CN215509291U - Porous inner side chamfer machining device - Google Patents

Abstract

The utility model discloses a porous inner side chamfer processing device, which comprises: the fixing plate is horizontally arranged; the workpiece positioning block is arranged on the fixing plate; the power device is arranged on the fixed plate; the two cutter clamping devices are arranged on the fixed plate; the cutter feeding device is arranged below the fixing plate; the electric control system is electrically connected with the power device; a workpiece gripping device; the parts transfer device is a common conveyor belt structure. The method has the advantages of high processing efficiency, uniform chamfer size and depth, realization of mechanical processing of the inner chamfer of the porous side, simple operation and saving of a large amount of manpower and material resources. The utility model utilizes the fixed device to chamfer the inner side of the porous part, can control the tolerance within a certain range, reduces the probability of error occurrence and avoids economic loss.

Description

Porous inner side chamfer machining device

Technical Field

The utility model relates to the technical field of machining, in particular to a multi-hole inner side chamfer machining device.

Background

The existing mechanical processing is not thorough enough for mechanization of production details, some nonstandard parts can not be finished by using a traditional processing machine for processes such as rounding, chamfering and the like, rounding or chamfering operation is not carried out, the appearance and the assembly function of a product are influenced, manual chamfering is generally used, the consumed work time is more, the efficiency is low, and the quality cannot be guaranteed. Especially, four holes are formed in the multiple types of opening and closing handles, C0.5 chamfers are arranged on the inner sides of the holes, the chamfers cannot be made due to the fact that the difficulty of die forming is large, the chamfers C0.5 need to be machined, the assembly requirements and the assembly functions of products can be met, the characteristic distance between the two bosses with the holes is only 26mm and is small, common machining equipment cannot machine the chamfers, only manual machining can be conducted, the manually machined chamfers are uneven in size, and efficiency is low. The labor is wasted, errors are easy to occur, and larger economic loss is caused. Therefore, a device capable of mechanically processing the inner chamfer of the multiple holes is urgently needed.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present invention is directed to a multi-hole inner chamfer machining device.

In order to achieve the purpose, the utility model adopts the technical scheme that:

a porous inside chamfer machining device, comprising:

the fixing plate is horizontally arranged;

the workpiece positioning block is of a block structure and is arranged on the fixing plate;

the power device is arranged on the fixing plate and comprises a motor, a first annular belt and a second annular belt, and the first annular belt and the second annular belt are both connected to a transmission shaft of the motor;

the two cutter clamping devices are arranged on the fixed plate and are respectively connected with the first annular belt and the second annular belt;

the cutter feeding device is arranged below the fixing plate and abuts against the lower surface of the fixing plate;

the electric control system is arranged on one side of the power device and is electrically connected with the power device;

a workpiece grasping device, the workpiece grasping device comprising: the supporting rotating shaft is connected with the base and the four grippers, and the four grippers are distributed in a cross shape;

the part conveying devices are arranged on two sides of the base of the workpiece grabbing device and are arranged below the two opposite hand grips, and the part conveying devices are common conveying belt structures.

The above-mentioned porous inboard chamfer processingequipment wherein, still includes: the T-shaped guide rails are arranged on the fixing plate, the four T-shaped guide rails are arranged in a matrix mode, two T-shaped guide rails are arranged on one side, and the other two T-shaped guide rails are arranged on the other side.

Foretell porous inboard chamfer processingequipment, wherein, cutter clamping device still includes: the support comprises a support and a rotating shaft, wherein two T-shaped grooves are formed in the bottom of the support, each T-shaped groove is formed in the support and is matched with the T-shaped guide rail with two, two bearing holes are formed in the support, each rotating shaft supports against one end of each bearing hole, a square hole is formed in the center of the rotating shaft, a belt groove is formed in the outer edge of the rotating shaft, one belt groove is formed in the support, two belt grooves in the support are connected with the first annular belt and the other belt groove in the support is connected with the second annular belt.

