CN212793224U - Air condition compressor stator processing equipment with skew correction structure - Google Patents

Abstract

The invention discloses an air conditioner compressor stator processing device with a deflection correcting structure, which comprises a device main body and a milling cutter, wherein a foot rest is arranged at the front side of the device main body, the top of the device main body is provided with a slide rail, the top of the slide rail is provided with a U-shaped slide block, the top of the U-shaped slide block is provided with a clamping mechanism, the rear side of the bottom of the clamping mechanism is connected with a slide block, the bottom of the sliding block is provided with a sliding groove, the front side of the top of the device main body is provided with a bracket, and the top of the bracket is provided with a fixed frame, the device has a structure capable of adjusting the front and back positions at one position through the arrangement of the screw rod, and simultaneously, the milling cutter mechanism is convenient to control, because the concave rail is embedded in the surface of the rotating shaft, and the annular frame is embedded in the concave rail, when the rotating shaft rotates, the concave rail and the annular frame can be driven to rotate, and the front position and the rear position of the milling cutter mechanism are indirectly moved.

Description

Air condition compressor stator processing equipment with skew correction structure

Technical Field

The invention relates to the technical field of stator processing, in particular to air-conditioning compressor stator processing equipment with a deflection correcting structure.

Background

The compressor stator is an important component of the air conditioner compressor, the stator consists of a stator core, a stator winding and a machine base, the stator mainly functions to generate a rotating magnetic field, and the rotor mainly functions to be cut by magnetic lines of force in the rotating magnetic field to generate (output) current.

Most traditional compressor stator is by aluminium system material through high temperature processing, forms appointed structure and polish the shaping in the fixed grinding apparatus of inversion, and such processing method time is longer, and has potential risk to the staff, and some compressor stators are then polished or milling machine processing by the raw materials, but because the imperfection of centre gripping equipment, there is the phenomenon of error disappearance to the processing of this type of precision part, and then cause the stator to have size difference.

Disclosure of Invention

The invention aims to provide air conditioner compressor stator processing equipment with a deflection correction structure, which aims to solve the problem that the traditional compressor stator proposed in the background art is mostly made of aluminum materials through high-temperature processing, a specified structure is formed in an inverted fixed grinding tool and is ground and formed, the processing mode is long in time and has potential risks for workers, and part of the compressor stator is ground by raw materials or processed by a milling machine, but due to the fact that clamping equipment is not complete, the phenomenon of error loss exists in the processing of parts with the precision, and further the stator has size difference.

In order to achieve the purpose, the invention provides the following technical scheme: an air conditioner compressor stator processing device with a deflection correction structure comprises a device main body and a milling cutter, wherein a foot rest is arranged on the front side of the device main body, a slide rail is arranged at the top of the device main body, a U-shaped slide block is arranged at the top of the slide rail, a clamping mechanism is arranged at the top of the U-shaped slide block, a slide block is connected to the rear side of the bottom of the clamping mechanism, a slide groove is formed in the bottom of the slide block, a support is arranged on the front side of the top of the device main body, a fixed frame is arranged at the top of the support, a lead screw is arranged inside the fixed frame, a first motor is arranged on the front side of the fixed frame, a milling cutter mechanism is arranged on the right side of the fixed frame, a bar-shaped frame is arranged at the top of the milling cutter mechanism, a second motor is arranged inside, the bottom of the sliding frame is provided with a milling cutter, the bottom of the clamping mechanism is provided with a sliding plate, the right side of the top of the sliding plate is provided with a telescopic rod, an annular fixing frame is arranged around the telescopic rod, the left side of the first motor is provided with a connecting shaft, the left side of the connecting shaft is connected with a moving strip, a driving shaft penetrates through the moving strip, the top of the driving shaft is connected with a connecting plate, a driven shaft penetrates through the left side of the connecting plate, the bottom of the driven shaft is provided with a sliding strip, the bottom of the sliding strip is provided with a bottom sliding groove, the front side of the sliding strip is provided with a fixing ring, the left side of the screw rod is provided with a rotating shaft, a concave rail is arranged on the surface of the rotating shaft, an annular frame is embedded into the concave rail, the right side of the annular frame is provided with a connecting plate, the top of the milling cutter is provided with a top, the bottom of apical axis is connected with the embedding piece, and the bottom of embedding piece is provided with rotates the post, the top of rotating the post is provided with the go-between, and rotates the top inboard of post and be provided with the recess, the bottom of rotating the post is provided with the edge of a knife.

Preferably, the device main body and the slide rail are of an embedded structure, the slide rail and the U-shaped slide block are of an embedded structure, and the slide rail and the U-shaped slide block are of a slidable structure.

