CN216030009U - Efficient machining's accessory processing equipment of polishing - Google Patents

Abstract

The utility model discloses efficient machining accessory grinding processing equipment in the technical field of grinding processing equipment, which comprises a base, wherein sliding grooves A are formed in two sides of the upper surface of the base, sliding rails are arranged on two sides of the inner bottom end of the base, a shell is arranged at the top of the base, a sliding groove B is formed in the top end of the inner part of the shell, bearings are arranged above the inner walls of the two sides of the shell, a rotating shaft A is arranged in each bearing, external threads A are arranged on the outer wall of the rotating shaft A, and the efficient machining accessory grinding processing equipment is reasonable in structure, and is provided with a grinding assembly and a driving assembly, wherein the grinding assembly is matched with a moving block A to move left and right, and the moving block B is matched with the driving assembly to move back and forth, so that the automatic adjustment of the grinding direction of the grinding processing equipment in the grinding process is facilitated, the efficient grinding operation of the grinding processing equipment is enhanced, and simultaneously, simple structure, convenient operation save a large amount of loaded down with trivial details steps, the effectual work efficiency that has improved.

Description

Efficient machining's accessory processing equipment of polishing

Technical Field

The utility model relates to the technical field of polishing equipment, in particular to efficient machining accessory polishing equipment.

Background

The full-name reciprocating type electric polishing polisher (a file grinder) of the polisher is widely used for finish machining and surface polishing treatment in the mold industry, is a substitute of the similar pneumatic products, and is characterized in that: suitable little space, the fine machining place, have small, the rotational speed is high, stability is good, almost no vibrations, but the one-hand operation, the work piece exquisiteness of indefatigability, polishing, it is exquisite, removable to polish consumptive material extensively easily available, low price, change different consumptive materials and can realize: the grinding machine has the advantages that the grinding machine can achieve the effects of rough carving, fine grinding and high mirror surface brightness of workpieces by carving, drilling, grinding, polishing, grinding and the like, and the grinding machine with the functions of dust collection and illumination is also arranged on the market.

The accessory of current efficient machining processing equipment of polishing exists the defect: when the polisher polishes mechanical workpieces, because the position of the mechanical workpieces needs to be changed in the polishing process, the position of the mechanical workpieces needs to be adjusted manually, so that the working efficiency is affected, and the potential safety hazard is easily caused.

There is therefore a need to develop an efficient machining accessory sanding apparatus.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide efficient machining accessory polishing equipment, which is provided with a polishing component and a driving component, wherein the polishing component is matched with a moving block A to move left and right, and a moving block B is matched with the driving component to move front and back, so that the polishing orientation of the polishing equipment can be automatically adjusted in the polishing process, the efficient polishing operation of the polishing equipment is enhanced, and the problem of low efficiency of the polishing equipment in the background technology is solved.

In order to achieve the purpose, the utility model provides the following technical scheme: an efficient accessory polishing device for machining comprises a base, wherein sliding grooves A are formed in two sides of the upper surface of the base, the two sides of the bottom end in the base are both provided with slide rails, the top of the base is provided with a shell, the top end of the interior of the shell is provided with a sliding chute B, bearings are arranged above the inner walls of the two sides of the shell, a rotating shaft A is arranged in the bearing, an external thread A is arranged on the outer wall of the rotating shaft A, a moving block A is arranged in the center of the outer wall of the rotating shaft A, the bottom of the moving block A is provided with a grinding component, the rear end of the interior of the base is provided with a driving component, the driving assembly comprises a driving motor C, a rotating shaft C and a rotating shaft D, external threads B are arranged at the center positions of the outer walls of the rotating shaft C and the rotating shaft D, and a moving block B is installed on one side of the outer walls of the rotating shaft C and the rotating shaft D.

Preferably, a driving motor A is installed above the outer wall of one side of the shell, and an output shaft on the driving motor A is connected with the rotating shaft A through a coupler A.