Foretell porous inboard chamfer processingequipment, wherein, cutter clamping device still includes: the bearing, four the bearing respectively with two four on the support the dead eye cooperatees, every the bearing with all be equipped with axle sleeve, tapering chuck and chamfer cutter between the support, every the axle sleeve all passes the bearing, every the one end of axle sleeve is square boss structure, the one end of axle sleeve with square groove cooperatees, the other end of axle sleeve is seted up porosely, the internal surface in hole is seted up there is the internal thread, the surface of the one end of tapering chuck be equipped with internal thread matched with external screw thread, chamfer cutter is located on the other end of tapering chuck.

The above-mentioned porous inside chamfer processingequipment, wherein, the cutter feed arrangement includes: the through hole is arranged on the first plate-shaped structure, and the through hole penetrates through the first plate-shaped structure and the fixing plate.

The above-mentioned porous inside chamfer processingequipment, wherein, the cutter feed arrangement includes: the guide sleeve and the wedge block, the wedge block run through the guide sleeve and with the via hole cooperatees, the one end of guide sleeve support in first platelike structure, the other end of guide sleeve with the wedge block cooperatees.

The above-mentioned porous inside chamfer processingequipment, wherein, the cutter feed arrangement includes: the wedge-shaped block is connected with the air cylinder through the wedge-shaped block.

The above-mentioned porous inside chamfer processingequipment, wherein, the cutter feed arrangement includes: the bottom plate is parallel to the first plate-shaped structure, the side wall is perpendicular to the bottom plate, one end of the side wall is connected with the outer edge of the bottom plate, and the other end of the side wall is connected with the first plate-shaped structure.

In the above device for processing a multi-hole inner chamfer, the guide sleeve, the wedge block, the cylinder shaft end and the cylinder are all arranged in a space surrounded by the bottom plate, the first plate-shaped structure and the side wall.

Due to the adoption of the technology, compared with the prior art, the utility model has the following positive effects:

(1) the method has the advantages of high processing efficiency, uniform chamfer size and depth, realization of mechanical processing of the inner chamfer of the porous side, simple operation and saving of a large amount of manpower and material resources.

(2) The utility model utilizes the fixed device to chamfer the inner side of the porous part, can control the tolerance within a certain range, reduces the probability of error occurrence and avoids economic loss.

Drawings

Fig. 1 is a schematic axial view of the overall structure of the porous inside chamfer machining device of the present invention.

Fig. 2 is a schematic view of a tool holder of the overall structure of the porous inner chamfer machining device of the present invention.

Fig. 3 is a schematic view of a tool feeding device of the entire structure of the porous inside chamfer processing device of the present invention.

In the drawings: 1. a tool clamping device; 2. a tool feeding device; 3. a workpiece positioning block; 4. A fixed block; 5. a power plant; 6. an electronic control system; 7. a gripper; 8. a workpiece gripping device; 9. a part transfer device; 11. a T-shaped guide rail; 12. a support; 13. a T-shaped groove; 14. a bearing; 15. a shaft sleeve; 16. a taper chuck; 17. chamfering the cutter; 18. a square groove; 21. a via hole; 22. a guide sleeve; 23. a wedge block; 24. the end of the cylinder shaft; 25. a cylinder; 26. a base plate.

Detailed Description

The utility model is further described with reference to the following drawings and specific examples, which are not intended to be limiting. FIG. 1 is a schematic axial view of the overall construction of the multi-hole inside chamfer machining device of the present invention; FIG. 2 is a schematic view of a tool holder of the overall construction of the multi-hole inside chamfer machining device of the present invention; fig. 3 is a schematic view of a tool feeding device of the entire structure of the porous inside chamfer processing device of the present invention. Referring to fig. 1 to 3, a porous inner chamfer machining device according to a preferred embodiment is shown, including: the fixing plate 4 is horizontally arranged; the workpiece positioning block 3 is of a block structure, and the workpiece positioning block 3 is arranged on the fixing plate 4; the power device 5 is arranged on the fixing plate 4, the power device 5 comprises a motor, a first annular belt and a second annular belt, and the first annular belt and the second annular belt are both connected to a transmission shaft of the motor; the two cutter clamping devices 1 are arranged on the fixing plate 4, and the two cutter clamping devices 1 are respectively connected with the first annular belt and the second annular belt; the cutter feeding device 2 is arranged below the fixing plate 4, and the cutter feeding device 2 is abutted against the lower surface of the fixing plate 4; the electric control system 6 is arranged on one side of the power device 5, and the electric control system 6 is electrically connected with the power device 5; work piece grabbing device 8, work piece grabbing device 8 includes: the support rotating shaft is connected with the base and the four grippers 7, and the four grippers 7 are distributed in a cross shape; the part conveying devices 9 are arranged on two sides of the base of the workpiece grabbing device 8, the two part conveying devices 9 are arranged below the two opposite hand grips 7, and the part conveying devices 9 are common conveyor belt structures. The size of the workpiece positioning block 3 is replaceable according to the size of a machined workpiece, the supporting rotating shaft is rotatable, the supporting rotating shaft rotates to drive the gripper 7 to rotate, and the workpiece can be moved from the part transmission device 9 on one side to the part transmission device 9 on the other side.

