CN115256202A - Automatic control device for polishing based on motor rotor shaft and polishing system applying automatic control device - Google Patents

Abstract

The invention belongs to the technical field of motor accessory manufacturing and application, and particularly discloses an automatic control device for polishing a motor rotor shaft. The invention has the beneficial effects that: 1. a semi-automatic feeding and rotating design of polishing and grinding of a motor rotor shaft is adopted to replace the traditional manual feeding control by workers, so that the polishing and grinding efficiency is improved, the product percent of pass is improved, and the economic cost is reduced; 2. the whole structure adopts a detachable structure design, so that the assembly, the subsequent transportation and the overhaul and maintenance are convenient; 3. the vertical support sliding plate, the clamping groove structure, the support bearing clamping groove and the motor rotor shaft support bearing are additionally arranged and used for supporting the motor rotor shaft in an auxiliary mode, and the polishing and grinding reliability and accuracy are improved.

Description

Automatic control device for polishing based on motor rotor shaft and polishing system applying automatic control device

Technical Field

The invention belongs to the technical field of motor accessory manufacturing and application, and particularly relates to an automatic control device for polishing a motor rotor shaft and a polishing system using the automatic control device.

Background

An Electric machine (also known as "motor") refers to an electromagnetic device that converts or transmits Electric energy according to the law of electromagnetic induction.

The motor is represented by a letter M (old standard is represented by a letter D) in a circuit, the motor mainly plays a role of generating driving torque and serving as a power source of electrical appliances or various machines, and the generator is represented by a letter G in a circuit and mainly plays a role of converting mechanical energy into electric energy.

Nickel plating refers to a process of plating a layer of nickel on a metal or some non-metal by electrolytic or chemical means, and is called nickel plating, nickel plating being electrolytic nickel plating and electroless nickel plating. The electroplating nickel is prepared by depositing a uniform and compact nickel coating on the cathode (plated part) by applying direct current in an electrolyte composed of nickel salt (called main salt), conductive salt, pH buffering agent and wetting agent, wherein bright nickel is obtained from the plating solution with brightener, and dark nickel is obtained from the electrolyte without brightener. Electroless nickel plating, also known as electroless nickel plating, and also known as autocatalytic nickel plating, refers to a process in which nickel ions in an aqueous solution are reduced by a reducing agent under certain conditions and are precipitated onto the surface of a solid substrate.

The rotor shaft of the motor is a rotating part in the motor, the motor consists of a rotor and a stator, and the motor is a conversion device for realizing electric energy and mechanical energy and electric energy. The motor rotating shaft must have enough mechanical strength and rigidity to complete the transmission of motor power, so that the motor does not vibrate or the stator and the rotor rub each other during operation.

The motor rotor shaft, which needs to be plated with nickel during the manufacturing process (see fig. 1), is used to improve the hardness, wear resistance, corrosion resistance, acid resistance, etc. of the rotor member.

After the nickel plating process is finished, the motor rotor shaft needs to be polished and ground, namely, particles or floating points and the like on the surface are removed, so that the motor rotor shaft meets the requirements of assembly and use standards. At present, when motor rotor axle polishing ground, the tradition is that the operation workman handheld motor rotor axle fixture equipment advances the operation of polishing part rubbing head, and its work efficiency is low, and artifical manual control leads to the disability rate of product high simultaneously, and the increase of phase-change has follow-up economic cost.

Therefore, in view of the above problems, the present invention provides an automatic control device for motor-based rotor shaft polishing and a polishing system using the same.

Disclosure of Invention

The purpose of the invention is as follows: the invention aims to provide an automatic control device for polishing a motor rotor shaft and a polishing system using the same, and solve the technical problems in the background art.

The technical scheme is as follows: the invention provides an automatic control device for polishing based on a motor rotor shaft, which comprises a table seat plate, a vertical support plate and a polishing component, wherein a stepping motor is arranged on one side of the vertical support plate on the table seat plate, a driving chain wheel is arranged on the stepping motor, a bearing installation groove is formed in one end of the vertical support plate, a bearing is arranged in the bearing installation groove, a transmission shaft penetrating through the bearing is arranged in one end of the vertical support plate, a driven chain wheel is arranged at one end of the transmission shaft, a connecting part is arranged at the other end of the transmission shaft, a fixed clamping block is arranged at one side of the connecting part, a movable clamping block is arranged on the fixed clamping block, a fixed clamping block ear plate and a movable clamping block ear plate are respectively arranged on the outer walls of the two sides of the fixed clamping block and the movable clamping block, a fixed clamping block ear plate through hole and a movable clamping block ear plate through hole are respectively arranged in the fixed clamping block ear plate and the movable clamping block ear plate, locking bolts and locking nuts are utilized between the fixed clamping block ear plate and the movable clamping block ear plate, and the driving chain wheel and the driven chain wheel are connected through a transmission chain; wherein, the non-polishing end of the motor rotor shaft is placed in the opposite surface of the fixed clamping block and the movable clamping block for fixing, and the driven chain wheel is driven by the stepping motor, the driving chain wheel and the transmission chain to drive the transmission shaft linkage connecting part and the fixing part to synchronously rotate anticlockwise/clockwise.

