CN113949219A

CN113949219A - Combined type conductive device of motor shaft current protection structure

Info

Publication number: CN113949219A
Application number: CN202111080020.0A
Authority: CN
Inventors: 尤磊; 董小艳; 于冰; 王光晨; 张帅; 王丁
Original assignee: Zhejiang CRRC Shangchi Electric Co Ltd
Current assignee: Zhejiang Shangchi Electric Co.,Ltd.
Priority date: 2021-09-15
Filing date: 2021-09-15
Publication date: 2022-01-18
Anticipated expiration: 2041-09-15
Also published as: CN113949219B

Abstract

The invention discloses a combined type conductive device of a motor shaft current protection structure, which comprises a conductive body and conductive brushes, wherein the conductive body comprises a head part and a tail part, the head part extends into an inner hole, the tail part is positioned at the outer side, the conductive brushes are fixed with the head part, the head part is in a rod shape, the conductive brushes are provided with a plurality of conductive brushes, the conductive brushes are sequentially sleeved on the head part, and the end part of the head part is provided with a locking structure.

Description

Combined type conductive device of motor shaft current protection structure

Technical Field

The invention belongs to the technical field of motors, and particularly relates to a combined type conducting device of a motor shaft current protection structure.

Background

The electric corrosion caused by the shaft current is a common bearing fault of the variable frequency motor, and because of the factors of variable frequency power supply, motor manufacturing and the like, common mode current and differential mode current can be formed on the bearing when the motor runs. A method for reducing and inhibiting shaft current is characterized in that filtering is added on a variable frequency power supply side to reduce common mode voltage, a solving mode on a motor side is mainly started from two aspects of blocking and dredging, wherein the blocking mode adopts an insulating end cover, an insulating bearing and the like, and the dredging mode is that a shell is in short circuit with a rotating shaft by adding a carbon brush, a conducting ring, an auxiliary bearing, a conducting elastic sheet and the like near the bearing to form a conducting bypass with lower impedance, so that the shaft current is mainly released through the conducting bypass, and the shaft current is prevented from flowing through the bearing to cause electric corrosion.

In the application field of new energy automobile motors, factors such as product structures and cost are limited, an insulating end cover and an insulating bearing are rarely used, the installation space of the motor needs to be additionally considered by adopting a grounding carbon brush or a conducting ring, and the motor which is loaded is difficult to modify.

At present, in new energy automobile motor field, adopt the conducting ring treatment mode to the axle current problem many, the conducting ring is electrically conductive through the electrically conductive fibre of intra-annular fixed and pivot contact, compares with the ground connection carbon brush, and electrically conductive fibre has advantages such as electric conductivity is good, wear-resisting, non-maintaining, because the conducting ring is great, can need increase the inside installation space of motor and cost, and it is very inconvenient to the rectification of existing motor simultaneously.

The applicant has invented a current protection structure for a shaft of a variable frequency motor, in which the conductive device of which structure is adopted is the technical problem to be solved.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides the electric conductor and the conductive brush which can be produced independently and then assembled, and the quantity of the conductive fibers or the conductive brushes can be adjusted according to the power of the motor, so that the conductive contact area is adjusted, and the electric conductor and the conductive brush are very beneficial to platformization and serialization.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a combination formula electric installation of motor shaft current protective structure, includes the electric conductor and leads electric brush, the electric conductor includes head and afterbody, and the head stretches into to the hole in, and the afterbody is located the outside, it is fixed with the head to lead electric brush, the head is shaft-like, it is provided with a plurality of to lead electric brush, and a plurality of leads electric brush and overlaps in proper order on the head, and the tip of head is provided with locking structure.

And a threaded blind hole is formed in the tail part of the conductor.

The conductive brush further comprises a copper ring and conductive fibers, one end of each conductive fiber is fixed in the copper ring, the other end of each conductive fiber extends out of the copper ring, and the copper ring is sleeved on the head.

The conductive brush further comprises two copper sheets and conductive fibers, the conductive fibers are located between the two copper sheets, and locking screws are arranged between the two copper sheets.

