CN222404712U - A cutting device for machining mechanical parts - Google Patents

Abstract

The utility model discloses a cutting device for machining mechanical parts, which comprises a workbench, wherein a gantry structure is arranged on the workbench, a machining assembly is arranged on the gantry structure, the machining assembly comprises a horizontal square column, the end part of the horizontal square column is rotationally connected with a rotary table, the periphery of the rotary table is provided with a ring groove, the ring groove is rotationally connected with the inner side of a driving bin, the periphery of one end of the rotary table far away from the horizontal square column is uniformly fixedly connected with a plurality of sleeves, a plurality of driving columns are rotationally connected in the sleeves, and a plurality of cutters are fixedly connected with one end of the driving columns far away from the rotary table. According to the angle steel bracket, a plurality of different types of cutters are adopted, wherein the cutter positioned at the lowest position is used for cutting processing, the turntable is driven to rotate through the third servo gear motor, the cutters at the different positions are positioned at the lowest position, the effect of replacing the cutters for processing is achieved, the cutter is replaced in a mode of removing the cutters without an additional cutter replacing mechanism, the cutter replacement is more convenient, and the overall processing efficiency is improved.

Description

Cutting device for machining mechanical parts

Technical Field

The utility model relates to the technical field of cutting equipment, in particular to a cutting device for machining mechanical parts.

Background

Cutting refers to a machining method for cutting redundant material layers on a blank or a workpiece into chips by using a cutting tool (comprising a cutter, a grinding tool and an abrasive), so that the workpiece obtains a specified geometric shape, size and surface quality, and in the machining of mechanical parts, a milling mode is mainly adopted, namely, the cutter adopts a rotating mode to machine the workpiece, for example, chinese patent application publication No. CN114749704A discloses a surface milling device for machining mechanical materials, the milling device comprises a machine table, a plurality of electric telescopic rods are fixed at the left part of the upper side of the machine table, a lifting seat is fixed at the upper end of the electric telescopic rods, a milling mechanism is fixed at the lower side of the lifting seat, a machining cavity is formed at the upper side of the machine table, a first motor is fixed at the right end of the machining cavity, a first threaded rod is fixed at the output shaft end of the first motor, a movable seat is connected with threads on the first threaded rod, a clamping seat is fixed on the movable seat, a transmission cavity is formed inside the clamping seat, and a transmission mechanism is arranged inside the transmission cavity, but the current machining device for machining mechanical parts has the following defects:

When the mechanical part is machined, the cutting condition is complex, a plurality of cutters are needed to be used for cutting in most cases, so that the cutters are needed to be replaced in the machining process, the machining is interrupted in the current cutter replacing mode, the cutters are taken down by the cutter replacing mechanism, and then additional cutters are installed.

For this purpose we propose a cutting device for machining mechanical parts to solve the above problems.

Disclosure of utility model

The present utility model is directed to a cutting device for machining a mechanical part, which solves the problems set forth in the background art.

The cutting device for machining the mechanical parts comprises a workbench, wherein a gantry structure is arranged on the workbench, a machining assembly is arranged on the gantry structure, the machining assembly comprises a transverse square column, the end part of the transverse square column is rotationally connected with a rotary table, the circumferential side of the rotary table is provided with a ring groove, the ring groove is rotationally connected with the inner side of a driving bin, a plurality of sleeves are uniformly fixedly connected with the circumferential side of one end of the rotary table far from the transverse square column, a plurality of driving columns are rotationally connected in the sleeves, a plurality of cutters are fixedly connected with one end of the driving columns far from the rotary table, the other end of the driving columns is positioned in the rotary table and fixedly connected with a plurality of face gears, and the types of the cutters are different;

The driving device is characterized in that a transmission cavity is formed in the driving bin and close to the ring groove, the upper part in the transmission cavity is rotationally connected with a driving belt pulley, a driven belt pulley is fixedly sleeved on the ring groove, a synchronous belt is sleeved on the driving belt pulley and the driven belt pulley, a third servo speed reducing motor is fixedly connected to one side, far away from the turntable, of the top surface of the driving bin, and the rotating shaft end of the third servo speed reducing motor is fixedly connected with the rotating shaft end of the driving belt.

Preferably, the rotary table is internally connected with a plurality of driving gears in a rotating way at positions close to a plurality of face gears, a plurality of driving shafts are horizontally fixedly connected to one ends of the driving gears, close to the transverse square columns, of the rotary table, a plurality of positioning hole grooves are horizontally formed in one side, close to the transverse square columns, of the rotary table, corresponding to the positions of the driving shafts, and a plurality of spline grooves are formed in the end parts of the driving shafts.

