CN112621183A

CN112621183A - Intelligent auxiliary installation device for electromechanical equipment

Info

Publication number: CN112621183A
Application number: CN202110261749.1A
Authority: CN
Inventors: 尚新闻; 刘源; 申祖辉; 陆雯; 马铭均; 王佳佳; 陈兴华; 平娟
Original assignee: Xinxiang Vocational and Technical College
Current assignee: Xinxiang Vocational and Technical College
Priority date: 2021-03-10
Filing date: 2021-03-10
Publication date: 2021-04-09
Anticipated expiration: 2041-03-10
Also published as: CN112621183B

Abstract

The invention relates to an intelligent auxiliary installation device, in particular to an intelligent auxiliary installation device for electromechanical equipment. The technical problem is to provide an intelligent auxiliary mounting device for electromechanical equipment, which can facilitate proofreading and intelligent mounting. The utility model provides an installation device is assisted to electromechanical device intelligence, includes chassis, workstation, fixed frame, first pneumatic cylinder, promotes piece and pushing equipment, and the workstation is installed at the top of chassis, and the right side at workstation top is connected with fixed frame, installs first pneumatic cylinder in the fixed frame, and the left end rigid coupling of first pneumatic cylinder telescopic link promotes the piece, and the left workstation top of fixed frame is provided with pushing equipment. The rotor can be limited and fixed through the clamping mechanism, the bearing installation of the rotor can be completed through the matching of the material pushing mechanism and the material feeding mechanism, and meanwhile, the clamping mechanism can work to automatically clamp, fix and calibrate the rotor, so that the production yield and the production efficiency can be improved.

Description

Intelligent auxiliary installation device for electromechanical equipment

Technical Field

The invention relates to an intelligent auxiliary installation device, in particular to an intelligent auxiliary installation device for electromechanical equipment.

Background

The motor rotor is a rotating part in the motor; the motor consists of a rotor and a stator, and is a conversion device for realizing electric energy and mechanical energy and electric energy; the rotor of the motor is divided into a motor rotor and a generator rotor.

When the existing motor rotor is provided with a bearing, the rotor is usually fixed firstly, then the bearing is pressed on the rotor through a hydraulic method, and the bearing installation of the rotor is completed through the way, because the existing hydraulic method does not calibrate the rotor when the bearing is installed on the rotor, and the phenomenon of uneven stress is easy to occur when the bearing is installed on the rotor, the rotor or the bearing is damaged, the assembled motor rotor has more scrapped products, in the existing hydraulic method, the rotor is usually mounted with the bearing by means of a hydraulic cylinder, during assembly, a worker needs to hold the bearing right above the rotor for calibration, and then the bearing is pressed downwards by the hydraulic cylinder to be assembled on the rotor, in the above operation process, the hydraulic cylinder is prone to hurting the hand of a worker due to improper operation of the worker, and the efficiency of assembling the bearing and the rotor through manual alignment is low.

Aiming at the problems, an intelligent auxiliary mounting device for electromechanical equipment, which can facilitate proofreading and intelligent mounting, is developed so as to improve the production qualification rate and the production efficiency.

Disclosure of Invention

In order to overcome the current hydraulic pressure method and carry out the bearing installation to the rotor through the mode of pneumatic cylinder usually, need the workman to hold the bearing and be located the rotor during the equipment and proofread directly over, then push down the bearing through the pneumatic cylinder, make the bearing assembly on the rotor, appear often in above operation process because workman's misoperation, the pneumatic cylinder crushes workman's hand easily to manual proofreading bearing and rotor carry out the shortcoming that assembly efficiency is low, the technical problem does: the intelligent auxiliary mounting device for the electromechanical equipment is convenient to calibrate and intelligently mount.