Preferably, the telescopic link is telescopic structure, and the flexible length of telescopic link is half of the sliding plate width, remove the strip and pass through linking axle with the telescopic link, and link up the axle and be sliding structure with removing the strip.

Preferably, remove the strip and be through connection structure with the linkage plate through the driving shaft, and remove strip, linkage plate and driving shaft and be rotating-structure, the linkage plate is through connection structure with the slip strip through the driven shaft, and linkage plate, slip strip and driven shaft are rotating-structure, end spout is sliding structure with the slip strip.

Preferably, the spout sets up two sets ofly altogether, and two sets of spouts are parallel mechanism, the slider is embedded structure with the spout, and slider and spout are sliding structure.

Preferably, the support sets up two sets ofly altogether, and two sets of supports are the axisymmetrical structure, the support is vertical structure with fixed frame.

Preferably, the concave rail and the rotating shaft are in an embedded structure, the concave rail and the rotating shaft are in a surrounding structure, the annular frame and the concave rail are in an embedded structure, and the annular frame and the rotating shaft are in a rotating structure.

Preferably, the sliding frame and the carrying frame are in a penetrating structure, and the sliding frame and the carrying frame are in a sliding structure.

Preferably, the embedding block and the groove are of an embedded structure, the embedding block and the inner wall of the groove are of a complete laminating structure, the connecting ring and the connecting ring are of an internally tangent structure, and the connecting ring are of a complete laminating structure.

Compared with the prior art, the invention has the following beneficial effects:

1. the device is provided with a movable structure capable of being adjusted at one position through the arrangement of the sliding rail and the sliding groove, the stability of the U-shaped sliding block can be ensured through the embedded structure of the sliding rail and the U-shaped sliding block, and meanwhile, the embedded structure of the sliding block and the sliding groove can perform a synergistic sliding action with the U-shaped sliding block, so that the clamping mechanism is driven to perform corresponding displacement, and later-period operation is facilitated.

2. The invention has a structure capable of adjusting the front and back positions on the device through the arrangement of the screw rod, and simultaneously facilitates the control of the milling cutter mechanism.

3. The milling cutter has the advantages that the milling cutter is arranged, so that the device has good steering capacity during operation, the embedded structure of the embedded block and the groove and the state that the embedded block is completely attached to the inner wall of the groove can ensure that the top shaft can completely transmit the rotating force to the bottom, and the internally tangent structure of the connecting ring and the connecting ring can ensure the integrity of the milling cutter and the integral firmness during operation.

4. The milling cutter comprises a bearing frame, a sliding frame, a bearing frame, a rectangular frame and a connecting piece, wherein the sliding frame is arranged on the bearing frame, the bearing frame is arranged on the sliding frame, the sliding frame is arranged on the bearing frame.

5. According to the invention, through the arrangement of the clamping mechanism, a structure capable of stably clamping the raw materials exists on the device, the telescopic rod operates to drive the connecting shaft and the moving strip to perform sliding operation, the moving strip and the connecting plate are connected through the through connection of the driving shaft, so that the connecting plate and the driving shaft can rotate, meanwhile, the connecting plate and the sliding strip are connected through the driven shaft, and the sliding strip and the bottom sliding groove are in an embedded structure, so that the sliding strip can reciprocate to drive the fixing ring to perform fixing operation on the raw materials.

Drawings

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

FIG. 2 is a schematic view of a clamping mechanism according to the present invention;

FIG. 3 is a schematic view of a lead screw structure according to the present invention;

FIG. 4 is a schematic view of the milling cutter mechanism of the present invention;

fig. 5 is a schematic view of the milling cutter structure of the present invention.

In the figure: 1. a device main body; 2. a foot rest; 3. a slide rail; 4. a U-shaped slider; 5. a clamping mechanism; 501. a sliding plate; 502. a telescopic rod; 503. an annular fixing frame; 504. a connecting shaft; 505. a moving bar; 506. a drive shaft; 507. a connector tile; 508. a driven shaft; 509. a bottom chute; 510. a slide bar; 511. a fixing ring; 6. a slider; 7. a chute; 8. a support; 9. a fixing frame; 10. a screw rod; 1001. a rotating shaft; 1002. a concave rail; 1003. an annular frame; 1004. a connecting plate; 11. a first motor; 12. a milling cutter mechanism; 13. a bar frame; 14. a second motor; 15. a sliding frame; 16. a bearing frame; 17. milling cutters; 1701. a top shaft; 1702. an adaptor ring; 1703. embedding a block; 1704. a groove; 1705. a connecting ring; 1706. rotating the column; 1707. knife edge.