Preferably, the sleeve member is sleeved on the horizontal square column in a sliding manner, the side wall of the sleeve member is horizontally fixedly connected with a plurality of positioning columns corresponding to the positions of the positioning holes, a plurality of positioning columns are inserted into the positioning holes, the top surface of the horizontal square column is fixedly connected with the electric push rod, and the output end of the electric push rod is fixedly connected with the side wall of the top of the sleeve member.

Preferably, the locating column and the sleeve member at the lowest part are internally rotated and sleeved with the driving rotating rod, the driving rotating rod is close to one end of the driving shaft and fixedly connected with the spline head, the spline head is inserted into the spline groove of the driving shaft at the lowest part, the sleeve member is far away from the bottom of one side of the turntable and fixedly connected with the driving motor, and the rotating shaft end of the driving motor is fixedly connected with the end part of the driving rotating rod.

Preferably, the gantry structure comprises two side plates, wherein the two side plates are fixedly connected to two sides of the workbench, two sliding grooves are formed in the top surfaces of the side plates, two sliding blocks are horizontally and movably connected in the sliding grooves, two vertical columns are vertically and fixedly connected to the top surfaces of the sliding blocks, a transverse frame is fixedly connected between the top ends of the vertical columns, two transverse sliding rails are fixedly connected to one side of the transverse frame, a sliding plate is horizontally and slidingly connected to the transverse sliding rails, two vertical sliding rails are fixedly connected to one side of the sliding plate, two vertical sliding plates are vertically and slidingly connected to the vertical sliding rails, one ends of the transverse square columns, which are far away from a turntable, are fixedly connected to the bottom side walls of the vertical plates, two L-shaped supports are fixedly connected to the two sides of the driving bin, and the ends of the L-shaped supports are fixedly connected to the side walls of the vertical plates.

Preferably, one of the sliding grooves is horizontally and rotatably connected with a first screw rod, a first threaded sleeve is fixedly connected on the sliding block, the first screw rod is in threaded connection with the first threaded sleeve, one of the sliding blocks is fixedly connected with a first servo gear motor at the end part of the side plate, the rotating shaft end of the first servo gear motor is fixedly connected with the end part of the first screw rod, one end of a transverse frame is fixedly connected with a second servo gear motor, one side of the transverse frame, close to a sliding plate, is horizontally and rotatably connected with a second screw rod, the sliding plate is fixedly connected with a second threaded sleeve, the second screw rod is in threaded connection with the second threaded sleeve, the rotating shaft end of the second servo gear motor is fixedly connected with the end part of the second screw rod, the sliding plate is vertically and fixedly connected with an electric cylinder, and the top end of the output end of the electric cylinder is fixedly connected with the top of the vertical plate.

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

According to the angle steel bracket, a plurality of different types of cutters are adopted, wherein the cutter positioned at the lowest position is used for cutting processing, the turntable is driven to rotate through the third servo gear motor, the cutters at the different positions are positioned at the lowest position, the effect of replacing the cutters for processing is achieved, the cutter is replaced in a mode of removing the cutters without an additional cutter replacing mechanism, the cutter replacement is more convenient, and the overall processing efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of a main structure of a first and second embodiment of the present utility model;

FIG. 2 is a schematic view showing the construction of a processing assembly according to the first and second embodiments of the present utility model;

FIG. 3 is a schematic view showing a cross-sectional structure of a processing assembly according to a first and second embodiment of the present utility model;

FIG. 4 is a schematic view of the construction of a kit according to a second embodiment of the present utility model;

FIG. 5 is an enlarged schematic view of the structure of FIG. 3A according to the present utility model;

Fig. 6 is a schematic view of a structure of a cross frame according to a second embodiment of the present utility model.

