CN215699550U - Motor rotor torsional spring installation device - Google Patents

Abstract

The utility model discloses an electric motor rotor torsional spring installation device, including the processing platform of bottom installation, be used for pressing the bearing station with the rotor that the bearing was installed on the rotor subassembly to and be used for installing the torsional spring installation station on the rotor subassembly with the torsional spring, the processing platform includes: the lower part is connected with a supporting rod and an adjusting supporting leg arranged at the bottom of the supporting rod. The bottom of the support rod of the motor rotor torsion spring mounting device is provided with the adjusting support leg, the height of the adjusting support leg can be adjusted after the adjusting support leg rotates along the threaded rod, a processing table is guaranteed to be horizontal, a rotor pressure bearing station is mounted on the processing table through the support frame, a bearing is automatically conveyed to a material pressing frame through the cam divider and the material pushing cylinder, the material pressing cylinder descends to press the bearing into a rotor assembly, the processing efficiency is improved, and the bearing is guaranteed to be mounted in place; after the spring installation of one side is accomplished, the product revolving cylinder drives the rotor subassembly and rotates the opposite side and carry out the installation of surplus spring, improves machining efficiency.

Description

Motor rotor torsional spring installation device

Technical Field

The utility model relates to an electric motor rotor torsional spring installation technical field specifically is an electric motor rotor torsional spring installation device.

Background

The rotor of the electrical machine is also a rotating part in the electrical machine. 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. The motor rotor is divided into an inner rotor rotation mode and an outer rotor rotation mode. The inner rotor rotates in such a way that a core body in the middle of the motor is a rotating body, and torque (referred to as a motor) is output or energy is input (referred to as a generator). The external rotor rotation mode is that the motor outer body is taken as a rotating body, and the application of various occasions is facilitated in different modes. And two ends of the rotor adopt rolling bearings and are fixedly arranged in an end cover of a motor shell. Since whatever type of rotor, when it is in operation, generates centrifugal inertia forces and affects the strength and mechanical efficiency of the rotor. The rotor is properly balanced to redistribute the mass of its parts to reduce the centrifugal inertial forces generated during rotation. Torsion springs are required to be installed in a particular motor rotor.

The existing motor rotor torsion spring is usually installed manually, the machining efficiency is low, the installation is easy and not in place, and the product quality is influenced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an electric motor rotor torsional spring installation device to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above purpose, the utility model provides the following technical scheme: an electric motor rotor torsional spring installation device, includes the processing platform of bottom installation, is used for pressing the bearing station with the rotor on installing the bearing to the rotor subassembly to and be used for installing the torsional spring with the torsional spring on the rotor subassembly torsional spring installation station, the processing platform includes:

a support rod connected and mounted below, an

The bottom of the supporting rod is provided with an adjusting supporting leg.

Furthermore, the adjusting support legs are connected with the support rods through threaded rods to form a movable structure, and the support rods are connected with the processing table through bolts to form a fixed structure.

Further, the rotor press bearing station comprises:

a support frame connected with the processing table;

the cam divider is arranged at the bottom of the outer side;

the material pushing cylinder is arranged at the bottom of the support frame;

a material pressing frame is arranged above the material pushing cylinder;

a rotor assembly provided on the material pressing frame, and

the material pressing cylinder is arranged at the top of the rotor component.

Furthermore, the support frame and the processing table are connected through bolts to form a fixing structure, the cam divider drives the feeding pipe to form a rotating structure, and a feeding guide rail is arranged between the material pressing frame and the support frame and connected through welding to form the fixing structure.

Furthermore, the material pushing cylinder drives a bearing in the material loading guide rail to form a movable structure, the rotor assembly is connected with the bearing in a clamping mode on the material pressing frame to form a fixed structure, and the material pressing cylinder, the material pressing frame and the rotor assembly are located on the same vertical line.

Further, the torsion spring installation station includes:

a support plate connected with the processing table;

a slide rail mounted on the support plate;

a translation feeding cylinder is arranged on the right side of the supporting plate;

a product rotating cylinder is arranged on the left side of the supporting plate;

a hook spring cylinder is arranged at the rear of the right side of the product rotating cylinder;

a spring rotating cylinder is arranged above the supporting plate;

a small lifting cylinder connected to the outside of the mounting plate of the spring rotary cylinder, an

The spring poking cylinder is arranged at the tail end of the left side.

