groove (320), and the V-shaped supporting block (343) is installed at the free end of each supporting rod (342).

2. The motor shaft high-frequency quenching device as claimed in claim 1, wherein: and the moving block (13) is provided with a water spray pipe (15) at two opposite sides of the quenching coil (14).

3. The motor shaft high-frequency quenching device as claimed in claim 1, wherein: first clamp rod (210) and second clamp rod (220) are ceramic rod, first clamp rod (210) are kept away from the first metal pole (211) of second clamp rod (220) one end fixedly connected with, fixed mounting has first tapered roller bearing (212) on first metal pole (211), rotary clamping mechanism (2) still include base (20), second motor (21) fixed mounting is on base (20), still fixed mounting has first bearing frame (201) on base (20), first metal pole (211) are rotated through first tapered roller bearing (212) and are installed on first bearing frame (201), the output shaft and first metal pole (211) transmission of second motor (21) are connected.

4. The motor shaft high-frequency quenching device as claimed in claim 1, wherein: second clamp rod (220) are kept away from first clamp rod (210) one end fixedly connected with second metal pole (221), fixed mounting has second tapered roller bearing (222) on second metal pole (221), rotary clamping mechanism (2) still include shape mount pad (29) of falling C, first pneumatic cylinder (22) are installed on shape mount pad (29) of falling C, first pneumatic cylinder (22) are connected with second bearing frame (223), second metal pole (221) are installed on second bearing frame (223) through second tapered roller bearing (222) rotation, dovetail (291) have transversely been seted up to shape mount pad (29) inner wall of falling C, second bearing frame (223) outer wall fixed mounting has dovetail block (292), dovetail block (292) are worn to establish in dovetail (291).

5. The motor shaft high-frequency quenching device as claimed in claim 4, wherein: first pneumatic cylinder (22) are close to fixed ejector pad (224) that is equipped with of second bearing frame (223) one end, ejector pad (224) and second bearing frame (223) sliding connection, install spring (225) between ejector pad (224) and second bearing frame (223), it has button (226) still to fix on ejector pad (224), button (226) electric connection has control module, control module and first motor (11), second motor (21), first pneumatic cylinder (22) and second pneumatic cylinder (31) electric connection.

6. The motor shaft high-frequency quenching device as claimed in claim 1, wherein: the V-shaped supporting block (343) is detachably connected with the supporting rod (342).

7. The high-frequency quenching device for the motor shaft as claimed in claim 6, wherein: a transverse plate (344) is fixedly arranged at the free end of the supporting rod (342), a plurality of inverted T-shaped grooves (345) are uniformly formed in the transverse plate (344), an inverted T-shaped clamping block (3431) is integrally formed on the V-shaped supporting block (343), the inverted T-shaped clamping block (3431) is clamped in the inverted T-shaped grooves (345), and a stop block (3432) is further integrally formed at the top end of the inverted T-shaped clamping block (3431) of the V-shaped supporting block (343).

8. The motor shaft high-frequency quenching device as claimed in claim 1, wherein: the free ends of the first clamping bar (210) and the second clamping bar (220) are conical.

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