The technical scheme is as follows: an electromechanical device intelligence assists installation device, including: the top of the chassis is provided with a workbench; the fixing frame is connected to one side of the top of the workbench; the first hydraulic cylinder is arranged in the fixed frame; the pushing block is connected with a telescopic rod of the first hydraulic cylinder; the pushing mechanism is arranged on one side, close to the fixed frame, of the top of the workbench; the feeding mechanism is arranged on one side, close to the material pushing mechanism, of the top of the workbench and is fixedly connected with a telescopic rod of the first hydraulic cylinder; the clamping mechanism is arranged on one side of the feeding mechanism; pushing equipment includes: the second hydraulic cylinder is arranged on one side, close to the fixed frame, of the top of the workbench; the sliding plate is connected with the telescopic rod of the second hydraulic cylinder and is arranged at the top of the workbench in a sliding manner; two limiting blocks are arranged and are respectively connected to the middles of the two sides of the top of the sliding plate; feed mechanism including: two mounting racks are arranged and are respectively connected to the tops of the workbenches on the two sides of the sliding plate; two connecting plates are arranged and respectively fixedly connected between the lower parts of the two mounting racks; the supporting plate is fixedly connected to one side, close to the mounting frame on one side, of the top of the workbench; the wedge-shaped plate is connected to one side, far away from the pushing block, of the telescopic rod of the first hydraulic cylinder, is positioned on the upper side of the supporting plate, and is connected with the mounting frame on one side in a sliding mode; the upper parts of the inner side walls of the two mounting racks are respectively provided with a first sliding chute, and the first sliding chutes are internally provided with sliding blocks in a sliding manner; two containing boxes are arranged and are respectively and fixedly connected to the corresponding side walls of the sliding blocks; two fixing plates are arranged and are respectively connected to one side of the upper part of the side wall of the corresponding mounting rack far away from the containing box; two first guide rods are arranged and are respectively arranged in the middle of the corresponding fixing plate in a sliding manner; the two first springs are respectively connected between the two corresponding containing boxes and the fixed plate, the two first springs are respectively wound on the outer sides of the corresponding first guide rods, a containing groove is formed in the lower portion of the side wall of the containing box far away from the fixed frame, and a sliding groove is formed in the lower portion of the side wall of the containing box close to the fixed frame; the wedge-shaped frame is connected between the lower parts of the side walls of the two containing boxes and is matched with the wedge-shaped plate; the clamping mechanism comprises: the sliding plate is arranged between one sides of the inner side walls of the two connecting plates in a sliding manner; two fixed blocks are respectively and fixedly connected to one side, far away from the sliding plate, of the inner side walls of the two corresponding connecting plates; two second guide rods are fixedly connected to the middle parts of the corresponding fixed blocks respectively, and both the two second guide rods are fixedly connected with the side wall of the sliding plate; two second springs are respectively and fixedly connected between the corresponding two sliding plates and the fixed block, and the two second springs are respectively wound on the outer sides of the corresponding second guide rods; the sliding frame is arranged on two sides of the sliding plate and is internally provided with a sliding frame in a sliding manner; the two arc-shaped clamping plates are respectively connected to the lower parts of the side walls of the two corresponding sliding frames; the mounting frame is fixedly connected to the top of the sliding plate between the two cross sliding chutes; the electric control push rod is arranged in the mounting frame, and a signal receiver is arranged on the electric control push rod; the rotating rod is fixedly connected to the upper end of the telescopic rod of the electric control push rod, and the two ends of the rotating rod are respectively rotatably provided with a swinging plate between the two ends of the rotating rod and the upper parts of the sliding frames on the two sides.

Further, the method also comprises the following steps: the lower part of the containing box at one side is provided with a moving groove at one side close to the placing groove, the lower part of the containing box at the other side is also provided with a moving groove at one side close to the sliding groove, and the moving groove is internally provided with a stop block in a sliding manner; and two third springs are respectively connected between the corresponding stop blocks and the moving grooves, and the two third springs are respectively positioned in the corresponding moving grooves.

Further, the method also comprises the following steps: the four support plates are fixedly connected to two sides of the sliding plate respectively and are positioned between the two limiting blocks; the top of the sliding plate on the lower side of the support plate is provided with a second sliding groove, and the second sliding groove is internally provided with a clamping block in a sliding manner; and four fourth springs are arranged and are respectively connected between two adjacent clamping blocks and the support plate.

The invention has the beneficial effects that:

the rotor can be limited and fixed through the clamping mechanism, the bearing installation of the rotor can be completed through the matching of the material pushing mechanism and the material feeding mechanism, and meanwhile, the clamping mechanism can work to automatically clamp, fix and calibrate the rotor, so that the production yield and the production efficiency can be improved;

through the cooperation of the third spring and the stop block, the bearing can be prevented from automatically moving out of the containing box to cause obstruction to the installation of the rotor bearing;

and the clamping blocks at the front side and the rear side can be tightly attached to the rotor through the fourth spring, so that the rotor can be limited, and the rotor bearing can be conveniently installed.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of the pushing mechanism of the present invention.