Preferably, a threaded hole a is formed in the surface of the moving block a, and internal threads on the threaded hole a are meshed and connected with external threads a on the rotating shaft a.

Preferably, the top of the moving block a is provided with a sliding block a, and the outer wall of the sliding block a is in sliding connection with the hole wall of the sliding groove B.

Preferably, the polishing assembly comprises a mounting frame, a driving motor B is mounted inside the mounting frame, an output shaft on the driving motor B is connected with a rotating shaft B through a coupler B, and a polishing sheet is mounted at the bottom end of the rotating shaft B.

Preferably, an output shaft of the driving motor C is connected with the rotating shaft C through a coupling C.

Preferably, the outer wall opposite side of pivot C is equipped with driving pulley, the outer wall opposite side of pivot D is equipped with driven pulley, be connected through driving belt between driving pulley and the driven pulley.

Preferably, a threaded hole B is formed in the center of the surface of the moving block B, and internal threads on the threaded hole B are meshed with external threads B on the rotating shaft C and the rotating shaft D.

Preferably, the bottom of the moving block B is provided with a sliding block B, and the outer wall of the sliding block B is slidably connected with the hole wall of the sliding rail.

Preferably, a supporting column is installed at the top of the moving block B, the outer wall of the supporting column is in sliding connection with the hole wall of the sliding groove a, the top end of the supporting column penetrates through the sliding groove a to be connected with the moving plate, lifting cylinders are installed on two sides of the top of the moving plate, and clamps are installed on the top ends of the lifting cylinders.

Compared with the prior art, the utility model has the beneficial effects that:

a driving motor A is arranged above the outer wall of one side of a shell, a rotating shaft A is arranged on an output shaft on the driving motor A through a coupler A, the driving motor A is started to drive the rotating shaft A to rotate forwards or reversely, a moving block A is arranged on the outer wall of the rotating shaft A, a threaded hole A on the moving block A is meshed with an external thread A on the rotating shaft A, the rotating shaft A rotates forwards or reversely to drive the moving block A to move leftwards or rightwards, a sliding block A is arranged at the top of the moving block A, the outer wall of the sliding block A is in sliding connection with the wall of a sliding groove B on the shell, when the moving block A moves leftwards or rightwards, the sliding block A slides on the shell, the situation that the moving block A is separated from the shell due to insufficient supporting force is avoided, a polishing assembly is arranged on the moving block A, a driving motor B is arranged on an installation frame on the polishing assembly, and the rotating shaft B is arranged on the output shaft on the driving motor B through a coupler B, starting a driving motor B to drive a rotating shaft B to rotate forwards or reversely, and matching a driving motor A to realize left and right grinding operation of a grinding sheet on a mechanical accessory by mounting the grinding sheet on the rotating shaft B when the mechanical accessory is ground;

the driving component is arranged at the rear end inside the base, the driving motor C on the driving component is arranged on one side of the rear end inside the base, the driving motor C is fixed in position, the rotating shaft C is arranged on an output shaft on the driving motor C through the coupler C, the driving motor C is started to drive the rotating shaft C to rotate forwards or reversely, the driving pulley is arranged on the rotating shaft C, the driven pulley is connected to the driving pulley through the transmission belt, the rotating shaft D is arranged on the driven pulley, the rotating shaft C rotates forwards or reversely to drive the rotating shaft D to rotate forwards or reversely, the movable block B is arranged on the outer wall of the rotating shaft C and the rotating shaft D, the threaded hole B on the movable block B is meshed with the external threads B on the rotating shaft C and the rotating shaft D, the rotating shaft C and the rotating shaft D rotate forwards or reversely to drive the movable block B to move forwards or backwards, and the supporting columns are arranged at the tops of the movable block B, run through spout A on the base with the support column, make the outer wall of support column and spout A's pore wall sliding connection, then the support column receives movable block B to drive, slide operation in spout A, through the top installation movable plate at the support column, and at the top installation lift cylinder of movable plate, with the top sectional fixture of lift cylinder, utilize lift cylinder to turn into the effect that linear reciprocating motion was accomplished to mechanical energy with air compression's pressure energy, start the lift cylinder, it carries out elevating movement to drive anchor clamps, position and height control around having realized polishing processing equipment carries out the automation at the in-process of polishing, the high-efficient operation of polishing processing equipment has been strengthened, and simultaneously, moreover, the steam generator is simple in structure, and convenient for operation, save a large amount of loaded down with trivial details steps, the effectual work efficiency that has improved.