The conductive brush further comprises two copper sheets and conductive fibers, wherein the copper sheets are provided with grooves which are radially arranged, the conductive fibers are positioned in the grooves, and a locking screw is arranged between the two copper sheets.

Further electrically conductive brush includes fixing base, clamp plate and conductive fiber, and the fixing base includes fixed plate, star post and compression leg, one side of star post and compression leg all is fixed with the fixed plate, and the compression leg is located the star inslot of star post, leaves installation space between compression leg and the star groove, and the length of compression leg is greater than the length of star post, and conductive fiber's centre is located the star inslot, and conductive fiber's both ends are stretched out by the star groove, set up the design hole that supplies the compression leg to pass on the clamp plate, the front end of compression leg is passed behind the design hole riveting fixed pressing plate.

And a counter bore is formed in the position, corresponding to the shaping hole, of the further pressing plate and used for accommodating the riveted end of the pressing column.

The star-shaped groove is V-shaped or U-shaped corresponding to the groove formed between the pressing column and the star-shaped column.

Further, the outer side surfaces of the star-shaped column and the pressure column are flush with the maximum outer circular surface of the fixing plate, a step is arranged at the front end of the pressure column, and the outer side surface of the front end of the pressure column is not flush with the maximum outer circular surface of the fixing plate.

The inner side of the star-shaped groove is provided with a non-slip edge extending along the radial direction.

Compared with the prior art, the invention has the beneficial effects that: the conductive device specially designed by the conductive fibers can be adjusted according to the size of the motor and the quantity of the conductive fibers or the conductive brushes according to the power of the motor, so that the conductive contact area is adjusted, the platformization and the serialization are greatly facilitated, and the conductive bodies and the conductive brushes of the conductive device can be independently produced and then assembled.

Drawings

FIG. 1 is a schematic structural diagram of a current protection structure of a shaft of a variable frequency motor;

FIG. 2 is a partial side view of the cover plate;

FIG. 3 is a partial cross-sectional view of the cover plate;

FIG. 4 is a cross-sectional view of a conductive device;

FIG. 5 is a side view of a tail portion of an electrical conductor;

FIG. 6 is a cross-sectional view of an electrical conductor;

FIG. 7 is a side view of a first construction of a conductive brush;

FIG. 8 is a perspective view of a copper ring;

FIG. 9 is a schematic view of one embodiment of a locking structure for an electrical conductor;

FIG. 10 is a schematic view of another embodiment of a locking arrangement for an electrical conductor;

FIG. 11 is a schematic view of one embodiment of the electrical conductor secured to the cover;

FIG. 12 is a cross-sectional view of a second construction of a conductive brush;

FIG. 13 is a side view of a second construction of a conductive brush;

FIG. 14 is a perspective view of a third configuration of a conductive brush;

FIG. 15 is a perspective view of a copper sheet in a third configuration of a conductive brush;

FIG. 16 is a cross-sectional view of a fourth construction of a conductive brush;

FIG. 17 is a perspective view of a fixing base in a fourth configuration of the conductive brush;

FIG. 18 is a perspective view of a press plate in a fourth configuration of the brush;

FIG. 19 is a cross-sectional view of a fifth construction of a conductive brush;

FIG. 20 is a perspective view of a fixing base in a fifth structure of a conductive brush.

Reference numerals: 1. a rotating shaft; 11. an inner bore; 2. a conductive device; 21. an electrical conductor; 211. mounting a platform; 212. a through hole; 213. a tail portion; 214. a ring groove; 215. a head portion; 216. a threaded segment; 217. a threaded blind hole; 22. a seal ring; 23. a conductive brush; 231. a copper ring; 232. a conductive fiber; 2321. an outer contour; 233. a copper sheet; 234. locking the screw; 235. a groove; 2361. pressing the column; 2362. a star-shaped slot; 2363. the front end of the compression leg; 2364. a fixing plate; 2365. a star-shaped column; 237. pressing a plate; 2371. shaping holes; 2373. a counter bore; 24. a hexagonal flange face nut; 3. a cover plate; 31. mounting a boss; 32. mounting holes; 33. a threaded hole; 4. and (4) end covers.