According to the technical scheme, the automatic control device for polishing the motor rotor shaft further comprises a group of first nuts and a group of second nuts, wherein the first nuts and the group of second nuts are arranged on the transmission shaft and used for locking and fixing the transmission shaft and the driven chain wheel.

According to the technical scheme, the automatic control device for polishing the motor rotor shaft further comprises a spiral groove arranged in the other end of the transmission shaft, and a connection part arranged on the other end of the transmission shaft and rotatably connected with the spiral groove; the connecting part is of a threaded rod structure, and a group of connecting part locking nuts are arranged on the connecting part of the threaded rod structure.

According to the technical scheme, the fixing part is of a circular plate type structure including but not limited to, and the fixed clamping block and the movable clamping block are of semicircular structures matched with each other for use.

According to the technical scheme, the automatic control device for polishing the motor rotor shaft further comprises a clamping groove which is arranged in the table base plate and is positioned on the other side of the vertical support plate, a vertical support sliding plate which is matched with the clamping groove for use, a support bearing clamping groove which is arranged in one end of the vertical support sliding plate, and a motor rotor shaft support bearing which is arranged in the support bearing clamping groove; the motor rotor shaft support bearing is sleeved in a non-polishing part of the motor rotor shaft and used for rotatably supporting the polishing part of the motor rotor shaft.

According to the technical scheme, the clamping groove is arranged to include but not limited to a dovetail structure, and the part, clamped into the clamping groove, of the vertical support sliding plate is arranged to include but not limited to the dovetail structure; wherein, the vertical support sliding plate can horizontally slide in the clamping groove during assembly.

According to the technical scheme, the automatic control device for polishing the motor rotor shaft further comprises a rotating speed sensor mounting screw groove arranged in the end face of one end of the transmission shaft, a rotating speed sensor mounted in the rotating speed sensor mounting screw groove, and a PLC control module matched with the rotating speed sensor for use; the PLC control module receives a transmission shaft rotating speed signal fed back by the rotating speed sensor and controls the stepping motor to regulate the speed or control the stepping motor to rotate anticlockwise/clockwise; the PLC control module is connected with a rotating speed sensor and a stepping motor, the rotating speed sensor comprises but is not limited to CS-1 and G-100-05-01, and the PLC control module comprises but is not limited to DVP02DA-E2 and 1756-IF16.

The invention provides a nickel plating and polishing system for a motor rotor shaft, which is provided with the automatic control device for polishing the motor rotor shaft.

Compared with the prior art, the automatic control device for polishing the motor rotor shaft has the advantages that: 1. the semi-automatic motor rotor shaft polishing, grinding and feeding rotary design is adopted to replace the traditional manual feeding control by workers, so that the polishing and grinding efficiency is improved, the product percent of pass is also improved, and the economic cost is reduced; 2. the whole structure adopts a detachable structure design, so that the assembly, the subsequent transportation and the overhaul and maintenance are convenient; 3. the perpendicular support sliding plate, draw-in groove structure, support bearing draw-in groove, the motor rotor shaft support bearing that increase for carry out supplementary support to the motor rotor shaft, improve reliability, the accurate nature of polishing grinding, erect in addition and support the sliding plate and can carry out the level in the draw-in groove structure and to sliding, accomplish the supplementary support of different length size's motor rotor shaft, the functionality is strong.

Drawings

To more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the following embodiments will be made to

While the drawings needed to describe the embodiments herein are briefly described, it should be apparent that the drawings described below are merely examples of the invention, and that other drawings may be derived from those of ordinary skill in the art without inventive faculty.