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 embodiments, and all other embodiments obtained by a person of ordinary skill in the art without creative efforts based on the embodiments of the present invention belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: an air conditioner compressor stator processing device with a deflection correction structure comprises a device main body 1 and a milling cutter 17, wherein a foot rest 2 is arranged on the front side of the device main body 1, a slide rail 3 is arranged on the top of the device main body 1, the device main body 1 and the slide rail 3 are of an embedded structure, the slide rail 3 and a U-shaped slide block 4 are of an embedded structure, the slide rail 3 and the U-shaped slide block 4 are of a slidable structure, a clamping mechanism 5 is fixed on the top of the U-shaped slide block 4 and can perform cooperative sliding operation, the top of the slide rail 3 is provided with the U-shaped slide block 4, the top of the U-shaped slide block 4 is provided with the clamping mechanism 5, the rear side of the bottom of the clamping mechanism 5 is connected with a slide block 6, the bottom of the slide block 6 is provided with slide grooves 7, the slide grooves 7 are arranged in two groups, the two groups of slide grooves 7 are parallel mechanisms, the slide block, the front side of the top of the device main body 1 is provided with a bracket 8, the top of the bracket 8 is provided with a fixed frame 9, the brackets 8 are arranged in two groups, the two groups of brackets 8 are in an axisymmetric structure, the bracket 8 and the fixed frame 9 are in a vertical structure to provide horizontal supporting force for the fixed frame 9 and ensure the level of the fixed frame 9, a screw rod 10 is arranged in the fixed frame 9, the front side of the fixed frame 9 is provided with a first motor 11, the right side of the fixed frame 9 is provided with a milling cutter mechanism 12, the top of the milling cutter mechanism 12 is provided with a strip-shaped frame 13, the inside of the strip-shaped frame 13 is provided with a second motor 14, the bottom of the second motor 14 is connected with a sliding frame 15, the periphery of the sliding frame 15 is provided with a bearing frame 16, the sliding frame 15 and the bearing frame 16 are in a penetrating structure, the sliding frame 15 and the bearing frame 16 are in a sliding structure, the sliding frame, meanwhile, the sliding frame 15 is internally provided with a rectangular frame shape which has a certain fixing effect on the sliding operation and ensures the stability of the operation of the milling cutter 17, the milling cutter 17 is arranged at the bottom of the sliding frame 15, the sliding plate 501 is arranged at the bottom of the clamping mechanism 5, the telescopic rod 502 is arranged at the right side of the top of the sliding plate 501, the annular fixing frame 503 is surrounded around the telescopic rod 502, the left side of the telescopic rod 502 is provided with a connecting shaft 504, the left side of the connecting shaft 504 is connected with a moving bar 505, a driving shaft 506 penetrates through the inside of the moving bar 505, the telescopic rod 502 is in a telescopic structure, the telescopic length of the telescopic rod 502 is half of the width of the sliding plate 501, the moving bar 505 is connected with the telescopic rod 502 through the connecting shaft 504, the connecting shaft 504 and the moving bar 505 are in a sliding structure, the telescopic rod 502 drives the connecting shaft 504 and the moving bar 505 to perform the, a driven shaft 508 penetrates through the inside of the left side of the connecting plate 507, a sliding bar 510 is arranged at the bottom of the driven shaft 508, a bottom sliding groove 509 is arranged at the bottom of the sliding bar 510, a fixing ring 511 is arranged at the front side of the sliding bar 510, the moving bar 505 and the connecting plate 507 are in a through connection structure through the driving shaft 506, the moving bar 505, the connecting plate 507 and the driving shaft 506 are in a rotating structure, the connecting plate 507 and the sliding bar 510 are in a through connection structure through the driven shaft 508, the connecting plate 507, the sliding bar 510 and the driven shaft 508 are in a rotating structure, the bottom sliding groove 509 and the sliding bar 510 are in a sliding structure, the connecting plate 507 and the driving shaft 506 can rotate due to the through connection effect of the moving bar 505 and the connecting plate 507 through the driving shaft 506, the connecting plate 507 and the sliding bar 510 are in a through connection through the driven shaft 508, and the sliding bar 510 and the bottom sliding groove 509 are, the fixed ring 511 is driven to fix the raw material, the left side of the screw rod 10 is provided with a rotating shaft 1001, the surface of the rotating shaft 1001 is provided with a concave rail 1002, an annular frame 1003 is embedded in the concave rail 1002, the right side of the annular frame 1003 is provided with a connecting plate 1004, the concave rail 1002 and the rotating shaft 1001 are in an embedded structure, the concave rail 1002 and the rotating shaft 1001 are in a surrounding structure, the annular frame 1003 and the concave rail 1002 are in an embedded structure, the annular frame 1003 and the rotating shaft 1001 are in a rotating structure, the concave rail 1002 is embedded in the surface of the rotating shaft, the annular frame 1003 is embedded in the concave rail 1002, the rotating shaft 1001 can drive the concave rail 1002 and the annular frame to rotate when rotating, so as to indirectly move the front and back positions of the milling cutter mechanism 12, the top of the milling cutter 17 is provided with a top shaft 1701, the bottom of the top shaft 1701 is surrounded with a connecting ring 1702, the bottom of the top shaft 1701 is connected with an embedding block 1703, the top of the rotation column 1706 is provided with a connecting ring 1705, the inner side of the top of the rotation column 1706 is provided with a groove 1704, the bottom of the rotation column 1706 is provided with a knife edge 1707, the embedded block 1703 and the groove 1704 are in an embedded structure, the embedded block 1703 and the inner wall of the groove 1704 are in a completely attached structure, the connecting ring 1702 and the connecting ring 1705 are in an internally attached structure, the connecting ring 1702 and the connecting ring 1705 are in a completely attached structure, the embedded block 1703 and the groove 1704 are in an embedded structure, and the embedded block 1703 and the inner wall of the groove 1704 are in a completely attached state, so that the rotation force of the top shaft 1701 can be completely transmitted to the bottom, the internally attached structure of the connecting ring 1702 and the connecting ring 1705 can ensure the integrity of the milling cutter 17, and.