Detailed Description

Embodiments of the present invention are further described with reference to fig. 1 to 20.

In the description of the present invention, it should be noted that, for the terms of orientation, such as "central", "lateral (X)", "longitudinal (Y)", "vertical (Z)", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc., indicate that the orientation and positional relationship are based on the orientation or positional relationship shown in the drawings, and are only for the convenience of describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and should not be construed as limiting the specific scope of the present invention.

Furthermore, if the terms "first" and "second" are used for descriptive purposes only, they are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. Thus, a definition of "a first" or "a second" feature may explicitly or implicitly include one or more of the features, and in the description of the invention, "a number" or "a number" means two or more unless explicitly specified otherwise.

The utility model provides a frequency conversion motor shaft current protective structure, includes pivot 1 and end cover 4, still includes:

the inner hole 11 is arranged on the rotating shaft 1 and is formed by extending the end part of the rotating shaft 1 inwards along the axial direction;

the conductive device 2 comprises a conductive body 21 and a conductive brush 23, wherein the conductive body 21 comprises a head part 215 and a tail part 213, the head part 215 extends into the inner hole 11, the tail part 213 is positioned at the outer side, the conductive brush 23 is fixed with the head part 215, the conductive brush 23 contacts the inner wall of the inner hole 11, and the tail part 213 is connected with the end cover 4;

the rotating shaft 1 and the end cover 4 are connected and conducted through the conducting device 2 to form a loop.

Usually, the opening of the end cap 4 is large, in this embodiment, a conductive cover plate 3 is fixed on the end cap 4, and the tail 213 of the conductive device 2 is fixed with the cover plate 3, that is, the rotating shaft 1 and the end cap 4 are connected and conducted through the conductive device 2 and the cover plate 3 to form a loop, the impedance of the loop is far smaller than the impedance of the bearing oil film, when there is a shaft voltage on the inner side and the outer side of the bearing oil film, the release of the shaft current is performed through the loop, thereby protecting the bearing from the corrosion of the shaft current.

Typically, the head 215 of the conductive device 2 extends into the bore 11 a length less than the depth of the bore 11.

As shown in fig. 3, in the present embodiment, preferably, the cover plate 3 is provided with a mounting boss 31, the mounting boss 31 is provided with a mounting hole 32 for the conductor 21 to pass through, the tail portion 213 of the conductor 21 is provided with a mounting platform 211, a plane of the mounting boss 31 is attached to the mounting platform 211 of the tail portion 213 to form a conductive surface, and the conductive surface is used for conducting the conductor 21 and the cover plate 3.

Usually, the mounting hole 32 is a circular inner hole 11, and the tail portion 213 of the conductor 21 is cylindrical corresponding to this, but the mounting hole 32 and the conductor 21 may have other shapes as long as they are attached to each other, and in the following embodiment, the mounting hole 32 is circular, and the conductor 21 is cylindrical, and the mounting hole 32 and the conductor 21 are mounted with a small gap therebetween.

In one embodiment, the mounting platform 211 of the conductor 21 is connected to the mounting boss 31 of the cover plate 3 by bolts, specifically, as shown in fig. 2 and 5, two or more threaded holes 33, which may be through holes 212 or blind holes, may be provided on the cover plate 3, and the through holes 212 are provided at the mounting platform 211 of the conductor 21, and the conductor 21 is fixed to the cover plate 3 by bolts sequentially passing through the mounting platform 211 of the conductor 21 and the threaded holes 33 of the cover plate 3; in this embodiment, the sealing ring 22 is disposed between the cylindrical surface of the conductive body 21 and the installation hole 32, specifically, the cylindrical surface of the conductive body 21 is disposed with the annular groove 214, and the sealing ring 22 is disposed in the annular groove 214.

In another embodiment, the conductive body 21 is screwed into the mounting hole 32 of the mounting boss 31, specifically, as shown in fig. 11, in this embodiment, the mounting hole 32 has an internal thread, and the cylindrical surface of the conductive body 21 has an external thread, and the two are fixedly connected by a screw thread, preferably, the mounting platform 211 of the conductive body 21 is polygonal, so as to screw the conductive body 21 by using a tool; in this embodiment, a seal ring 22 is provided between the mounting platform 211 of the conductor 21 and the mounting boss 31 of the cover plate 3.