FIG. 1 is a schematic view of a nickel-plated post-polished portion of a rotor shaft of an electric machine;

FIG. 2 is a schematic structural diagram of a front view of an automatic control device for polishing a shaft based on a motor rotor according to the present invention;

FIG. 3 is a schematic diagram of a left-side view assembly structure of a fixed part, a fixed clamping block, a movable clamping block and the like of the automatic control device for motor rotor shaft polishing, which is based on the invention;

FIG. 4 is a schematic left-view structural diagram of a clamping groove, a vertical support sliding plate, a motor rotor shaft support bearing and the like of the automatic control device for motor rotor shaft polishing according to the present invention;

wherein, the sequence numbers in the figure are as follows: 100-bench seat plate, 101-stepping motor, 102-vertical support plate, 103-driving chain wheel, 104-driving chain, 105-bearing installation groove, 106-bearing, 107-first nut, 108-driven chain wheel, 109-second nut, 110-driving shaft, 111-spiral groove, 112-connecting part, 113-fixing part, 114-connecting part locking nut, 115-fixed clamping block, 116-fixed clamping block lug plate, 117-movable clamping block, 118-movable clamping block lug plate, 119-fixed clamping block lug plate through hole, 120-movable clamping block lug plate through hole, 121-locking bolt, 122-locking bolt nut, 123-polishing part, 124-support bearing clamping groove, 125-motor rotor shaft support bearing, 126-clamping groove, 127-vertical support sliding plate, 128-rotation speed sensor installation spiral groove, 129-rotation speed sensor and 130-PLC control module.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

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.

Example one

The automatic control device for polishing based on the motor rotor shaft, as shown in fig. 2, 3 and 4, comprises a base plate 100, a vertical support plate 102 and a polishing member 123,

on the table base plate 100, a stepping motor 101 is provided at one side of a vertical support plate 102,

the stepping motor 101 is provided with a driving sprocket 103,

a bearing installation groove 105 is formed in one end of the vertical support plate 102,

a bearing 106 is provided in the bearing installation groove 105,

a transmission shaft 110 penetrating through the bearing 106 is provided in one end of the vertical support plate 102,

one end of the driving shaft 110 is provided with a driven sprocket 108,

the other end of the transmission shaft 110 is provided with a connection part 112,

one end of the connecting portion 112 is provided with a fixing portion 113,

one surface of the fixing part 113 is provided with a fixed clamping block 115,

the fixed clamping block 115 is provided with a movable clamping block 117,

the outer walls of the two sides of the fixed clamping block 115 and the movable clamping block 117 are respectively provided with a fixed clamping block lug plate 116 and a movable clamping block lug plate 118,

the fixed clamping block ear plate 116 and the movable clamping block ear plate 118 are respectively provided with a fixed clamping block ear plate through hole 119 and a movable clamping block ear plate through hole 120,

a fixed clamping block lug plate 116 and a movable clamping block lug plate 118 pass through a fixed clamping block lug plate through hole 119 and a movable clamping block lug plate through hole 120, and utilize a locking bolt 121 and a locking bolt nut 122,

the driving sprocket 103 and the driven sprocket 108 are connected by a transmission chain 104.

The non-polished end of the motor rotor shaft is placed in the opposite surfaces of the fixed clamping block 115 and the movable clamping block 117 for fixing, and the driven chain wheel 108 is driven by the stepping motor 101, the driving chain wheel 103 and the transmission chain 104 to drive the transmission shaft 110 to drive the linkage connecting part 112 and the fixing part 113 to synchronously rotate anticlockwise/clockwise.

Example two

Based on the first embodiment, the automatic control device for polishing the motor rotor shaft is preferred to further comprise a group of first nuts 107 and a group of second nuts 109 which are arranged on the transmission shaft 110 and used for locking and fixing the transmission shaft 110 and the driven sprocket 108, wherein the transmission shaft 110 and the driven sprocket 108 are respectively formed into a detachable structural design, and assembly and maintenance are utilized.

EXAMPLE III

In addition to the first or second embodiment, the automatic control device for polishing a motor rotor shaft preferably includes a groove 111 disposed in the other end of the transmission shaft 110, and a connection portion 112 rotatably connected to the groove 111.

The connecting portion 112 is a threaded rod structure, and a set of connecting portion locking nuts 114 is disposed on the threaded rod structure connecting portion 112, so that the connecting portion 112 and the transmission shaft 110 form a detachable structural design, and assembly and maintenance are utilized.

Example four

Based on the first embodiment, the second embodiment or the third embodiment, the automatic control device for polishing a motor rotor shaft preferably further includes a clamping groove 126 disposed in the pedestal plate 100 and located at the other side of the vertical support plate 102, a vertical support sliding plate 127 used in cooperation with the clamping groove 126, a support bearing clamping groove 124 disposed in one end of the vertical support sliding plate 127, and a motor rotor shaft support bearing 125 disposed in the support bearing clamping groove 124.