Drawings

FIG. 1 is an elevational, cross-sectional view provided by the present invention;

FIG. 2 is an enlarged view of the structure at A in FIG. 1 according to the present invention;

FIG. 3 is an enlarged view of the structure at B in FIG. 1 according to the present invention;

FIG. 4 is a front view of a grinding assembly provided by the present invention;

FIG. 5 is a top view of the drive assembly provided by the present invention;

fig. 6 is a perspective view of a base part structure provided by the present invention.

In the figure: 1. a base; 101. a chute A; 102. a slide rail; 2. a housing; 201. a chute B; 202. driving a motor A; 203. a coupler A; 204. a rotating shaft A; 205. an external thread A; 3. moving block A; 301. a threaded hole A; 302. a slide block A; 4. polishing the assembly; 401. a mounting frame; 402. driving a motor B; 403. a coupler B; 404. a rotating shaft B; 405. grinding the sheets; 5. a drive assembly; 501. driving a motor C; 502. a coupler C; 503. a rotating shaft C; 504. a drive pulley; 505. a drive belt; 506. a driven pulley; 507. a rotating shaft D; 508. an external thread B; 6. a moving block B; 601. a threaded hole B; 602. a slide block B; 603. a support pillar; 604. moving the plate; 605. a lifting cylinder; 606. and (4) clamping.

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.

The utility model provides the following technical scheme: an efficient machining accessory polishing device can effectively improve the efficiency of the polishing device in the using process, and a driving motor A202 and a driving assembly 5 are added, please refer to fig. 1-6, which comprises a base 1, wherein two sides of the upper surface of the base 1 are respectively provided with a sliding groove A101, two sides of the inner bottom end of the base 1 are respectively provided with a sliding rail 102, the top of the base 1 is provided with a shell 2, the inner top end of the shell 2 is provided with a sliding groove B201, two sides of the inner wall of the shell 2 are respectively provided with a bearing, a rotating shaft A204 is arranged in the bearing, the outer wall of the rotating shaft A204 is provided with an external thread A205, the outer wall center position of the rotating shaft A204 is provided with a moving block A3, the bottom of a moving block 3 is provided with a polishing assembly 4, the driving assembly 5 is arranged at the rear end of the inner part of the base 1, the driving assembly 5 comprises a driving motor C501, a rotating shaft C503 and a rotating shaft D507, the outer wall center positions of the rotating shafts C503 and D507 are respectively provided with an external thread B508, a moving block B6 is arranged on one side of the outer walls of the rotating shaft C503 and the rotating shaft D507;

further, a driving motor a202 is installed above the outer wall of one side of the housing 2, an output shaft on the driving motor a202 is connected with a rotating shaft a204 through a coupler a203, specifically, the rotating shaft a204 is installed on the output shaft on the driving motor a202 through the coupler a203, the driving motor a202 is started, and the rotating shaft a204 is driven to rotate forward or backward;