The working principle is as follows: for this kind of stator processing equipment, firstly, the ring-shaped raw material is placed on the clamping mechanism 5, the telescopic rod 502 performs the telescopic operation to drive the connecting shaft 504 and the moving bar 505 to perform the sliding operation, since the moving bar 505 and the connecting plate 507 are in the through connection structure through the driving shaft 506, the telescopic operation of the telescopic rod 502 can drive the moving bar 505, the driving shaft 506 and the connecting plate 507 to perform the cooperative rotation operation, similarly, the connecting plate 507 and the sliding bar 510 are in the through connection structure through the driven shaft 508, the connecting plate 507 rotates and simultaneously drives the sliding bar 510 to move, since the bottom of the sliding bar 510 is embedded in the bottom sliding groove 509, the sliding bar 510 performs the reciprocating motion, thereby driving the fixing ring 511 to fix the raw material, after the raw material is fixed, the clamping mechanism 5 is pushed, under the cooperative action of the sliding rail 3 and the sliding groove 7, the clamping mechanism 5 is moved to the bottom of the milling cutter mechanism 12, the first motor 11 is turned on, the first motor 11 drives the rotating shaft 1001 to rotate, the concave rail 1002 is embedded in the surface of the rotating shaft 1001, the annular rack 1003 is embedded in the concave rail 1002, the concave rail 1002 and the annular rack 1003 can be driven to rotate when the rotating shaft 1001 rotates, the front and back positions of the milling cutter mechanism 12 are indirectly moved, then the position of the milling cutter mechanism 12 is adjusted, the sliding frame 15 and the bearing frame 16 are moved, the milling cutter 17 is driven to descend to a specified height, the rotation force of the top shaft 1701 can be completely transmitted to the bottom by the embedded structure of the embedded block 1703 and the groove 1704 and the completely-jointed state of the embedded block 1703 and the inner wall of the groove 1704, the internally-tangent structure of the ring 1702 and the connecting ring 1705 can ensure the integrity of the milling cutter 17, then the second motor 14 is turned on, the second motor 14 provides power to the milling cutter 17, and drives the knife edge 1707 to rotate, so as to process raw, at this point, the whole process is finished.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. An air condition compressor stator processing equipment with skew correction structure, includes device main part (1) and milling cutter (17), its characterized in that: the front side of the device main body (1) is provided with a foot rest (2), the top of the device main body (1) is provided with a sliding rail (3), the top of the sliding rail (3) is provided with a U-shaped sliding block (4), the top of the U-shaped sliding block (4) is provided with a clamping mechanism (5), the bottom rear side of the clamping mechanism (5) is connected with a sliding block (6), the bottom of the sliding block (6) is provided with a sliding groove (7), the top front side of the device main body (1) is provided with a support (8), the top of the support (8) is provided with a fixed frame (9), the inside of the fixed frame (9) is provided with a lead screw (10), the front side of the fixed frame (9) is provided with a first motor (11), the right side of the fixed frame (9) is provided with a milling cutter mechanism (12), the top of the milling cutter mechanism (12) is provided with a bar-shaped, the bottom of the second motor (14) is connected with a sliding frame (15), a bearing frame (16) is arranged on the periphery of the sliding frame (15), a milling cutter (17) is arranged at the bottom of the sliding frame (15), a sliding plate (501) is arranged at the bottom of the clamping mechanism (5), a telescopic rod (502) is arranged on the right side of the top of the sliding plate (501), an annular fixing frame (503) is arranged around the telescopic rod (502), a connecting shaft (504) is arranged on the left side of the first motor (11), a moving strip (505) is connected to the left side of the connecting shaft (504), a driving shaft (506) penetrates through the moving strip (505), a connecting plate (507) is connected to the top of the driving shaft (506), a driven shaft (508) penetrates through the left side of the connecting plate (507), a sliding strip (510) is arranged at the bottom of the driven shaft (508), and a bottom sliding chute (509) is arranged at the bottom of the sliding strip (510), the front side of slide bar (510) is provided with solid fixed ring (511), the left side of lead screw (10) is provided with pivot (1001), and the surface of pivot (1001) is provided with concave rail (1002), the inside embedding of concave rail (1002) has annular frame (1003), and the right side of annular frame (1003) is provided with connecting plate (1004), the top of milling cutter (17) is provided with apical axis (1701), and apical axis (1701)'s bottom encircles and has links up ring (1702), apical axis (1701)'s bottom is connected with embedding piece (1703), and the bottom of embedding piece (1703) is provided with rotates post (1706), the top of rotating post (1706) is provided with go-between (1705), and rotates the top inboard of post (1706 and be provided with recess (1704), the bottom of rotating post (1706) is provided with edge (1707).