Fig. 3 is a schematic perspective view of the skateboard of the present invention.

Fig. 4 is a schematic perspective view of the feeding mechanism of the present invention.

Fig. 5 is a schematic perspective view of the mounting bracket of the present invention.

Fig. 6 is a schematic perspective view of the containing box of the present invention.

Fig. 7 is a schematic perspective view of the slider of the present invention.

Fig. 8 is a schematic perspective view of the clamping mechanism of the present invention.

Fig. 9 is a schematic perspective view of the sliding plate of the present invention.

Fig. 10 is a schematic perspective view of the mounting frame of the present invention.

Fig. 11 is a schematic perspective view of the stopper of the present invention.

Fig. 12 is a perspective view of the clamping block of the present invention.

In the reference symbols: 1_ underframe, 2_ workbench, 201_ fixed frame, 202_ first hydraulic cylinder, 203_ push block, 3_ pushing mechanism, 301_ second hydraulic cylinder, 302_ sliding plate, 303_ stopper, 4_ feeding mechanism, 401_ mounting frame, 402_ connecting plate, 403_ supporting plate, 404_ wedge plate, 405_ first chute, 406_ slider, 407_ containing box, 408_ fixed plate, 409_ first guide rod, 410_ first spring, 411_ placing groove, 412_ sliding groove, 413_ wedge frame, 5_ clamping mechanism, 501_ sliding plate, 502_ fixed block, 503_ second guide rod, 504_ second spring, 505_ cross chute, 506_ sliding frame, 507_ arc-shaped clamping plate, 508_ mounting frame, 509_ electrically controlled push rod, 510_ rotating rod, 511_ swinging plate, 6_ moving groove, 7_ stopper, 8_ third spring, 9_ fulcrum plate, 10_ second chute, 11_ clamping block, 12_ fourth spring.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings in conjunction with the following detailed description. It should be understood that the description is intended to be exemplary only, and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

Example 1

The utility model provides an electromechanical device intelligence assists installation device, as shown in fig. 1 and fig. 2, including chassis 1, workstation 2, fixed frame 201, first pneumatic cylinder 202, promote piece 203, pushing equipment 3, feed mechanism 4 and clamping mechanism 5, workstation 2 is installed at the top of chassis 1, the right side at 2 tops of workstation is connected with fixed frame 201, install first pneumatic cylinder 202 in the fixed frame 201, the left end rigid coupling of the telescopic link of first pneumatic cylinder 202 has and promotes

piece

203, 2 tops of the left workstation of fixed frame 201 are provided with pushing

equipment

3, 2 tops of workstation of pushing equipment 3 both sides are provided with feed mechanism 4, feed mechanism 4 and the telescopic link rigid coupling of first pneumatic cylinder 202, one side of feed mechanism 4 is provided with clamping mechanism 5.

When the bearing installation is needed to be carried out on the rotating shaft of the rotor, a user puts a proper amount of bearings into the feeding mechanism 4 and places the rotor on the pushing mechanism 3, then the user enables the clamping mechanism 5 to work for limiting and fixing the rotating shaft of the rotor, meanwhile, the rotating shaft of the rotor can be calibrated, then the first hydraulic cylinder 202 is started to enable the pushing block 203 to move leftwards, the feeding mechanism 4 moves along with the pushing block, so that the bearing at the lowest side of the feeding mechanism 4 and the rotating shaft of the rotor are positioned on the same straight line, at the moment, the pushing block 203 is further away from the feeding mechanism 4, the pushing block 203 continues to move leftwards to be matched with the clamping mechanism 5, the bearing at the right side can be installed at the right side of the rotating shaft of the rotor, then the user enables the pushing mechanism 3 and the feeding mechanism 4 to be matched and work, so that the bearing can be installed at the left side of the rotating shaft of the rotor, then the user, the feeding mechanism 4 is reset to remove the limitation of the rotor moving leftwards, meanwhile, the clamping mechanism 5 is reset to remove the limitation and fixation of the rotating shaft of the rotor, after the bearing is installed on the rotating shaft of the rotor, the pushing mechanism 3 continues to enable the rotor to move leftwards to be away from the feeding mechanism 4, then the rotor on the pushing mechanism 3 is taken down and replaced, then the pushing mechanism 3 is reset and closed, then a user repeats the operation, the bearing installation can be carried out on the rotating shaft of the next rotor, the rotating shaft installation bearing of the rotor is completed through the operation mode, and the production qualification rate and the production efficiency of the rotating shaft installation bearing of the rotor can be improved.

