CN115592432A - High-precision finish machining system for aluminum alloy - Google Patents

Abstract

The invention relates to the technical field of metal processing equipment, in particular to an aluminum alloy high-precision finish machining system which comprises a base, wherein a cutting machine is arranged at the top end of the base, a supporting mechanism is arranged on one side of the cutting machine, a clamping mechanism is arranged at the top end of the supporting mechanism, conveying mechanisms are arranged on two sides of the clamping mechanism, and one side of the supporting mechanism is connected with a synchronizing mechanism; the workpiece is conveyed to the rotary table through the first conveyor, the rotary table drives the workpiece to rotate, the adjusting plate and the clamping plate are automatically driven to move, the workpiece is clamped, finish machining is performed through the cutting machine, the workpiece is driven to the position above the discharge groove after machining is completed, the first sliding rod is released on the driving disc, the adjusting plate and the clamping plate do not clamp the workpiece, the workpiece falls onto the second conveyor through the discharge groove, the machined workpiece is conveyed to a proper position through the second conveyor, the whole conveying and dismounting are automatic, the dismounting and mounting of the workpiece are orderly executed, and the machining efficiency is greatly improved.

Description

High-precision finish machining system for aluminum alloy

Technical Field

The invention relates to the technical field of metal processing equipment, in particular to an aluminum alloy high-precision finish machining system.

Background

In the production of some anisotropic aluminum alloy products, such as engine housings and the like, a rough product having a rough shape is obtained by casting, and then the outer shape of the rough product and each of the connection end surfaces need to be subjected to cutting and finishing.

However, when processing aluminum alloy products, the conventional processing equipment needs manual operation to fix the workpiece, which is very troublesome to disassemble and assemble, and when performing batch manufacturing and processing, the processing equipment is particularly labor-consuming and time-consuming, has low processing efficiency, and is easy to neglect in manual operation, which causes a series of quality problems such as processing precision and the like due to untight clamping.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a high-precision finish machining system for aluminum alloy.

The technical scheme adopted by the invention for solving the technical problems is as follows: the utility model provides an aluminum alloy high accuracy finish machining system, includes the base, the top of base is equipped with the miller, one side of miller is equipped with supporting mechanism, supporting mechanism's top is equipped with presss from both sides the material mechanism, it is equipped with conveying mechanism to press from both sides material mechanism both sides, one side of supporting mechanism is connected with lazytongs, supporting mechanism passes through lazytongs drive conveying mechanism and presss from both sides material mechanism synchronous operation.

Specifically, the supporting mechanism includes the base, one side of miller is equipped with the base, base fixed connection is on the base, the top fixedly connected with tray of base, the top of tray is rotated and is connected with the carousel, the inside fixedly connected with fixed axle of base, the fixed axle runs through the inside that the tray extends to the carousel, the fixed axle rotates and connects the carousel, the outside cover of fixed axle has the sleeve pipe, the bottom fixed connection of sleeve pipe and carousel, row's silo has been seted up to one side of tray, be equipped with a plurality of balls on the tray.

Specifically, the supporting mechanism still includes driving motor, the internally mounted of base has driving motor, fixedly connected with driving piece on driving motor's the motor shaft, sheathed tube bottom fixedly connected with sheave, sheave and driving piece use of mutually supporting, driving motor passes through driving piece, sheave drive sleeve pipe intermittent type and rotates.

Specifically, the clamping mechanism includes the driving-disc, the inside of carousel rotates and is equipped with the driving-disc, the top fixed connection of driving-disc and fixed axle, spacing spout has been seted up to the inside of driving-disc, the inside sliding connection of carousel has a plurality of first slide bars, the first slider of one end fixedly connected with of first slide bar, first slider passes through spacing spout and driving-disc sliding connection, the driving-disc passes through spacing spout, the first slide bar axial reciprocating motion of first slider drive.

Concretely, the clamping mechanism still includes the adjusting plate, first slide bar is located the outside one end fixedly connected with adjusting plate of carousel, fixedly connected with becomes the synchronization frame of U word form on the first slide bar, synchronization frame sliding connection is in the inside of carousel, the both ends of synchronization frame are equipped with a second slider respectively, be equipped with the hang plate that is the slope setting on the second slider, be equipped with the second slide bar on the second slider, second slide bar sliding connection is in the carousel, second slide bar and hang plate sliding connection, the second slider passes through the activity of hang plate drive second slide bar, the second slide bar is located the outside one end fixedly connected with splint of carousel, adjusting plate and the common centre gripping work piece of two splint.