The head 215 is in a rod shape in this embodiment, the conductive brush 23 is sleeved on the head 215, and the end of the head 215 is provided with a locking structure.

In the present invention, the head 215 may be cylindrical or polygonal, and the shape of the conductive brush 23 is matched with that of the head 215, so that the conductive brush 23 can be stably sleeved on the head 215, and in the following embodiment, the head 215 is cylindrical, that is, a cylindrical section is formed here, and a circular hole is formed in the middle of the conductive brush 23.

The electric conduction brushes 23 are provided with a plurality of electric conduction brushes 23, the plurality of electric conduction brushes 23 are sequentially sleeved on the head part 215 along the axial direction, the size of the electric conduction device 2 can be selected according to the size of the motor, meanwhile, the length of the head part 215 in the electric conduction body 21 and the number of the electric conduction brushes 23 can be adjusted according to different power of the motor, so that the contact area between the electric conduction brushes 23 and the inner wall of the inner hole 11 of the rotating shaft 1 is increased, and the electric conduction body 21 is made of aluminum or tin-plated copper materials.

In one embodiment, the locking structure is as shown in fig. 4 and fig. 6, the end of the head 215 of the electric conductor 21 is provided with a threaded section 216, the threaded section 216 is provided with a hexagonal flange nut 24 for locking, at this time, the thickness of all the conductive brushes 23 is slightly greater than the length of the cylindrical section of the head 215 of the electric conductor 21, the total thickness of the conductive brushes 23 is usually 0.2-1mm greater than the length of the cylindrical section of the head 215 of the electric conductor 21, it should be noted that the length of the threaded section 216 of the head 215 of the electric conductor 21 does not account for the length of the cylindrical section, when assembling is performed, all the conductive brushes 23 are sequentially sleeved on the cylindrical section, and then are screwed and fixed with the threaded section 216 of the electric conductor 21 through the hexagonal flange nut 24.

In another embodiment, the locking structure is shown in fig. 9, in which the head 215 of the conductive body 21 has no threaded section 216, but has a hollow hole at its end, and when all the conductive brushes 23 are fixed, the end of the head 215 of the conductive body 21 is flanged outwards by means of interference riveting to fix the conductive brushes 23, i.e. the process from a1 to a2 in fig. 9.

In another embodiment, the locking structure is shown in fig. 10, where the head 215 of the conductive body 21 has no threaded segment 216, and all the conductive brushes 23 are fixed at its end by means of cross-section rivets, i.e., the process from B1 to B2 in fig. 10.

Referring to fig. 7 and 8, a first structure of the conductive brush 23 according to the present invention is shown, in which the conductive brush 23 includes a copper ring 231 and conductive fibers 232, one end of the conductive fibers 232 is fixed in the copper ring 231, and the other end extends out of the copper ring 231, and the copper ring 231 is sleeved on the head 215.

Specifically, the copper ring 231 is cylindrical, fig. 8 is an initial structural state of the copper ring 231, the conductive fibers 232 are fully filled in the copper ring 231, the extension lengths of two ends are controlled to be approximately the same, a compression joint device (such as a press) is adopted to press and compress the preformed plane of the copper ring 231, all the conductive fibers 232 are compressed and fixed in the copper ring 231, then a hole 2311 of the copper ring 231 is processed, the hole of the copper ring 231 is in small transition fit with the cylindrical section of the head 215 of the conductor 21, the outer contour of the conductive fibers 232 is trimmed by a tool, the arc diameter 2312 of the outer contour of the conductive fibers 232 is larger than the inner hole 11 of the rotating shaft 1 by 1-3mm, and the conductive brush 23 is manufactured; the maximum arc diameter of the copper ring 231 after the press-fitting molding is preferably 2-4mm smaller than the inner hole 11 of the rotating shaft 1.