The motor rotor shaft support bearing 125 is sleeved on the non-polished part of the motor rotor shaft and is used for rotatably supporting the polished part of the motor rotor shaft.

EXAMPLE five

On the basis of the first embodiment or the second embodiment or the third embodiment or the fourth embodiment, the automatic control device for polishing the motor rotor shaft preferably further includes a rotation speed sensor mounting groove 128 disposed in an end surface of the transmission shaft 110, a rotation speed sensor 129 mounted in the rotation speed sensor mounting groove 128, and a PLC control module 130 used in cooperation with the rotation speed sensor 129.

The PLC control module 130 receives the rotation speed signal of the transmission shaft 110 fed back by the rotation speed sensor 129, and controls the step motor 101 to adjust the speed or controls the step motor 101 to rotate counterclockwise/clockwise.

The PLC control module 130 is connected with a rotation speed sensor 129 and the stepping motor 101, the rotation speed sensor 129 comprises but is not limited to CS-1 and G-100-05-01, and the PLC control module 130 comprises but is not limited to DVP02DA-E2 and 1756-IF16.

In addition, the fixing portion 113 in the above embodiments is configured to include, but not limited to, a circular plate structure, and the fixed clamping block 115 and the movable clamping block 117 are respectively configured to be a semicircular structure for cooperating with each other.

In addition, the slot 126 of the above embodiment is configured to include but not limited to a dovetail structure, and the part of the vertical support sliding plate 127 clamped in the slot 126 is configured to include but not limited to a dovetail structure; wherein the vertical support sliding plate 127 can slide horizontally in the slot 126 during assembly.

The invention discloses an application of a motor rotor shaft nickel plating polishing system, which is provided with an automatic control device for polishing a motor rotor shaft.

The working principle or the structural principle of the automatic control device for polishing the motor rotor shaft based on the structure is as follows:

(1) firstly, a non-polished part of a motor rotor shaft (a nickel-plated part is polished and ground in fig. 1) to be polished and ground is placed in a fixed clamping block 115, a movable clamping block 117 is clamped on the fixed clamping block 115, a fixed clamping block lug plate 116 and a movable clamping block lug plate 118 are locked by a locking bolt 121 and a locking bolt nut 122 through a fixed clamping block lug plate through hole 119 and a movable clamping block lug plate through hole 120, and the non-polished part of the motor rotor shaft is firmly positioned in a cavity formed by the movable clamping block 117 and the fixed clamping block 115;

(2) then, the motor rotor shaft support bearing 125 is clamped into the support bearing clamping groove 124, at this time, the vertical support sliding plate 127 is pushed to slide in the clamping groove 126 to be close to the non-polished part of the motor rotor shaft, and the non-polished part of the motor rotor shaft penetrates through the motor rotor shaft support bearing 125, so that the vertical support sliding plate 127 completes the support of the rotating motor rotor shaft to be polished and ground;

(3) finally, the step motor 101 is started through the PLC control module 130, the rotating step motor 101 is linked to the fixed clamping block 115 and the movable clamping block 117 through the transmission shaft 110, the connecting portion 112 and the fixing portion 113 to rotate synchronously, the rotating fixed clamping block 115 and the movable clamping block 117 drive the motor rotor shaft to rotate, and the motor rotor shaft is matched with the polishing component 123 to complete the rotary control polishing and grinding operation.

In addition, the PLC control module 130 receives the rotation speed signal of the transmission shaft 110 fed back by the rotation speed sensor 129 in real time, and controls the stepping motor 101 to adjust the speed or controls the stepping motor 101 to rotate counterclockwise/clockwise; meanwhile, the input rotation speed value can be preset in the PLC control module 130, so that automatic rotation control is realized.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (8)

1. Based on motor rotor axle polishing uses automated control device, including bedplate (100), perpendicular backup pad (102) and polishing part (123), its characterized in that:

a stepping motor (101) is arranged on one side of the vertical support plate (102) on the bench plate (100),

a driving chain wheel (103) is arranged on the stepping motor (101),

a bearing installation groove (105) is arranged in one end of the vertical support plate (102),

a bearing (106) is arranged in the bearing mounting groove (105),

a transmission shaft (110) penetrating through the bearing (106) is arranged in one end of the vertical support plate (102),

one end of the transmission shaft (110) is provided with a driven chain wheel (108),

the other end of the transmission shaft (110) is provided with a connecting part (112),