Specifically, conveying mechanism includes first conveyer and second conveyer, one side of base is equipped with first conveyer and the opposite side is equipped with the second conveyer, first conveyer flushes with the tray, the second conveyer is located the bottom side of arranging the silo, first conveyer and second conveyer install the top side at the base jointly.

Specifically, the synchronizing mechanism includes the transmission case, one side of base is equipped with the transmission case, the transmission case is installed on the top side of base, it is connected with first transmission shaft to rotate between base and the transmission case for drive first conveyer pivoted second transmission shaft extends to the inside of transmission case, the one end fixedly connected with second bevel gear and the other end fixedly connected with third bevel gear of first transmission shaft, the first bevel gear of fixedly connected with on the motor shaft of driving motor, first bevel gear and second bevel gear mesh mutually, the internally mounted of transmission case has the axle bed, second transmission shaft and axle bed rotate and connect, the last fixedly connected with fourth bevel gear of second transmission shaft, fourth bevel gear and third bevel gear mesh mutually.

Concretely, lazytongs still includes the third transmission shaft for the drive the third transmission shaft of second conveyer extends to the inside of transmission case, second transmission shaft, third transmission shaft are located the inside one end difference fixedly connected with lug of transmission case, the inside swing joint of lug has universal ball, sliding connection has the telescopic link on the universal ball, the inside fixedly connected with third slide bar of transmission case, swing joint has the rod cover on the third slide bar, two telescopic link and rod cover welding are in the same place.

The invention has the beneficial effects that:

(1) According to the aluminum alloy high-precision finish machining system, a workpiece is conveyed to the rotary table through the first conveyor, the rotary table drives the workpiece to rotate, the adjusting plate and the clamping plate are automatically driven to move, the workpiece is fastened, then finish machining is carried out through the cutting machine, the workpiece is driven to the position above the discharge groove after machining is finished, the first sliding rod is released on the driving disc, the adjusting plate and the clamping plate do not clamp the workpiece, the workpiece falls onto the second conveyor through the discharge groove, the machined workpiece is conveyed to the proper position through the second conveyor, the whole conveying and dismounting are automatic, the dismounting and mounting of the workpiece are performed orderly, and the machining efficiency is greatly improved.

(2) According to the aluminum alloy high-precision finish machining system, the driving motor for driving the clamping workpiece synchronously drives the second transmission shaft and the third transmission shaft to rotate together through the bevel gears, so that the first conveyor and the second conveyor run in a mode of matching with the moving frequency of the rotary table, the synchronism and the conveying effect are greatly improved, the problems of material blockage, untimely feeding and the like are avoided, the transmission rate can be automatically adjusted along with the change of the machining rate, and the use of equipment is not worry.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic structural diagram of the overall structure of a preferred embodiment of an aluminum alloy high-precision finishing system provided by the present invention;

FIG. 2 is a schematic view of a connection structure of the supporting mechanism and the synchronizing mechanism shown in FIG. 1;

figure 3 is a schematic view of the sheave and drive member shown in figure 2;

FIG. 4 is a schematic view of a connection structure of the supporting mechanism and the clamping mechanism shown in FIG. 1;

fig. 5 is a schematic structural view of the synchronization mechanism shown in fig. 1.