In the figure, 1, a workbench, 2, a gantry structure, 3, a processing assembly, 21, a side plate, 22, a sliding groove, 23, a sliding block, 24, a stand column, 25, a transverse frame, 26, a transverse sliding rail, 27, a sliding plate, 28, a vertical sliding rail, 29, a vertical plate, 210, a first servo speed reduction motor, 211, a first screw rod, 212, a first threaded sleeve, 213, a second servo speed reduction motor, 214, a second screw rod, 215, a second threaded sleeve, 216, an electric cylinder, 31, a transverse square column, 32, a turntable, an annular groove, 34, a driving bin, 35, a sleeve, 36, a driving column, 37, a cutter, 38, a transmission cavity, 39, a driving pulley, 310, a driven pulley, 311, a synchronous belt, 312, a third servo speed reduction motor, 313, a face gear, 314, a driving gear, 315, a driving shaft, 316, a positioning hole groove, 317, a spline groove, 318, a sleeve, 319, a positioning column, 320, an electric push rod, 321, a driving rotary rod, 322, a spline head, 323, a driving motor, 324 and an L-shaped bracket.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1:

Referring to fig. 1-3, the utility model provides a cutting device for machining mechanical parts, which comprises a workbench 1, wherein a gantry structure 2 is arranged on the workbench 1, a machining component 3 is arranged on the gantry structure 2, the machining component 3 comprises a transverse square column 31, the end part of the transverse square column 31 is rotationally connected with a rotary table 32, the peripheral side of the rotary table 32 is provided with a ring groove 33, the ring groove 33 is rotationally connected with the inner side of a driving bin 34, the peripheral side of one end of the rotary table 32 far from the transverse square column 31 is uniformly fixedly connected with a plurality of sleeves 35, the plurality of sleeves 35 are rotationally connected with a plurality of driving columns 36, one end of the plurality of driving columns 36 far from the rotary table 32 is fixedly connected with a plurality of cutters 37, the other end of the plurality of driving columns 36 is positioned in the rotary table 32 and fixedly connected with a plurality of face gears 313, the cutters 37 are different in types, and the cutters 37 positioned at the lowest position are used for cutting and machining work;

The transmission cavity 38 is formed in the position, close to the annular groove 33, inside the driving bin 34, the driving pulley 39 is rotatably connected to the upper portion in the transmission cavity 38, the driven pulley 310 is fixedly sleeved on the annular groove 33, the synchronous belt 311 is sleeved on the driving pulley 39 and the driven pulley 310, one side, far away from the rotary disc 32, of the top surface of the driving bin 34 is fixedly connected with the third servo speed reducing motor 312, the rotary shaft end of the third servo speed reducing motor 312 is fixedly connected with the rotary shaft end of the driving pulley 39, the rotary disc 32 is driven to rotate through the third servo speed reducing motor 312, the cutters 37 at different positions are placed at the lowest position, the effect of replacing the cutters 37 for machining is achieved, cutters are replaced in a mode of removing the cutters 37 without an additional cutter replacing mechanism, the cutter replacement is more convenient, and the overall machining efficiency is improved.

Example 2:

Referring to fig. 1-6, in the second embodiment of the present utility model, based on the previous embodiment, a plurality of driving gears 314 are rotatably connected to the turntable 32 near the plurality of face gears 313, a plurality of driving shafts 315 are horizontally fixedly connected to one end of the turntable 32 near the square column 31 at the rotation shaft of the plurality of driving gears 314, a plurality of positioning holes 316 are horizontally formed in the turntable 32 near the square column 31 at positions corresponding to the plurality of driving shafts 315, and a plurality of spline grooves 317 are formed at the ends of the plurality of driving shafts 315.

The sleeve member 318 is sleeved on the horizontal square column 31 in a sliding manner, a plurality of positioning columns 319 are fixedly connected to the side wall of the sleeve member 318 horizontally corresponding to the positions of the plurality of positioning hole slots 316, the plurality of positioning columns 319 are inserted into the plurality of positioning hole slots 316, the top surface of the horizontal square column 31 is fixedly connected with the electric push rod 320, and the output end of the electric push rod 320 is fixedly connected with the side wall of the top of the sleeve member 318.

The positioning column 319 and the sleeve member 318 which are positioned at the lowest part are internally rotated and sleeved with the driving rotating rod 321, one end of the driving rotating rod 321 close to the driving shaft 315 is fixedly connected with the spline head 322, the spline head 322 is inserted into the spline groove 317 of the driving shaft 315 which is positioned at the lowest part, the sleeve member 318 is far away from the bottom of one side of the turntable 32 and fixedly connected with the driving motor 323, the rotating shaft end of the driving motor 323 is fixedly connected with the end part of the driving rotating rod 321, after the cutter 37 which is processed is switched, the sleeve member 318 moves to enable the positioning column 319 to be inserted into the positioning hole groove 316, and meanwhile, the spline head 322 of the driving rotating rod 321 is inserted into the spline groove 317 of the driving shaft 315 which is positioned at the lowest part, and the cutter 37 which is used for processing is driven to rotate through the driving motor 323 to process.