Furthermore, the supporting plate and the processing table are connected through bolts to form a fixed structure, the two sliding rails are symmetrically arranged, and the translation feeding cylinder drives the spring rotating cylinder and the mounting plate thereof to form a sliding structure along the sliding rails.

Furthermore, the small lifting cylinder drives the spring rotating cylinder to form a lifting structure, the spring rotating cylinder drives the spring to form a rotating structure, and the product rotating cylinder drives the rotor assembly placed on the product rotating cylinder to form a rotating structure.

Compared with the prior art, this practical beneficial effect is:

the bottom of the supporting rod is provided with an adjusting supporting leg, the height of the adjusting supporting leg can be adjusted after the adjusting supporting leg rotates along the threaded rod, the processing table is guaranteed to be horizontal, a rotor pressing bearing station is installed on the processing table through a supporting frame, the bearing is automatically conveyed to a material pressing frame through a cam divider and a material pushing cylinder, the material pressing cylinder descends to press the bearing into the rotor assembly, the processing efficiency is improved, and the bearing is guaranteed to be installed in place;

be provided with torsional spring installation station, in the installation that carries out the spring, when moving expected position after becoming the shape of needs with the spring hook through hook spring cylinder, dial spring cylinder and stir the spring downwards, make the spring mounting target in place, after the spring mounting of one side was accomplished, product revolving cylinder drove the rotor subassembly and changes the opposite side and carry out the installation of surplus spring, improvement machining efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts. Throughout the drawings, like elements or portions are generally identified by like reference numerals. In the drawings, elements or portions are not necessarily drawn to scale.

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic view of a rotor bearing pressing station structure according to the present invention;

FIG. 3 is a schematic diagram of the torsion spring mounting station of the present invention.

In the figure: 1. a processing table; 110. a support bar; 120. adjusting the support legs; 2. pressing a bearing station by the rotor; 210. a support frame; 220. a cam divider; 230. a material pushing cylinder; 240. a material pressing frame; 250. a rotor assembly; 260. a material pressing cylinder; 3. a torsion spring mounting station; 310. a support plate; 320. a slide rail; 330. a translation feeding cylinder; 340. a product rotating cylinder; 350. a hook spring cylinder; 360. a spring rotating cylinder; 370. a small lifting cylinder; 380. and a spring-pulling cylinder.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front", "rear", "both ends", "one end", "the other end", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "connected," and the like are to be construed broadly, such as "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments obtained by persons skilled in the art based on the embodiments in the present application without any creative work belong to the protection scope of the present application.

Referring to fig. 1-3, the present invention provides a technical solution: the utility model provides an electric motor rotor torsional spring installation device, includes the processing platform 1 of bottom installation, is used for installing the rotor pressure bearing station 2 on the rotor subassembly with the bearing to and be used for installing the torsional spring installation station 3 on the rotor subassembly, processing platform 1 includes: the lower part is connected with the supporting rod 110 which is arranged, and the adjusting foot 120 which is arranged at the bottom of the supporting rod 110.

The adjusting support legs 120 are connected with the support rods 110 through threaded rods to form a movable structure, the support rods 110 are connected with the machining table 1 through welding to form a fixed structure, and the adjusting support legs 120 rotate along the threaded rods to adjust the height, so that the machining table 1 is guaranteed to be horizontal.

Rotor pressure bearing station 2 includes: a support frame 210 connected to the processing table 1; a cam divider 220 mounted at the bottom of the outer side; a material pushing cylinder 230 at the bottom of the support frame 210; a material pressing frame 240 arranged above the material pushing cylinder 230; a rotor assembly 250 arranged on the material pressing frame 240, and a material pressing air cylinder 260 arranged on the top of the rotor assembly 250.