In a preferred embodiment, the method further comprises: the T-shaped guide rails 11 and the four T-shaped guide rails 11 are arranged on the fixed plate 4, the four T-shaped guide rails 11 are arranged in a matrix, two T-shaped guide rails 11 are arranged on one side, and the other two T-shaped guide rails 11 are arranged on the other side.

In a preferred embodiment, the tool holder 1 further comprises: support 12 and axis of rotation, the bottom of two supports 12 all has two T type grooves 13, two T type grooves 13 of every support 12 all cooperate with two T type guide rail 11 with one side, two bearing 14 holes have all been seted up on two supports 12, every axis of rotation all supports in the tip in a bearing 14 hole, the quad slit has been seted up at the center of axis of rotation, the belt groove has been seted up in the outer fringe of axis of rotation, two epaxial belt grooves of rotation on one support 12 connect first endless belt, the epaxial belt groove of two rotations on another support 12 connects second endless belt.

In a preferred embodiment, a guide wheel can be arranged between the two rotating shafts on one side, the guide wheel is matched with the two rotating shafts, and the guide wheel is matched with the two rotating shafts to operate and play a role in transmission. The guide wheels also serve to keep the bearing 14 and the support 12 from moving outwards and inwards during operation of the device, which fixes the position of the rotating shaft, which does not follow the support 12 and moves outwards.

In a preferred embodiment, the tool holder 1 further comprises: bearing 14, four bearings 14 cooperate with four bearing 14 holes on two supports 12 respectively, all be equipped with axle sleeve 15 between every bearing 14 and the support 12, tapering chuck 16 and chamfer cutter 17, every axle sleeve 15 all passes bearing 14, the one end of every axle sleeve 15 is square boss structure, the one end and the square groove 18 of axle sleeve 15 cooperate, the other end of axle sleeve 15 is seted up porosely, the internal surface in hole is seted up there is the internal thread, the surface of the one end of tapering chuck 16 is equipped with the external screw thread with internal thread matched with, chamfer cutter 17 is located on the other end of tapering chuck 16.

Power is provided by the motor, and the motor shaft drives first annular belt and second annular belt, and first annular belt and second annular belt drive four axis of rotation, and four axis of rotation are through the cooperation transmission moment of torsion of the square boss of square groove 18 and bearing 14 cover, and then drive the operation of cutter.

The above are merely preferred embodiments of the present invention, and the embodiments and the protection scope of the present invention are not limited thereby.

The present invention also has the following embodiments in addition to the above:

in a further embodiment of the utility model, the tool feeding device 2 comprises: the through hole 21 and the first plate-shaped structure, the first plate-shaped structure is pressed against the fixing plate 4, the through hole 21 is opened on the first plate-shaped structure, and the through hole 21 penetrates through the first plate-shaped structure and the fixing plate 4.

In a further embodiment of the utility model, the tool feeding device 2 comprises: the guide sleeve 22 and the wedge block 23, the wedge block runs through the guide sleeve 22 and is matched with the through hole 21, one end of the guide sleeve 22 is abutted against the first plate-shaped structure, and the other end of the guide sleeve is matched with the wedge block 23.

In a further embodiment of the utility model, the tool feeding device 2 comprises: a cylinder shaft end 24 and a cylinder 25, wherein the cylinder shaft end 24 is connected with the wedge block 23 and the cylinder 25.