The gantry structure 2 comprises two side plates 21, wherein the two side plates 21 are fixedly connected to two sides of the workbench 1, two sliding grooves 22 are formed in the top surfaces of the two side plates 21, two sliding blocks 23 are horizontally and movably connected in the two sliding grooves 22, two upright posts 24 are vertically and fixedly connected to the top surfaces of the two sliding blocks 23, a transverse frame 25 is fixedly connected between the top ends of the two upright posts 24, two transverse slide rails 26 are fixedly connected to one side of the transverse frame 25, sliding plates 27 are horizontally and slidably connected to the two transverse slide rails 26, two vertical slide rails 28 are fixedly connected to one side of the sliding plates 27, vertical sliding plates 29 are vertically and slidably connected to the two vertical slide rails 28, one ends of transverse square posts 31, which are far away from a turntable 32, are fixedly connected to the bottom end side walls of the vertical plates 29, two L-shaped brackets 324 are fixedly connected to two sides of the driving bin 34, and the ends of the two L-shaped brackets 324 are fixedly connected to the side walls of the vertical plates 29.

The first screw rod 211 is horizontally and rotatably connected in one sliding groove 22, the first threaded sleeve 212 is fixedly connected on the sliding block 23, the first screw rod 211 is in threaded connection with the first threaded sleeve 212, the end part of one side plate 21 is fixedly connected with the first servo gear motor 210, the rotating shaft end of the first servo gear motor 210 is fixedly connected with the end part of the first screw rod 211, one end of the transverse frame 25 is fixedly connected with the second servo gear motor 213, one side of the transverse frame 25, close to the sliding plate 27, is horizontally and rotatably connected with the second screw rod 214, the sliding plate 27 is fixedly connected with the second threaded sleeve 215, the second screw rod 214 is in threaded connection with the second threaded sleeve 215, the rotating shaft end of the second servo gear motor 213 is fixedly connected with the end part of the second screw rod 214, the sliding plate 27 is vertically and fixedly connected with the electric cylinder 216, the top end of the output end of the electric cylinder 216 is fixedly connected with the top end of the vertical plate 29, and the gantry structure 2 adopts triaxial movement, so that the processing assembly 2 can be conveniently placed at a proper position.

Example 3:

Referring to fig. 1-6, in a third embodiment of the present utility model, when the present utility model is used, based on the two embodiments, a fixture for carrying a dual-axis movement of a workpiece is installed on the workbench 1, after the workpiece is fixed, the workpiece is machined by the machining assembly 3, during machining, when the tool 37 needs to be replaced, the electric push rod 320 drives the sleeve 318 to move so that the positioning column 319 leaves the positioning hole 316, contacts the turntable 32 to limit, the electric push rod 320 drives the turntable 32 to rotate so that the required tool 37 moves to the lowest, and then the electric push rod 320 drives the sleeve 318 to return to the original position, limiting the turntable 32 to realize tool replacement, the angle steel bracket 3 of the present utility model adopts a plurality of different types of tools 37, wherein the tools 37 positioned at the lowest position are used for cutting machining work, and the cutter 37 positioned at the lowest position is driven by the third servo speed reducing motor 312 to rotate so as to realize the effect of replacing the tool 37 for machining, and the tool 37 does not need to be replaced by an additional tool replacing mechanism, thus improving the overall machining efficiency.

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

Claims (6)

1. Cutting device for machining mechanical parts, comprising a table (1), characterized in that:

The automatic cutting machine is characterized in that a gantry structure (2) is arranged on the workbench (1), a machining assembly (3) is arranged on the gantry structure (2), the machining assembly (3) comprises a horizontal square column (31), the end part of the horizontal square column (31) is rotationally connected with a rotary table (32), a circular groove (33) is formed in the periphery of the rotary table (32), the circular groove (33) is rotationally connected with the inner side of a driving bin (34), one end periphery of the rotary table (32) far away from the horizontal square column (31) is uniformly fixedly connected with a plurality of sleeves (35), a plurality of driving columns (36) are rotationally connected with one end of the sleeve (35), a plurality of driving columns (36) are fixedly connected with a plurality of cutters (37) far away from one end of the rotary table (32), and the other end of the driving columns (36) are positioned in the rotary table (32) and fixedly connected with a plurality of face gears (313), and the types of the cutters (37) are different;