As shown in fig. 2 and 3, the pushing mechanism 3 includes a second hydraulic cylinder 301, a sliding plate 302 and a limiting block 303, the second hydraulic cylinder 301 is installed at the top of the workbench 2, the second hydraulic cylinder 301 is located at the left side of the fixing frame 201, the sliding plate 302 is fixedly connected to the left end of the telescopic rod of the second hydraulic cylinder 301, the sliding plate 302 and the top of the workbench 2 are slidably arranged, and the limiting block 303 is fixedly connected to the middle of the left side and the right side of the top of the sliding plate 302.

When a bearing needs to be installed on the rotating shaft of the rotor, a user places the rotor on the sliding plate 302, the iron core of the rotor is located between the left limiting block 303 and the right limiting block 303, the iron core of the rotor can be limited through the left limiting block 303 and the right limiting block 303, the rotating shaft of the rotor is located above the left limiting block 303 and the right limiting block 303, then the user starts the first hydraulic cylinder 202 to enable the pushing block 203 to move leftwards, the pushing block 203 can enable the feeding mechanism 4 to work while moving leftwards, the bearing on the lowest side of the feeding mechanism 4 and the rotating shaft of the rotor can be located on the same straight line, at the moment, the pushing block 203 is further away from the feeding mechanism 4, the pushing block 203 continues to move leftwards, so that the bearing on the right side can be installed on the right side of the rotating shaft of the rotor, the second hydraulic cylinder 301 is started to enable the sliding plate 302 to move leftwards, therefore, the left bearing can be installed on the left side of the rotating shaft of the rotor, then a user starts the first hydraulic cylinder 202 to enable the pushing block 203 to reset to the right, the feeding mechanism 4 is reset accordingly, the limit for the leftward movement of the rotor is released, the sliding plate 302 continues to move leftward, the sliding plate 302 can be moved leftward and away from the left installation frame 401, then the user removes the rotor on the sliding plate 302 and replaces the rotor, then the second hydraulic cylinder 301 is started to enable the sliding plate 302 to reset to the right and close, and then the user repeats the operation to enable the next rotating shaft installation of the rotor.

As shown in fig. 4, 5, 6 and 7, the feeding mechanism 4 includes a mounting frame 401, a connecting plate 402, a supporting plate 403, a wedge plate 404, a sliding block 406, a containing box 407, a fixing plate 408, a first guide rod 409, a first spring 410 and a wedge frame 413, the two mounting frames 401 are respectively connected to the tops of the work tables 2 on the left and right sides of the sliding plate 302, the connecting plate 402 is fixedly connected between the lower portions of the front and rear sides of the two mounting frames 401, the supporting plate 403 is installed on the rear side of the top of the work table 2, the supporting plate 403 is located on the right side of the mounting frame 401 on the right side, the wedge plate 404 is fixedly connected to the telescopic rod of the first hydraulic cylinder 202, the wedge plate 404 is located on the right side of the pushing block 203, the wedge plate 404 is located on the upper side of the supporting plate 403, the wedge plate 404 is slidably connected to the rear side wall of the mounting frame 401 on the, the inside wall rigid coupling of controlling two sliders 406 has and holds case 407, the equal rigid coupling in inside wall upper portion of controlling two mounting brackets 401 has fixed plate 408, fixed plate 408 is located the front side that holds case 407, the middle part slidingtype of fixed plate 408 is equipped with first guide arm 409, the rear end of first guide arm 409 and the corresponding preceding lateral wall rigid coupling that holds case 407, be connected with first spring 410 between two adjacent front and back holding case 407 and fixed plate 408, control two first spring 410 and wind respectively in the first guide arm 409 outside that corresponds, the left side holds the left side wall lower part of case 407 and opens there is standing groove 411, the right side wall lower part that the case 407 was held on the right side is opened there is sliding tray 412, control two back side wall lower parts that hold case 407 and install wedge frame 413 between, wedge frame 413 and wedge 404 cooperate.