In a further embodiment of the utility model, the tool feeding device 2 comprises: the bottom plate 26 is parallel to the first plate-shaped structure, the side wall is perpendicular to the bottom plate 26, one end of the side wall is connected with the outer edge of the bottom plate 26, and the other end of the side wall is connected with the first plate-shaped structure.

In a further embodiment of the utility model, the guide sleeve 22, the wedge-shaped block 23, the cylinder shaft end 24 and the cylinder 25 are all arranged in a space enclosed by the bottom plate 26, the first plate-shaped structure and the side wall.

While the utility model has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the utility model.

Claims (9)

1. The utility model provides a porous inboard chamfer processingequipment which characterized in that includes:

the fixing plate is horizontally arranged;

the workpiece positioning block is of a block structure and is arranged on the fixing plate;

the power device is arranged on the fixing plate and comprises a motor, a first annular belt and a second annular belt, and the first annular belt and the second annular belt are both connected to a transmission shaft of the motor;

the two cutter clamping devices are arranged on the fixed plate and are respectively connected with the first annular belt and the second annular belt;

the cutter feeding device is arranged below the fixing plate and abuts against the lower surface of the fixing plate;

the electric control system is arranged on one side of the power device and is electrically connected with the power device;

a workpiece grasping device, the workpiece grasping device comprising: the supporting rotating shaft is connected with the base and the four grippers, and the four grippers are distributed in a cross shape;

the part conveying devices are arranged on two sides of the base of the workpiece grabbing device and are arranged below the two opposite hand grips, and the part conveying devices are of a conveying belt structure.

2. The apparatus of claim 1, further comprising: the T-shaped guide rails are arranged on the fixing plate, the four T-shaped guide rails are arranged in a matrix mode, two T-shaped guide rails are arranged on one side, and the other two T-shaped guide rails are arranged on the other side.

3. The apparatus for machining a porous inner chamfer as claimed in claim 2, wherein the tool holding means further comprises: the support comprises a support and a rotating shaft, wherein two T-shaped grooves are formed in the bottom of the support, each T-shaped groove is formed in the support and is matched with the T-shaped guide rail with two, two bearing holes are formed in the support, each rotating shaft supports against one end of each bearing hole, a square hole is formed in the center of the rotating shaft, a belt groove is formed in the outer edge of the rotating shaft, one belt groove is formed in the support, two belt grooves in the support are connected with the first annular belt and the other belt groove in the support is connected with the second annular belt.

4. The apparatus for machining a porous inner chamfer as claimed in claim 3, wherein the tool holding means further comprises: the bearing, four the bearing respectively with two four on the support the dead eye cooperatees, every the bearing with all be equipped with axle sleeve, tapering chuck and chamfer cutter between the support, every the axle sleeve all passes the bearing, every the one end of axle sleeve is square boss structure, the one end of axle sleeve with square groove cooperatees, the other end of axle sleeve is seted up porosely, the internal surface in hole is seted up there is the internal thread, the surface of the one end of tapering chuck be equipped with internal thread matched with external screw thread, chamfer cutter is located on the other end of tapering chuck.

5. The multi-hole inside chamfer machining device according to claim 1, wherein the tool feeding device comprises: the through hole is arranged on the first plate-shaped structure, and the through hole penetrates through the first plate-shaped structure and the fixing plate.

6. The multi-hole inside chamfer machining device according to claim 5, wherein the tool feeding device comprises: the guide sleeve and the wedge block, the wedge block run through the guide sleeve and with the via hole cooperatees, the one end of guide sleeve support in first platelike structure, the other end of guide sleeve with the wedge block cooperatees.

7. The multi-hole inside chamfer machining device according to claim 6, wherein the tool feeding device comprises: the wedge-shaped block is connected with the air cylinder through the wedge-shaped block.

8. The multi-hole inside chamfer machining device according to claim 7, wherein the tool feeding device comprises: the bottom plate is parallel to the first plate-shaped structure, the side wall is perpendicular to the bottom plate, one end of the side wall is connected with the outer edge of the bottom plate, and the other end of the side wall is connected with the first plate-shaped structure.

9. The multi-hole inside chamfer machining device of claim 8, wherein the guide sleeve, the wedge, the cylinder shaft end and the cylinder are all disposed in a space enclosed by the bottom plate, the first plate-like structure and the side wall.

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