The driving device is characterized in that a transmission cavity (38) is formed in the driving bin (34) and close to the ring groove (33), a driving belt pulley (39) is connected to the upper portion in the transmission cavity (38) in a rotating mode, a driven belt pulley (310) is fixedly sleeved on the ring groove (33), a synchronous belt (311) is sleeved on the driving belt pulley (39) and the driven belt pulley (310), a third servo speed reducing motor (312) is fixedly connected to the top surface of the driving bin (34) at one side far away from the turntable (32), and a rotating shaft end of the driving belt pulley (39) is fixedly connected to the rotating shaft end of the third servo speed reducing motor (312).

2. The cutting device for machining mechanical parts according to claim 1, wherein a plurality of driving gears (314) are rotatably connected to the inside of the turntable (32) at positions close to the plurality of face gears (313), a plurality of driving shafts (315) are horizontally fixedly connected to one ends of the rotating shafts of the driving gears (314) close to the transverse square columns (31), a plurality of positioning hole grooves (316) are horizontally formed in the side, close to the transverse square columns (31), of the turntable (32) corresponding to the plurality of driving shafts (315), and a plurality of spline grooves (317) are formed in the ends of the driving shafts (315).

3. The cutting device for machining mechanical parts according to claim 2, wherein a sleeve member (318) is horizontally sleeved on the horizontal square column (31) in a sliding manner, a plurality of positioning columns (319) are horizontally fixedly connected to the side wall of the sleeve member (318) corresponding to the positions of a plurality of positioning hole slots (316), a plurality of positioning columns (319) are inserted into the positioning hole slots (316), an electric push rod (320) is fixedly connected to the top surface of the horizontal square column (31), and the output end of the electric push rod (320) is fixedly connected to the side wall of the top of the sleeve member (318).

4. The cutting device for machining mechanical parts according to claim 3, wherein the locating column (319) and the sleeve (318) which are located at the lowest position are internally and rotatably sleeved with the driving rotating rod (321), one end, close to the driving shaft (315), of the driving rotating rod (321) is fixedly connected with the spline head (322), the spline head (322) is inserted into the spline groove (317) of the driving shaft (315) which is located at the lowest position, the bottom of one side, far away from the turntable (32), of the sleeve (318) is fixedly connected with the driving motor (323), and the rotating shaft end of the driving motor (323) is fixedly connected with the end part of the driving rotating rod (321).

5. The cutting device for machining mechanical parts according to claim 1, wherein the gantry structure (2) comprises two side plates (21), the two side plates (21) are fixedly connected to two sides of the workbench (1), the two top surfaces of the two side plates (21) are provided with two sliding grooves (22), the two sliding grooves (22) are internally and horizontally and smoothly connected with two sliding blocks (23), the top surfaces of the two sliding blocks (23) are vertically fixedly connected with two upright posts (24), a transverse frame (25) is fixedly connected between the top ends of the two upright posts (24), one side of the transverse frame (25) is fixedly connected with two transverse sliding rails (26), the two transverse sliding rails (26) are horizontally and slidingly connected with sliding plates (27), one side of the sliding plates (27) is far away from the transverse frame (25) and fixedly connected with two vertical sliding rails (28), one end of each transverse square post (31) far away from the turntable (32) is fixedly connected to the bottom side wall of the vertical sliding plates (29), two sides of each driving bin (34) are fixedly connected with two L-shaped side walls (324) of the two L-shaped brackets (324).

6. The cutting device for machining mechanical parts according to claim 5, wherein one sliding groove (22) is horizontally and rotatably connected with a first screw rod (211), a sliding block (23) is fixedly connected with a first threaded sleeve (212), the first screw rod (211) is in threaded connection with the first threaded sleeve (212), one end of the side plate (21) is fixedly connected with a first servo gear motor (210), a rotating shaft of the first servo gear motor (210) is fixedly connected with the end of the first screw rod (211), one end of a transverse frame (25) is fixedly connected with a second servo gear motor (213), one side of the transverse frame (25) close to a sliding plate (27) is horizontally and rotatably connected with a second screw rod (214), the sliding plate (27) is fixedly connected with a second threaded sleeve (215), the second screw rod (214) is in threaded connection with the end of the second threaded sleeve (215), the sliding plate (27) is vertically and fixedly connected with an electric cylinder (216), and the output end of the electric cylinder (216) is fixedly connected with the top end of the vertical plate (29).