As shown in fig. 12 and 13, which shows a second structure of the conductive brush 23 of the present invention, in this structure, the conductive brush 23 in this embodiment includes two copper sheets 233 and conductive fibers 232, the conductive fibers 232 are located between the two copper sheets 233, and a locking screw 234 is provided between the two copper sheets 233, that is, the two copper sheets 233 are fixed by the locking screw 234, and the conductive fibers 232 are clamped and fixed between the two copper sheets 233.

Wherein the locking screw 234 is preferably a pop rivet such that its end does not protrude to the outside of the copper plate 233.

As shown in fig. 14 and 15, which illustrate a third structure of the conductive brush 23 according to the present invention, in this structure, the conductive brush 23 includes two copper sheets 233 and conductive fibers 232, the copper sheets 233 are provided with radially arranged grooves 235, the conductive fibers 232 are located in the grooves 235, locking screws 234 are provided between the two copper sheets 233, the two copper sheets 233 are locked by the locking screws 234, and the conductive fibers 232 are fixed in the grooves 235, preferably, four grooves 235 are provided and uniformly distributed along the circumference, and at this time, the locking screws 234 may be solid rivets, and the ends of the solid rivets do not protrude from the grooves 235.

As shown in fig. 16, 17 and 18, a fourth structure of the conductive brush 23 of the present invention is shown, in this structure, the conductive brush 23 includes a fixing base, a pressing plate 237 and conductive fibers 232, the fixing base includes a fixing plate 2364, a star-shaped column 2365 and a pressing column 2361, one side of the star-shaped column 2365 and one side of the pressing column 2361 are both fixed to the fixing plate 2364, the pressing column 2361 is located in a star-shaped groove 2362 of the star-shaped column 2365, a mounting space is left between the pressing column 2361 and the star-shaped groove 2362, the length of the pressing column 2361 is greater than that of the star-shaped column 2365, the middle of the conductive fibers 232 is located in the star-shaped groove 2362, two ends of the conductive fibers 232 are extended from the star-shaped groove 2362, a shaping hole 2371 for the pressing column 2361 to pass through is provided on the pressing plate 237, and the end of the pressing column 2361 is riveted to the fixing plate 237 after passing through the shaping hole 2371.

Pressure plate 237 has the same outer diameter as fixed plate 2364.

Counterbore 2373 is preferably provided in press plate 237 corresponding to shaped hole 2371. counterbore 2373 is used to receive the riveted end of press stud 2361.

The preferred star-shaped groove 2362 is V-shaped or U-shaped corresponding to the groove formed between the compression leg 2361 and the star-shaped leg 2365.

The cross section of the preferred compression leg 2361 is triangular, and the shaped hole 2371 is a triangular hole.

The preferred compression leg 2361 has a radially extending non-slip edge on the inner side of the star 2362.

Referring to fig. 19 and 20, a fifth structure of the electric brush 23 according to the present invention is shown, which is modified from the fourth structure of the electric brush 23, and the pressing plate 237 is the same as that shown in fig. 18, in this structure, the outer side surfaces of the star-shaped columns 2365 and the pressing columns 2361 are flush with the maximum outer circumferential surface of the fixing plate 2364, and a step is provided at the front end 2363 of the pressing column, i.e., the end of the pressing column 2361 facing the pressing plate 237, so that the outer side surface of the front end 2363 of the pressing column is not flush with the maximum outer circumferential surface of the fixing plate 2364, and can smoothly penetrate into the shaping hole 2371 of the pressing plate 237.

Like this conductive fiber 232 is after fixed, and when it contacted with the hole 11 of pivot 1, conductive fiber 232 kick-backs more easily, can not be unfavorable for the electrically conductive effect of resilience because of length overlength.

The fourth and fifth structures of the conductive brush 23 according to the present invention are mounted by placing the conductive fibers 232 in all the star-shaped grooves 2362 in sequence, and extending both ends of the conductive fibers to the outside of the star-shaped grooves 2362, then fixing the conductive fibers with the pressing plate 237, making the front ends 2363 of all the pressing columns pass through the shaping holes 2371 of the pressing plate 237, pressing the conductive fibers 232 in the star-shaped grooves 2362 with the pressing plate 237, pressing and riveting the front ends 2363 of the pressing columns on the pressing plate 237 with a press or other tools, and filling the counter bores 2373 with the front ends 2363 of the pressed and riveted pressing columns.