The first hydraulic cylinder 202 is started to enable the pushing block 203 to move leftwards, the pushing block 203 moves leftwards and simultaneously enables the wedge-shaped plate 404 to move leftwards, the wedge-shaped plate 404 can move leftwards and be supported through the supporting plate 403, when the wedge-shaped plate 404 moves leftwards and is in contact with the wedge-shaped frame 413, the wedge-shaped frame 404 continues to move leftwards, so that the wedge-shaped frame 413 can be squeezed to move forwards, the wedge-shaped frame 413 moves forwards to enable the containing boxes 407 on the left side and the right side to move forwards, the first spring 410 is compressed along with the wedge-shaped frame 413, so that the bearings on the lowest sides in the containing boxes 407 on the left side and the right side and the rotating shaft of the rotor are positioned on the same straight line, meanwhile, the containing boxes 407 on the left side and the right side can be limited through the wedge-shaped plate 404, at the moment, the pushing block 203 has a certain distance from the containing box 407 on the right side, the pushing block 203 continues to move, the rotor on the upper side of the sliding plate 302 can be moved leftwards by moving the pushing block 203 and the sliding plate 302 leftwards, the bearing on the lowest side in the left containing box 407 can be conveniently installed on the left side of the rotating shaft of the rotor by matching the placing groove 411, after the bearing is installed on the left side of the rotating shaft of the rotor, a user controls the first hydraulic cylinder 202 to make the pushing block 203 and the wedge plate 404 reset rightwards, after the pushing block 203 and the wedge plate 404 reset rightwards, the user closes the first hydraulic cylinder 202, because the bearing on the lowest side in the left containing box 407 and the right containing box 407 is installed on the left side and the right side of the rotating shaft of the rotor, the wedge plate 404 reset rightwards can release the limit of the wedge frame 413, under the action of the elastic force of the first spring 410, the containing boxes 407 and the wedge frames 413 on the left side and the right side can be moved backwards and reset, so that the bearing on the lowest side in the, the lowermost bearing in the storage box 407 then drops downward, and then the user repeats the above operation to install the rotating shaft of the rotor.

As shown in fig. 8, 9 and 10, the clamping mechanism 5 includes a sliding plate 501, a fixed block 502, a second guide rod 503, a second spring 504, a sliding frame 506, an arc-shaped clamp plate 507, a mounting frame 508, an electric control push rod 509, a rotating rod 510 and a swinging plate 511, the sliding plate 501 is slidably disposed between the right portions of the inner side walls of the front and rear connecting plates 402, the fixed block 502 is connected between the inner side walls of the front and rear connecting plates 402, the fixed block 502 is located at the left side of the sliding plate 501, the second guide rod 503 is slidably disposed in the middle of the fixed block 502, the right ends of the front and rear second guide rods 503 are fixedly connected to the left side wall of the sliding plate 501, the second spring 504 is fixedly connected between the sliding plate 501 and the fixed block 502, the front and rear second springs 504 are respectively wound on the outer sides of the corresponding second guide rods 503, the front and rear sides of the sliding plate 501 are respectively provided, an installation frame 508 is fixedly connected to the top of the sliding plate 501 between the front cross sliding groove 505 and the rear cross sliding groove 505, an electric control push rod 509 is arranged at the bottom in the installation frame 508, a signal receiver is arranged on the electric control push rod, a rotating rod 510 is installed at the upper end of a telescopic rod of the electric control push rod 509, and swing plates 511 are rotatably installed between the left end and the right end of the rotating rod 510 and the upper portions of the front sliding frame 506 and the rear.

When the bearing installation is needed to be carried out on the rotating shaft of the rotor, a user puts a proper amount of bearings into the feeding mechanism 4 and places the rotor on the material pushing mechanism 3, then the user enables the clamping mechanism 5 to work to limit and fix the rotating shaft of the rotor, the clamping mechanism 5 realizes the functions of limiting and calibrating the rotating shaft of the rotor, the user transmits signals to the electric control push rod 509, the electric control push rod 509 can drive the rotating rod 510 to move upwards through the signal receiver, the rotating rod 510 moves upwards to enable the sliding frames 506 at the front side and the rear side to be close through the swinging plates 511 at the front side and the rear side, the sliding frames 506 at the front side and the rear side are close to enable the arc clamping plates 507 at the front side and the rear side to be close to clamp the rotating shaft of the rotor, the rotating shaft of the rotor can be prevented from swinging in the bearing clamping process, and the qualification rate of rotor bearing assembly can, when the bearing is installed on the right side of the rotating shaft of the rotor, the pushing block 203 and the sliding plate 302 continue to move leftwards, so that the sliding plate 501 moves leftwards, the second spring 504 is compressed therewith, when the bearing is installed on the left portion of the rotating shaft of the rotor, a user transmits a signal to the electric control push rod 509, the electric control push rod 509 is enabled to pull the rotating rod 510 to move downwards through the signal receiver to reset and close, the rotating rod 510 moves downwards to enable the sliding frames 506 on the front side and the rear side to be away from and reset through the swinging plate 511, the arc-shaped clamping plates 507 on the front side and the rear side are away from and reset along with the swinging plate 511, so that the limitation on the rotor can be relieved, meanwhile, the sliding plate 501 can move rightwards to reset under the elastic force of the second spring 504.