furthermore, a threaded hole a301 is formed in the surface of the moving block A3, an internal thread on the threaded hole a301 is meshed with an external thread a205 on the rotating shaft a204, a sliding block a302 is arranged at the top of the moving block A3, an outer wall of the sliding block a302 is in sliding connection with a hole wall of the sliding groove B201, the polishing assembly 4 comprises a mounting frame 401, a driving motor B402 is installed inside the mounting frame 401, an output shaft on the driving motor B402 is connected with the rotating shaft B404 through a coupler B403, a polishing disc 405 is installed at the bottom end of the rotating shaft B404, specifically, the threaded hole a301 on the moving block A3 is meshed with the external thread a205 on the rotating shaft a204, the rotating shaft a204 rotates forwards or backwards to drive the moving block A3 to move leftwards or rightwards, the sliding block a302 is arranged at the top of the moving block A3 to slidably connect the outer wall of the sliding block a302 with the hole wall of the sliding groove B201 on the housing 2, when the moving block A3 moves leftwards or rightwards, the sliding block a302 slides on the housing 2, the situation that a moving block A3 is separated from a shell 2 due to insufficient supporting force is avoided, the grinding assembly 4 is installed on the moving block A3, the driving motor B402 is installed on the installation frame 401 on the grinding assembly 4, the rotating shaft B404 is installed on the output shaft of the driving motor B402 through the coupler B403, the driving motor B402 is started to drive the rotating shaft B404 to rotate forwards or backwards, the grinding sheet 405 is installed on the rotating shaft B404, and when a mechanical accessory is ground, the grinding sheet 405 is matched with the driving motor A202 to realize left and right grinding operation of the mechanical accessory by the grinding sheet 405;

further, an output shaft on the driving motor C501 is connected with a rotating shaft C503 through a coupler C502, the other side of the outer wall of the rotating shaft C503 is provided with a driving pulley 504, the other side of the outer wall of the rotating shaft D507 is provided with a driven pulley 506, the driving pulley 504 is connected with the driven pulley 506 through a transmission belt 505, specifically, the driving motor C501 on the driving assembly 5 is installed on one side of the rear end inside the base 1, so that the position of the driving motor C501 is fixed, the rotating shaft C503 is installed on the output shaft on the driving motor C501 through the coupler C502, the driving motor C501 is started to drive the rotating shaft C503 to rotate forwards or reversely, the driving pulley 504 is arranged on the rotating shaft C503, the driving pulley 504 is connected with the driven pulley 506 through the transmission belt 505, and the rotating shaft D507 is installed on the driven pulley 506, so that the rotating shaft C503 rotates forwards or reversely, and drives the rotating shaft D507 or reversely;

further, a threaded hole B601 is formed in the center of the surface of the moving block B6, internal threads on the threaded hole B601 are meshed with a rotating shaft C503 and external threads B508 on a rotating shaft D507, a sliding block B602 is arranged at the bottom of the moving block B6, the outer wall of the sliding block B602 is connected with the hole wall of the sliding rail 102 in a sliding manner, a supporting column 603 is arranged at the top of the moving block B6, the outer wall of the supporting column 603 is connected with the hole wall of the sliding groove a101 in a sliding manner, the top end of the supporting column 603 penetrates through the sliding groove a101 to be connected with the moving plate 604, lifting cylinders 605 are arranged on both sides of the top of the moving plate 604, a clamp 606 is arranged at the top end of the lifting cylinder 605, specifically, the threaded hole B601 on the moving block B6 is meshed with the rotating shaft C503 and the external threads B508 on the rotating shaft D507 to enable the rotating shaft C503 and the rotating shaft D507 to rotate forwards or reversely to drive the moving block B6 to move forwards or backwards, the moving block B6, the supporting column 603 penetrates through the sliding groove a101 on the base 1 by arranging the supporting column 603 at the top of the supporting column B6, the outer wall of the supporting column 603 is in sliding connection with the hole wall of the sliding groove A101, the supporting column 603 is driven by the moving block B6, sliding operation is performed in the sliding groove A101, the moving plate 604 is installed at the top end of the supporting column 603, the lifting cylinder 605 is installed at the top of the moving plate 604, the top end of the lifting cylinder 605 is provided with the clamp 606, the lifting cylinder 605 is utilized to convert compressed air pressure energy into mechanical energy to achieve linear reciprocating motion, the lifting cylinder 605 is started, the clamp 606 is driven to perform lifting motion, automatic front and back position and height adjustment of the polishing equipment in the polishing process is achieved, and efficient polishing operation of the polishing equipment is enhanced.