Support frame 210 and processing platform 1 pass through bolted connection and constitute fixed knot structure, and cam splitter 220 drives the material loading pipe and constitutes revolution mechanic, presses to be provided with between material frame 240 and the support frame 210 material loading guide rail and passes through bolted connection and constitute fixed knot structure, and when the material loading pipe did not expect at present, cam splitter 220 rotated and changed the material pipe.

The material pushing cylinder 230 drives the bearing in the material loading guide rail to form a movable structure, the rotor assembly 250 is connected with the bearing on the material pressing frame 240 in a clamping mode to form a fixed structure, the material pressing cylinder 260, the material pressing frame 240 and the rotor assembly 250 are located on the same vertical line, and after the previous bearing is completely pressed and taken away, the material pushing cylinder 230 pushes the bearing to be pushed forwards into the material pressing frame 240.

Torsion spring installation station 3 includes: a support plate 310 connected to the processing table 1; a slide rail 320 installed on the support plate 310; a translation feeding cylinder 330 arranged at the right side of the supporting plate 310; a product rotating cylinder 340 installed at the left side of the support plate 310; a hook spring cylinder 350 installed at the rear of the right side of the product rotation cylinder 340; a spring rotating cylinder 360 installed above the support plate 310; a small lifting cylinder 370 connected with the outer side of the mounting plate of the spring rotating cylinder 360, and a spring pulling cylinder 380 arranged at the tail end of the left side.

The supporting plate 310 and the processing table 1 are connected through bolts to form a fixed structure, two sliding rails 320 are symmetrically arranged, the translational feeding cylinder 330 drives the spring rotating cylinder 360 and the mounting plate thereof to form a sliding structure along the sliding rails 320, and the translational feeding cylinder 330 drives the hook spring cylinder 350, the spring rotating cylinder 360, the small lifting cylinder 370 and the spring pulling cylinder 380 to move back and forth for feeding.

The small lifting cylinder 370 drives the spring rotating cylinder 360 to form a lifting structure, the spring rotating cylinder 360 drives the spring to form a rotating structure, the product rotating cylinder 340 drives the rotor assembly 250 placed on the product rotating cylinder to form a rotating structure, and after the first spring is completely installed, the product rotating cylinder rotates 180 degrees to wait for installation of the second spring.

When in use, firstly, the height of the adjusting support legs 120 is adjusted by rotating along the threaded rods, the processing table 1 is ensured to be horizontal, when the current feeding pipe is not fed, the cam divider 220 rotates to replace the feeding pipe, the bearing is conveyed to the feeding guide rail, the rotor assembly 250 is manually placed on the material pressing frame 240, the bottom of the rotor assembly 250 is attached to the bearing at the moment, the starting button is pressed to press the material pressing cylinder 260 to move downwards for pressing, the product is manually taken out after pressing, after the previous bearing is pressed and taken away, the material pushing cylinder 230 pushes the bearing to push forwards into the material pressing frame 240, the operation is repeated to mount the rotor assembly 250 and the bearing, then the rotor assembly 250 provided with the bearing is manually placed on the product rotating cylinder 340 on the torsion spring mounting station 3 to be fixed, the torsion spring is manually placed at a specified position on the right side machine position, the starting button is pressed, the spring is hooked by the hook spring cylinder 350, the spring rotating cylinder 360 rotates for 180 degrees, the small lifting cylinder 370 lifts the torsion spring mounting part structure, the translational feeding cylinder 330 carries out transverse translational feeding, the small lifting cylinder 370 descends to enable the torsion spring to reach an expected position, the spring shifting cylinder 380 shifts the spring into a product motor, the spring shifting cylinder 380 returns to the original position, the small lifting cylinder 370 lifts the torsion spring mounting part structure, the translational feeding cylinder 330 carries out transverse translational returning, the product rotating cylinder 340 rotates the spring on the other side by 180 degrees by the product rotating motor, the spring rotating cylinder 360 rotates for 180 degrees simultaneously, the hook foot of the hook spring is loosened by the hook spring cylinder 350, the torsion spring is manually placed at a specified position on the right side again, the starting button is pressed, the hook spring is hooked by the hook spring cylinder 350, the spring rotating cylinder 360 rotates for 180 degrees, the translational feeding cylinder 330 carries out transverse translational feeding, and the small lifting cylinder 370 descends to enable the torsion spring to reach the expected position, the spring poking cylinder 380 pokes the spring into the product motor, the spring poking cylinder 380 returns to the original position, the small lifting cylinder 370 lifts the torsion spring mounting part structure, the translation feeding cylinder 330 transversely translates and returns, the product rotating cylinder 340 rotates the product motor 180 degrees, meanwhile, the spring rotating cylinder 360 rotates 180 degrees, the small lifting cylinder 370 descends to the original position, the hook spring cylinder 350 loosens the hook foot of the hook spring, and the mounting of the torsion spring is completed.