In the figure: 1. a base; 2. a cutting machine; 3. a support mechanism; 31. a base; 32. a tray; 33. a turntable; 34. a fixed shaft; 35. a sleeve; 36. a sheave; 37. a drive member; 38. a drive motor; 39. a discharge chute; 391. a ball bearing; 4. a material clamping mechanism; 41. a drive disc; 42. a limiting chute; 43. a first slide bar; 44. a first slider; 45. an adjustment plate; 46. a synchronous frame; 47. a second slider; 48. an inclined plate; 49. a second slide bar; 491. a splint; 5. a conveying mechanism; 51. a first conveyor; 52. a second conveyor; 6. a synchronization mechanism; 61. a transmission case; 62. a first bevel gear; 63. a first drive shaft; 64. a second bevel gear; 65. a third bevel gear; 66. a second transmission shaft; 67. a fourth bevel gear; 68. a shaft seat; 69. a third transmission shaft; 691. a third slide bar; 692. a rod sleeve; 693. a telescopic rod; 694. a bump; 695. a universal ball.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1-5, the high-precision finish machining system for the aluminum alloy comprises a base 1, wherein a cutting machine 2 is arranged at the top end of the base 1, a supporting mechanism 3 is arranged on one side of the cutting machine 2, a clamping mechanism 4 is arranged at the top end of the supporting mechanism 3, conveying mechanisms 5 are arranged on two sides of the clamping mechanism 4, one side of the supporting mechanism 3 is connected with a synchronizing mechanism 6, and the conveying mechanisms 5 and the clamping mechanism 4 are driven by the supporting mechanism 3 to synchronously operate through the synchronizing mechanism 6.

Specifically, supporting mechanism 3 includes base 31, one side of miller 2 is equipped with base 31, base 31 fixed connection is on base 1, the top fixedly connected with tray 32 of base 31, the top of tray 32 is rotated and is connected with carousel 33, the inside fixedly connected with fixed axle 34 of base 31, fixed axle 34 runs through the inside that tray 32 extends to carousel 33, fixed axle 34 rotates and connects carousel 33, the outside cover of fixed axle 34 has sleeve pipe 35, the bottom fixed connection of sleeve pipe 35 and carousel 33, row's material groove 39 has been seted up to one side of tray 32, be equipped with a plurality of balls 391 on the tray 32.

Specifically, the supporting mechanism 3 further includes a driving motor 38, the driving motor 38 is installed inside the base 31, a driving member 37 is fixedly connected to a motor shaft of the driving motor 38, a sheave 36 is fixedly connected to the bottom end of the sleeve 35, the sheave 36 and the driving member 37 are used in cooperation with each other, and the driving motor 38 drives the sleeve 35 to intermittently rotate through the driving member 37 and the sheave 36.

Specifically, material clamping mechanism 4 includes driving-disc 41, the inside of carousel 33 rotates and is equipped with driving-disc 41, the top fixed connection of driving-disc 41 and fixed axle 34, spacing spout 42 has been seted up to the inside of driving-disc 41, the inside sliding connection of carousel 33 has a plurality of first slide bars 43, the one end fixed connection of first slide bar 43 has first slider 44, first slider 44 passes through spacing spout 42 and driving-disc 41 sliding connection, driving-disc 41 passes through spacing spout 42, the first slide bar 43 of first slider 44 drive axial reciprocating motion.

Specifically, the clamping mechanism 4 further includes an adjusting plate 45, one end of the first slide rod 43 located outside the rotary table 33 is fixedly connected with the adjusting plate 45, the first slide rod 43 is fixedly connected with a U-shaped synchronization frame 46, the synchronization frame 46 is slidably connected inside the rotary table 33, two ends of the synchronization frame 46 are respectively provided with a second slide block 47, the second slide block 47 is provided with an inclined plate 48 arranged in an inclined manner, the second slide block 47 is provided with a second slide rod 49, the second slide rod 49 is slidably connected to the rotary table 33, the second slide rod 49 is slidably connected with the inclined plate 48, the second slide block 47 drives the second slide rod 49 to move through the inclined plate 48, one end of the second slide rod 49 located outside the rotary table 33 is fixedly connected with a clamping plate 491, and the adjusting plate 45 and the two clamping plates 491 clamp the workpiece together; in the procedure of driving the workpiece to move, when the corresponding first slide block 44 moves to another position of the limiting chute 42, the first slide bar 43 is driven to be away from the fixed shaft 34, the first slide bar 43 pushes the adjusting plate 45 to contact the workpiece, the first slide bar 43 is fixedly connected with the synchronous frame 46, the synchronous frame 46 moves to drive the second slide blocks 47 at two ends, the second slide blocks 47 drive the second slide bars 49 to move through the inclined plates 48, so that the two clamping plates 491 are close to each other, the process of clamping the two sides of the workpiece is completed, then the workpiece is transferred to the bottom end position of the cutting machine 2 along with the further rotation of the rotary disc 33, the cutting machine 2 starts to process the workpiece, the processed workpiece is transferred to the position close to the groove 39, the first slide block 44 is reset at this time, the adjusting plate 45 and the clamping plates 491 are not in clamping, the workpiece falls onto the second conveyor 52 under the action of gravity, the second conveyor moves the finished workpiece to the other position, the finished workpiece is discharged, and the processing efficiency is greatly improved, and the processing procedure is realized.