The working principle is as follows: when the polishing device is used, a driving motor A202 is arranged above the outer wall of one side of a shell 2, an output shaft on the driving motor A202 is provided with a rotating shaft A204 through a coupler A203, the driving motor A202 is started to drive the rotating shaft A204 to rotate forwards or backwards, a moving block A3 is arranged on the outer wall of the rotating shaft A204, a threaded hole A301 on a moving block A3 is meshed with an external thread A205 on the rotating shaft A204, the rotating shaft A204 rotates forwards or backwards to drive a moving block A3 to move leftwards or rightwards, a sliding block A302 is arranged on the top of the moving block A3, the outer wall of the sliding block A302 is in sliding connection with the hole wall of a sliding groove B201 on the shell 2, when the moving block A3 moves leftwards or rightwards, the sliding block A302 slides on the shell 2 to avoid the situation that the moving block A3 is separated from the shell 2 due to insufficient supporting force, a polishing component 4 is arranged on the moving block A3, and a driving motor 402B is arranged on a mounting rack 401 on the polishing component 4, installing a rotating shaft B404 on an output shaft of a driving motor B402 through a coupling B403, starting the driving motor B402 to drive the rotating shaft B404 to rotate forwards or backwards, installing a polishing disc 405 on the rotating shaft B404, when a mechanical part is polished, matching with the driving motor A202 to realize that the polishing disc 405 performs left and right polishing operation on the mechanical part, installing a driving component 5 at the rear end inside the base 1, installing a driving motor C501 on the driving component 5 at one side of the rear end inside the base 1 to fix the position of the driving motor C501, installing a rotating shaft C503 on the output shaft of the driving motor C501 through the coupling C502, starting the driving motor C501 to drive the rotating shaft C503 to rotate forwards or backwards, installing a driving belt pulley 504 on the rotating shaft C503 to connect a driven pulley 506 through a driving belt 505, installing a rotating shaft D507 on the driven pulley 506 to enable the rotating shaft C503 to rotate forwards or backwards to drive the rotating shaft D507, a moving block B6 is installed on the outer walls of a rotating shaft C503 and a rotating shaft D507, a threaded hole B601 on a moving block B6 is meshed with an external thread B508 on the rotating shaft C503 and the rotating shaft D507 to enable the rotating shaft C503 and the rotating shaft D507 to rotate forward or reversely to drive a moving block B6 to move forward or backward, a supporting column 603 is installed on the top of the moving block B6 to penetrate through a sliding groove A101 on a base 1, the outer wall of the supporting column 603 is in sliding connection with the hole wall of the sliding groove A101, the supporting column 603 is driven by the moving block B6 to perform sliding operation in the sliding groove A101, a moving plate 604 is installed on the top of the supporting column 603, a lifting cylinder 605 is installed on the top of the moving plate 604, a clamp 606 is installed on the top of the lifting cylinder 605, the pressure energy of air compression is converted into mechanical energy to achieve linear reciprocating motion by the lifting cylinder 605, the lifting cylinder 605 is started to drive the clamp 606 to perform lifting motion, the automatic polishing device has the advantages that the polishing device can be automatically adjusted in position and height in the polishing process, the efficient polishing operation of the polishing device is enhanced, meanwhile, the automatic polishing device is simple in structure and convenient to operate, a large number of complex steps are omitted, and the working efficiency is effectively improved.

While the utility model has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the utility model. In particular, the various features of the embodiments disclosed herein may be used in any combination, provided that there is no structural conflict, and the combinations are not exhaustively described in this specification merely for the sake of brevity and conservation of resources. Therefore, it is intended that the utility model not be limited to the particular embodiments disclosed, but that the utility model will include all embodiments falling within the scope of the appended claims.