The foregoing is merely an example of the present invention and common general knowledge of known specific structures and features of the embodiments is not described herein in any greater detail. It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (8)

1. The utility model provides an electric motor rotor torsional spring installation device, includes processing platform (1) of bottom installation, is used for pressing bearing station (2) with the rotor that the bearing was installed on the rotor subassembly to and be used for installing the torsional spring installation station (3) on the rotor subassembly, its characterized in that: the processing table (1) comprises:

a support rod (110) connected and mounted thereunder, an

An adjusting foot (120) is arranged at the bottom of the supporting rod (110).

2. A motor rotor torsion spring mounting device according to claim 1, wherein: the adjustable supporting foot (120) is connected with the supporting rod (110) through a threaded rod to form a movable structure, and the supporting rod (110) is connected with the processing table (1) through a bolt to form a fixed structure.

3. A motor rotor torsion spring mounting device according to claim 1, wherein: the rotor bearing pressing station (2) comprises:

a support frame (210) connected with the processing table (1);

a cam divider (220) arranged at the bottom of the outer side;

a material pushing cylinder (230) at the bottom of the support frame (210);

a material pressing frame (240) is arranged above the material pushing cylinder (230);

a rotor assembly (250) disposed on the plunger rack (240), and

and a material pressing cylinder (260) is arranged at the top of the rotor component (250).

4. A motor rotor torsion spring mounting device according to claim 3, wherein: the supporting frame (210) and the processing table (1) are connected through bolts to form a fixing structure, the cam divider (220) drives the feeding pipe to form a rotating structure, and a feeding guide rail is arranged between the material pressing frame (240) and the supporting frame (210) and is connected through welding to form the fixing structure.

5. A motor rotor torsion spring mounting device according to claim 3, wherein: the material pushing cylinder (230) drives a bearing in the material loading guide rail to form a movable structure, the rotor assembly (250) is connected with the bearing in a clamping mode on the material pressing frame (240) to form a fixed structure, and the material pressing cylinder (260), the material pressing frame (240) and the rotor assembly (250) are located on the same vertical line.

6. A motor rotor torsion spring mounting device according to claim 1, wherein: the torsion spring mounting station (3) comprises:

a support plate (310) connected to the processing table (1);

a slide rail (320) mounted on the support plate (310);

a translational feeding cylinder (330) arranged at the right side of the supporting plate (310);

a product rotating cylinder (340) installed at the left side of the support plate (310);

a hook spring cylinder (350) arranged at the rear of the right side of the product rotating cylinder (340);

a spring rotary cylinder (360) arranged above the support plate (310);

a small lifting cylinder (370) connected to the outside of the mounting plate of the spring rotary cylinder (360), and

a spring-pulling cylinder (380) is arranged at the left end.

7. A motor rotor torsion spring mounting device according to claim 6, wherein: the supporting plate (310) is connected with the processing table (1) through bolts to form a fixed structure, the sliding rails (320) are symmetrically provided with two, and the translation feeding cylinder (330) drives the spring rotating cylinder (360) and the mounting plate thereof to form a sliding structure along the sliding rails (320).

8. A motor rotor torsion spring mounting device according to claim 6, wherein: little lift cylinder (370) drive spring revolving cylinder (360) and constitute elevation structure, and spring revolving cylinder (360) drive the spring and constitute revolution structure, product revolving cylinder (340) drive rotor subassembly (250) of placing on it and constitute revolution structure.

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