Specifically, the conveying mechanism 5 comprises a first conveyor 51 and a second conveyor 52, the first conveyor 51 is arranged on one side of the base 31, the second conveyor 52 is arranged on the other side of the base, the first conveyor 51 is flush with the tray 32, the second conveyor 52 is positioned on the bottom side of the discharging groove 39, and the first conveyor 51 and the second conveyor 52 are jointly installed on the top side of the base 1; the driving motor 38 is firstly started, the driving motor 38 drives the driving member 37 to rotate, then the driving member 37 engages with the grooved wheel 36, the grooved wheel 36 rotates 90 degrees, since the grooved wheel 36 is fixedly connected with the rotary disc 33 through the sleeve 35, the rotary disc 33 is driven to rotate synchronously, a workpiece is conveyed to a corresponding notch of the rotary disc 33 through the first conveyor 51, then the rotary disc 33 drives the workpiece to rotate around the fixed shaft 34, the plurality of balls 391 are arranged on the tray 32, and the balls 391 are in rolling connection with the workpiece, so that friction force between the moving workpiece and the fixed tray 32 can be reduced, and the bottom of the workpiece is prevented from being abraded.

Specifically, the synchronizing mechanism 6 includes a transmission case 61, one side of the base 31 is provided with the transmission case 61, the transmission case 61 is installed on the top side of the base 1, a first transmission shaft 63 is rotatably connected between the base 31 and the transmission case 61 and is used for driving a second transmission shaft 66 of the first conveyor 51 to rotate to extend into the transmission case 61, one end of the first transmission shaft 63 is fixedly connected with a second bevel gear 64 and the other end of the first transmission shaft is fixedly connected with a third bevel gear 65, a motor shaft of the driving motor 38 is fixedly connected with a first bevel gear 62, the first bevel gear 62 is meshed with the second bevel gear 64, an axle seat 68 is installed inside the transmission case 61, the second transmission shaft 66 is rotatably connected with the axle seat 68, a fourth bevel gear 67 is fixedly connected to the second transmission shaft 66, and the fourth bevel gear 67 is meshed with the third bevel gear 65.

Specifically, the synchronizing mechanism 6 further includes a third transmission shaft 69, the third transmission shaft 69 is used for driving the second conveyor 52 to extend into the transmission case 61, one end of each of the second transmission shaft 66 and the third transmission shaft 69, which is located inside the transmission case 61, is fixedly connected with a bump 694, a universal ball 695 is movably connected inside the bump 694, an expansion rod 693 is slidably connected to the universal ball 695, a third slide bar 691 is fixedly connected inside the transmission case 61, a rod sleeve 692 is movably connected to the third slide bar 691, and the two expansion rods 693 and the rod sleeve 692 are welded together; in order to match the frequency and speed of taking out the workpieces by the rotary table 33, the driving motor 38 drives the first transmission shaft 63 to rotate through the first bevel gear 62 and the second bevel gear 64, then the first transmission shaft 63 drives the second transmission shaft 66 to rotate through the third bevel gear 65 and the fourth bevel gear 67, the first conveyor 51 is driven to operate by the second transmission shaft 66, the function of conveying the workpieces intermittently by the first conveyor 51 is achieved, the frequency and speed of movement of the first conveyor 51 are equal to those of the rotary table 33, the matching effect is better, then the second transmission shaft 66 drives the telescopic rod 693 through the lug 694 and the universal ball 695, the rod sleeve 692 swings back and forth along the third sliding rod 691 at the left and right, so that the third transmission shaft 69 rotates at the same speed, the moving mode of the first conveyor 51 is copied onto the second conveyor 52, the purpose of synchronously conveying the workpieces is also achieved, the matching effect between the rod sleeve 692 and the third transmission shaft 692 is better, the movable mode of connecting the second transmission shaft 66 with the second transmission shaft 692 and the third transmission shaft 69 is copied onto the second conveyor 52 at the same speed, even if the problem of different heights of simultaneous conveying and the two transmission shafts are solved, even if the problem of the labor-saving and the different transmission speed is solved, and the problem of the problem that the process is solved at the later stage, and the problem that the process is not changed in time, the process is solved.