In the invention, the tail part 213 of the electric conductor 21 is provided with the threaded blind hole 217, the threaded blind hole 217 is formed by extending the end part of the tail part 213 of the electric conductor 21 inwards, so that the electric conduction device 2 can be conveniently pulled out when being detached, namely, when the electric conduction device 2 is detached, a tool with a screw rod can be screwed into the threaded blind hole 217 to pull out the whole electric conduction device 2, and meanwhile, the threaded blind hole 217 is used for installing a grounding wire, thereby being more beneficial to releasing shaft current and protecting a bearing.

The above description is only a preferred embodiment of the present invention, and the protection scope of the present invention is not limited to the above embodiments, and all technical solutions belonging to the idea of the present invention belong to the protection scope of the present invention. It should be noted that modifications and embellishments within the scope of the invention may occur to those skilled in the art without departing from the principle of the invention, and are considered to be within the scope of the invention.

Claims

1. The utility model provides a combination formula electric installation of motor shaft current protective structure which characterized in that: including electric conductor and electrically conductive brush, the electric conductor includes head and afterbody, and the head stretches into to the hole in, and the afterbody is located the outside, it is fixed with the head to electrically conductive brush, the head is shaft-like, electrically conductive brush is provided with a plurality of, and a plurality of electrically conductive brush overlaps in proper order on the head, and the tip of head is provided with locking structure.

2. The combined conducting device of the current protective structure for the motor shaft of claim 1, wherein: and the tail part of the conductor is provided with a threaded blind hole.

3. The combined conducting device of the current protection structure of the motor shaft according to claim 2, wherein: the conductive brush comprises a copper ring and conductive fibers, one end of each conductive fiber is fixed in the copper ring, the other end of each conductive fiber extends out of the copper ring, and the copper ring is sleeved on the head.

4. The combined conducting device of the current protective structure for the motor shaft of claim 3, wherein: the conductive brush comprises two copper sheets and conductive fibers, the conductive fibers are located between the two copper sheets, and locking screws are arranged between the two copper sheets.

5. The combined conducting device of the current protective structure for the motor shaft of claim 3, wherein: the conductive brush comprises two copper sheets and conductive fibers, wherein grooves are radially arranged on the copper sheets, the conductive fibers are located in the grooves, and locking screws are arranged between the two copper sheets.

6. The combined conducting device of the current protective structure for the motor shaft of claim 4, wherein: the conductive brush comprises a fixing seat, a pressing plate and conductive fibers, the fixing seat comprises a fixing plate, a star-shaped column and a pressing column, one side of the star-shaped column and one side of the pressing column are fixed on the fixing plate, the pressing column is located in a star-shaped groove of the star-shaped column, an installation space is reserved between the pressing column and the star-shaped groove, the length of the pressing column is larger than that of the star-shaped column, the middle of the conductive fibers is located in the star-shaped groove, two ends of the conductive fibers are extended out of the star-shaped groove, a shaping hole for the pressing column to penetrate through is formed in the pressing plate, and the front end of the pressing column penetrates through the shaping hole and then is riveted with the fixing plate.

7. The combined conducting device of the current protective structure for the motor shaft of claim 6, wherein: the press plate is provided with a counter bore corresponding to the shaping hole, and the counter bore is used for accommodating the end part of the pressure column which is riveted.

8. The combined conducting device of the current protective structure for the motor shaft of claim 7, wherein: the star-shaped groove is V-shaped or U-shaped corresponding to the groove formed between the pressing column and the star-shaped column.

9. The combined conducting device of the motor shaft current protecting structure of claim 8, wherein: the outer side surfaces of the star-shaped columns and the pressure columns are flush with the maximum outer circular surface of the fixing plate, steps are arranged at the front ends of the pressure columns, and the outer side surface of the front ends of the pressure columns is not flush with the maximum outer circular surface of the fixing plate.

10. The combined conducting device of the current protective structure for the motor shaft of claim 9, wherein: the inner side surface of the compression leg facing the star-shaped groove is provided with an anti-slip edge extending along the radial direction.