Claims (10)

1. The utility model provides an efficient machining's accessory processing equipment of polishing, includes base (1), its characterized in that: the polishing machine is characterized in that sliding grooves A (101) are formed in two sides of the upper surface of the base (1), sliding rails (102) are mounted on two sides of the bottom end of the interior of the base (1), a shell (2) is mounted at the top of the base (1), a sliding groove B (201) is formed in the top end of the interior of the shell (2), bearings are arranged above the inner walls of two sides of the shell (2), a rotating shaft A (204) is mounted in each bearing, external threads A (205) are formed in the outer wall of the rotating shaft A (204), a moving block A (3) is mounted at the center position of the outer wall of the rotating shaft A (204), a polishing assembly (4) is mounted at the bottom of the moving block A (3), a driving assembly (5) is mounted at the rear end of the interior of the base (1), each driving assembly (5) comprises a driving motor C (501), a rotating shaft C (503) and a rotating shaft D (507), and external threads B (508) are formed in the center positions of the outer walls of the rotating shaft C (503) and the rotating shaft D (507), and a moving block B (6) is arranged on one side of the outer walls of the rotating shaft C (503) and the rotating shaft D (507).

2. An efficient machined part grinding process apparatus as set forth in claim 1 wherein: a driving motor A (202) is installed on the upper portion of the outer wall of one side of the shell (2), and an output shaft on the driving motor A (202) is connected with a rotating shaft A (204) through a coupler A (203).

3. An efficient machined part grinding process apparatus as set forth in claim 1 wherein: the surface of the moving block A (3) is provided with a threaded hole A (301), and internal threads on the threaded hole A (301) are meshed and connected with external threads A (205) on the rotating shaft A (204).

4. An efficient machined part grinding process apparatus as set forth in claim 1 wherein: the top of the moving block A (3) is provided with a sliding block A (302), and the outer wall of the sliding block A (302) is in sliding connection with the hole wall of the sliding groove B (201).

5. An efficient machined part grinding process apparatus as set forth in claim 1 wherein: the polishing assembly (4) comprises a mounting frame (401), a driving motor B (402) is mounted inside the mounting frame (401), an output shaft on the driving motor B (402) is connected with a rotating shaft B (404) through a shaft coupling B (403), and a polishing plate (405) is mounted at the bottom end of the rotating shaft B (404).

6. An efficient machined part grinding process apparatus as set forth in claim 1 wherein: an output shaft on the driving motor C (501) is connected with a rotating shaft C (503) through a coupler C (502).

7. An efficient machined part grinding process apparatus as set forth in claim 1 wherein: the outer wall opposite side of pivot C (503) is equipped with drive pulley (504), the outer wall opposite side of pivot D (507) is equipped with driven pulley (506), be connected through drive belt (505) between drive pulley (504) and the driven pulley (506).

8. An efficient machined part grinding process apparatus as set forth in claim 1 wherein: the center of the surface of the moving block B (6) is provided with a threaded hole B (601), and internal threads on the threaded hole B (601) are meshed and connected with external threads B (508) on the rotating shaft C (503) and the rotating shaft D (507).

9. An efficient machined part grinding process apparatus as set forth in claim 1 wherein: the bottom of the moving block B (6) is provided with a sliding block B (602), and the outer wall of the sliding block B (602) is in sliding connection with the hole wall of the sliding rail (102).

10. An efficient machined part grinding process apparatus as set forth in claim 1 wherein: the top of the moving block B (6) is provided with a supporting column (603), the outer wall of the supporting column (603) is in sliding connection with the hole wall of the sliding groove A (101), the top end of the supporting column (603) penetrates through the sliding groove A (101) to be connected with the moving plate (604), two sides of the top of the moving plate (604) are provided with lifting cylinders (605), and the top ends of the lifting cylinders (605) are provided with clamps (606).

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