one end of the connecting part (112) is provided with a fixing part (113),

one surface of the fixing part (113) is provided with a fixed clamping block (115),

a movable clamping block (117) is arranged on the fixed clamping block (115),

the outer walls of the two sides of the fixed clamping block (115) and the movable clamping block (117) are respectively provided with a fixed clamping block lug plate (116) and a movable clamping block lug plate (118),

the fixed clamping block ear plate (116) and the movable clamping block ear plate (118) are respectively provided with a fixed clamping block ear plate through hole (119) and a movable clamping block ear plate through hole (120),

the fixed clamping block lug plate (116) and the movable clamping block lug plate (118) are connected through a fixed clamping block lug plate through hole (119) and a movable clamping block lug plate through hole (120) by using a locking bolt (121) and a locking bolt nut (122),

the driving chain wheel (103) and the driven chain wheel (108) are connected through a transmission chain (104);

the non-polishing end of the motor rotor shaft is placed in the opposite surface of the fixed clamping block (115) and the movable clamping block (117) for fixing, and the driven chain wheel (108) is driven by the stepping motor (101), the driving chain wheel (103) and the driving chain (104) to drive the transmission shaft (110) to be linked with the connecting part (112) and the fixing part (113) to synchronously rotate anticlockwise/clockwise.

2. The automated control device for motor rotor shaft polishing as claimed in claim 1, wherein: the automatic control device for polishing the motor-based rotor shaft further comprises a group of first nuts (107) and a group of second nuts (109), wherein the first nuts (107) and the group of second nuts are arranged on the transmission shaft (110) and used for locking and fixing the transmission shaft (110) and the driven chain wheel (108).

3. The automated control device for motor rotor shaft polishing as claimed in claim 2, wherein: the automatic control device for polishing the motor rotor shaft further comprises a spiral groove (111) arranged in the other end of the transmission shaft (110), and a connecting part (112) and the spiral groove (111) are rotationally connected;

the connecting part (112) is of a threaded rod structure, and a group of connecting part locking nuts (114) are arranged on the connecting part (112) of the threaded rod structure.

4. The automated control device for motor rotor shaft polishing as claimed in claim 3, wherein: the fixing part (113) is arranged to include but not limited to a circular plate type structure, and the fixed clamping block (115) and the movable clamping block (117) are respectively arranged to be in a semicircular structure matched with each other for use.

5. The automated control device for motor rotor shaft polishing as claimed in claim 4, wherein: the automatic control device for polishing the motor rotor shaft further comprises a clamping groove (126) which is arranged in the pedestal plate (100) and is positioned at the other side of the vertical support plate (102), a vertical support sliding plate (127) which is matched with the clamping groove (126) for use, a support bearing clamping groove (124) which is arranged in one end of the vertical support sliding plate (127), and a motor rotor shaft support bearing (125) which is arranged in the support bearing clamping groove (124);

the motor rotor shaft support bearing (125) is sleeved in the non-polishing part of the motor rotor shaft and used for rotatably supporting the polishing part of the motor rotor shaft.

6. The automated control device for motor rotor shaft polishing as claimed in claim 5, wherein: the clamping groove (126) is arranged to comprise but not limited to a dovetail structure, and the part of the vertical support sliding plate (127) clamped into the clamping groove (126) is arranged to comprise but not limited to a dovetail structure;

wherein, the vertical support sliding plate (127) can horizontally slide on the clamping groove (126) during assembly.

7. The automated control device for motor rotor shaft polishing as claimed in claim 5, wherein: the automatic control device for polishing the motor rotor shaft further comprises a rotating speed sensor mounting screw groove (128) arranged in the end face of one end of the transmission shaft (110), a rotating speed sensor (129) arranged in the rotating speed sensor mounting screw groove (128), and a PLC control module (130) matched with the rotating speed sensor (129) for use;

the PLC control module (130) receives a rotating speed signal of the transmission shaft (110) fed back by the rotating speed sensor (129), and controls the stepping motor (101) to regulate the speed or controls the stepping motor (101) to rotate anticlockwise/clockwise;

the PLC control module (130) is connected with a rotating speed sensor (129) and the stepping motor (101), the rotating speed sensor (129) comprises but is not limited to CS-1 and G-100-05-01, and the PLC control module (130) comprises but is not limited to DVP02DA-E2 and 1756-IF16.

8. The utility model provides a motor rotor shaft nickel plating polishing system which characterized in that: equipped with an automated control device for polishing of shafts based on electric motors rotors according to any of claims 1 to 7.

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