Example 2

In addition to embodiment 1, as shown in fig. 11, the container further includes a stopper 7 and a third spring 8, wherein the moving grooves 6 are formed in the lower portions of the inner sides of the left and right containers 407, the left and right moving grooves 6 are located between the placing groove 411 and the sliding groove 412, the stopper 7 is slidably disposed in the moving groove 6, the third spring 8 is fixedly connected between the stopper 7 and the moving groove 6, and the left and right third springs 8 are respectively located in the corresponding moving grooves 6.

After the bearing is installed in the pivot of rotor, hold case 407 rearward movement and can make the bearing extrusion dog 7 of downside move downwards, third spring 8 compresses thereupon, hold case 407 and continue rearward movement, so can make and install in the pivot upper bearing of rotor shifts out and holds case 407, can make dog 7 rebound under the effect of third spring 8 elasticity reset, hold the interior downside bearing of case 407 and drop downwards thereupon, can carry on spacingly to the bearing that drops downwards through dog 7, so can conveniently install the bearing.

As shown in fig. 3 and 12, the sliding plate structure further comprises a support plate 9, a clamping block 11 and a fourth spring 12, two support plates 9 are fixedly connected to the front side and the rear side of the top of the sliding plate 302, the front support plate 9 and the rear support plate 9 are located between the left limiting block 303 and the right limiting block 303, a second sliding groove 10 is formed in the top of the sliding plate 302 on the lower side of the support plate 9, the clamping block 11 is arranged in the second sliding groove 10 in a sliding mode, and the fourth spring 12 is fixedly connected between the front clamping block 11 and the support plate.

The rotor core is put into and is pressed from both sides between the tight piece 11, the pivot of rotor this moment is located the top of two stopper 303, because it is equipped with fourth spring 12 to press from both sides tight piece 11 inboard, press from both sides tight piece 11 and slide on slide 302, so four gliding tight pieces 11 of clamp can press from both sides the rotor core of different diameters, when four gliding tight pieces 11 of clamp pressed from both sides tight rotor core, all move to slide 302 inboard through fourth spring 12, realize the function of fixing a position the rotor pivot, make the rotor pivot with hold the case 407 on the sliding tray 412 centre bore concentric, with this realization rotor accurate location and the equipment function of being fit for different model rotor pivot bearings.

The technical principle of the embodiment of the present invention is described above in conjunction with the specific embodiments. The description is only intended to explain the principles of embodiments of the invention and should not be taken in any way as limiting the scope of the embodiments of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive step, and these embodiments will fall within the scope of the present invention.

Claims

1. The utility model provides an electromechanical device intelligence auxiliary installation device which characterized in that, including:

the top of the chassis (1) is provided with a workbench (2);

the fixing frame (201) is connected to one side of the top of the workbench (2);

a first hydraulic cylinder (202) arranged in the fixed frame (201);

the pushing block (203) is connected with a telescopic rod of the first hydraulic cylinder (202);

the pushing mechanism (3) is arranged on one side, close to the fixing frame (201), of the top of the workbench (2);

the feeding mechanism (4) is arranged on one side, close to the pushing mechanism (3), of the top of the workbench (2), and the feeding mechanism (4) is fixedly connected with a telescopic rod of the first hydraulic cylinder (202);

the clamping mechanism (5) is arranged on one side of the feeding mechanism (4);

the pushing mechanism (3) comprises:

the second hydraulic cylinder (301) is arranged on one side, close to the fixed frame (201), of the top of the workbench (2);

the sliding plate (302) is connected with the telescopic rod of the second hydraulic cylinder (301), and the sliding plate (302) is arranged at the top of the workbench (2) in a sliding manner;

two limiting blocks (303) are arranged and are respectively connected to the middles of two sides of the top of the sliding plate (302);

feed mechanism (4) including:

two mounting frames (401) are arranged and are respectively connected to the tops of the working tables (2) on the two sides of the sliding plate (302);

two connecting plates (402) are arranged and are respectively and fixedly connected between the lower parts of the two mounting frames (401);

the supporting plate (403) is fixedly connected to one side, close to the mounting frame (401), of the top of the workbench (2);

the wedge-shaped plate (404) is connected to one side, far away from the pushing block (203), of the telescopic rod of the first hydraulic cylinder (202), the wedge-shaped plate (404) is located on the upper side of the supporting plate (403), and the wedge-shaped plate (404) is connected with the mounting frame (401) on one side in a sliding mode;

the upper parts of the inner side walls of the two mounting frames (401) are respectively provided with a first sliding chute (405), and the sliding blocks (406) are arranged in the first sliding chutes (405) in a sliding manner;

two containing boxes (407) are arranged and are respectively and fixedly connected to the side walls of the corresponding sliding blocks (406);

two fixing plates (408) are arranged and are respectively connected to one side, far away from the containing box (407), of the upper part of the side wall of the corresponding mounting frame (401);

two first guide rods (409) are arranged and are respectively arranged in the middle of the corresponding fixing plate (408) in a sliding manner;

the two first springs (410) are respectively connected between the two corresponding containing boxes (407) and the fixed plate (408), the two first springs (410) are respectively wound on the outer sides of the corresponding first guide rods (409), a placing groove (411) is formed in the lower portion of the side wall of the containing box (407) far away from the fixed frame (201), and a sliding groove (412) is formed in the lower portion of the side wall of the containing box (407) close to the fixed frame (201);

the wedge-shaped frame (413) is connected between the lower parts of the side walls of the two containing boxes (407), and the wedge-shaped frame (413) is matched with the wedge-shaped plate (404);

the clamping mechanism (5) comprises:

the sliding plate (501) is arranged between the inner side walls of the two connecting plates (402) in a sliding manner;

two fixing blocks (502) are respectively and fixedly connected to one side, far away from the sliding plate (501), of the inner side walls of the two corresponding connecting plates (402);

two second guide rods (503) are respectively and fixedly connected to the middle parts of the corresponding fixed blocks (502), and the two second guide rods (503) are fixedly connected with the side wall of the sliding plate (501);

two second springs (504) are respectively fixedly connected between the corresponding two sliding plates (501) and the corresponding fixed block (502), and the two second springs (504) are respectively wound on the outer sides of the corresponding second guide rods (503);

the sliding frame (506), both sides of the sliding plate (501) are provided with cross sliding chutes (505), and the sliding frame (506) is arranged in the cross sliding chutes (505) in a sliding manner;

two arc-shaped clamping plates (507) are arranged and are respectively connected to the lower parts of the side walls of the two corresponding sliding frames (506);

the mounting frame (508) is fixedly connected to the top of the sliding plate (501) between the two cross sliding chutes (505);

the electric control push rod (509) is arranged in the mounting frame (508), and a signal receiver is arranged on the electric control push rod (509);

and the rotating rod (510) is fixedly connected to the upper end of the telescopic rod of the electric control push rod (509), and the swinging plates (511) are rotatably arranged between the two ends of the rotating rod (510) and the upper parts of the sliding frames (506) at the two sides respectively.

2. The intelligent auxiliary installation device of electromechanical equipment as claimed in claim 1, further comprising:

a moving groove (6) is formed in one side, close to the placing groove (411), of the lower portion of the containing box (407) on one side, a moving groove (6) is also formed in one side, close to the sliding groove (412), of the lower portion of the containing box (407) on the other side, and the moving groove (6) is internally provided with a stop block (7) in a sliding mode;

and two third springs (8) are arranged and are respectively connected between the corresponding stop block (7) and the moving groove (6), and the two third springs (8) are respectively positioned in the corresponding moving grooves (6).

3. The intelligent auxiliary installation device of electromechanical equipment as claimed in claim 2, further comprising:

four support plates (9) are respectively and fixedly connected to two sides of the sliding plate (302), and the four support plates (9) are positioned between the two limit blocks (303);

the top of the sliding plate (302) on the lower side of the support plate (9) is provided with a second sliding chute (10), and the second sliding chute (10) is internally provided with the clamping block (11) in a sliding manner;

and four fourth springs (12) are arranged and are respectively connected between two adjacent clamping blocks (11) and the support plate (9).