2. An air conditioner compressor stator processing equipment with a deflection correcting structure according to claim 1, characterized in that: the device main body (1) and the sliding rail (3) are of an embedded structure, the sliding rail (3) and the U-shaped sliding block (4) are of an embedded structure, and the sliding rail (3) and the U-shaped sliding block (4) are of a slidable structure.

3. An air conditioner compressor stator processing equipment with a deflection correcting structure according to claim 1, characterized in that: the telescopic rod (502) is of a telescopic structure, the telescopic length of the telescopic rod (502) is half of the width of the sliding plate (501), the moving strip (505) is connected with the telescopic rod (502) through the connecting shaft (504), and the connecting shaft (504) and the moving strip (505) are of a sliding structure.

4. An air conditioner compressor stator processing equipment with a deflection correcting structure according to claim 1, characterized in that: remove strip (505) and link up fishplate bar (507) and be through connection structure through driving shaft (506), and remove strip (505), link up fishplate bar (507) and driving shaft (506) and be rotating-structure, link up fishplate bar (507) and slide bar (510) are through connection structure through driven shaft (508), and link up fishplate bar (507), slide bar (510) and driven shaft (508) are rotating-structure, end spout (509) are sliding structure with slide bar (510).

5. An air conditioner compressor stator processing equipment with a deflection correcting structure according to claim 1, characterized in that: the sliding grooves (7) are arranged in two groups, the two groups of sliding grooves (7) are parallel mechanisms, the sliding blocks (6) and the sliding grooves (7) are of embedded structures, and the sliding blocks (6) and the sliding grooves (7) are of slidable structures.

6. An air conditioner compressor stator processing equipment with a deflection correcting structure according to claim 1, characterized in that: the support (8) are arranged in two groups, the two groups of supports (8) are in axial symmetry structures, and the supports (8) and the fixing frame (9) are in vertical structures.

7. An air conditioner compressor stator processing equipment with a deflection correcting structure according to claim 1, characterized in that: the concave rail (1002) and the rotating shaft (1001) are in an embedded structure, the concave rail (1002) and the rotating shaft (1001) are in a surrounding structure, the annular frame (1003) and the concave rail (1002) are in an embedded structure, and the annular frame (1003) and the rotating shaft (1001) are in a rotating structure.

8. An air conditioner compressor stator processing equipment with a deflection correcting structure according to claim 1, characterized in that: the sliding frame (15) and the bearing frame (16) are in a penetrating structure, and the sliding frame (15) and the bearing frame (16) are in a sliding structure.

9. An air conditioner compressor stator processing equipment with a deflection correcting structure according to claim 1, characterized in that: the embedded block (1703) and the groove (1704) are of an embedded structure, the embedded block (1703) and the inner wall of the groove (1704) are of a complete attaching structure, the connection ring (1702) and the connection ring (1705) are of an internally-cutting structure, and the connection ring (1702) and the connection ring (1705) are of a complete attaching structure.

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