When the automatic workpiece feeding device is used, firstly, the driving motor 38 is started, the driving motor 38 drives the driving part 37 to rotate, then the driving part 37 is meshed with the grooved wheel 36, the grooved wheel 36 rotates 90 degrees, the grooved wheel 36 is fixedly connected with the rotary table 33 through the sleeve 35, the rotary table 33 is driven to synchronously rotate, a workpiece is conveyed to a corresponding notch of the rotary table 33 through the first conveyor 51, then the rotary table 33 drives the workpiece to rotate around the fixed shaft 34, the tray 32 is provided with a plurality of balls 391, and the balls 391 are in rolling connection with the workpiece, so that the friction force between the workpiece moving and the fixed tray 32 can be reduced, and the bottom of the workpiece is prevented from being abraded; in the procedure of driving the workpiece to move, when the corresponding first slide block 44 moves to another position of the limiting chute 42, the first slide bar 43 is driven to be away from the fixed shaft 34, the first slide bar 43 pushes the adjusting plate 45 to contact the workpiece, the first slide bar 43 is fixedly connected with the synchronizing frame 46, the synchronizing frame 46 moves to drive the second slide blocks 47 at two ends, the second slide blocks 47 drive the second slide bars 49 to move through the inclined plates 48, so that the two clamping plates 491 are close to each other, the two sides of the workpiece are clamped, the process of clamping the workpiece is completed, then the workpiece is transferred to the bottom end position of the cutting machine 2 along with the further rotation of the rotary table 33, the cutting machine 2 starts to process the workpiece, the processed workpiece is transferred to the position close to the discharging chute 39, at this time, the first slide block 44 is reset, the adjusting plates 45 and the clamping plates 491 are not clamping the workpiece, the workpiece falls onto the second conveyor 52 under the action of gravity, the finished product is transferred to the subsequent process by the second conveyor 52, the currently unused clamping plates 491 and the like can continuously clamp the next conveyed workpiece, so as a reciprocating process, the workpiece is realized, the process of material is greatly improved, and the process efficiency is greatly improved; in order to match the frequency and speed of the workpiece taken by the rotary plate 33, the driving motor 38 drives the first transmission shaft 63 to rotate through the first bevel gear 62 and the second bevel gear 64, then the first transmission shaft 63 drives the second transmission shaft 66 to rotate through the third bevel gear 65 and the fourth bevel gear 67, the first conveyor 51 is driven to operate by the second transmission shaft 66, the function of conveying the workpiece intermittently by the first conveyor 51 is realized, the moving frequency and speed of the first conveyor 51 are equal to those of the rotary plate 33, the matching effect is better, then the second transmission shaft 66 drives the telescopic rod 693 through the projection 694 and the universal ball 695, the rod sleeve 692 swings up and down and left and right along the third slide rod 691 in a reciprocating manner, and the third transmission shaft 69 is driven to rotate at the same speed, copy first conveyer 51's movable mode to second conveyer 52 on, the purpose of conveying the work piece in step is realized equally, make the cooperation effect between each other better, rod cover 692 mainly plays the purpose of connecting second transmission shaft 66 and third transmission shaft 69, even both are in the horizontal height of difference and position also can the synchronous activity, fundamental solution carry putty or carry untimely scheduling problem, the different work piece speed of later stage processing is different in addition, when changing process rate, through above transmission mode, carry also synchronous change, need not to carry out the process of a debugging again, use more save worry laborsaving.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. The utility model provides an aluminum alloy high accuracy finish machining system, its characterized in that, includes base (1), the top of base (1) is equipped with miller (2), one side of miller (2) is equipped with supporting mechanism (3), the top of supporting mechanism (3) is equipped with presss from both sides material mechanism (4), it is equipped with conveying mechanism (5) to press from both sides material mechanism (4) both sides, one side of supporting mechanism (3) is connected with lazytongs (6), supporting mechanism (3) are through lazytongs (6) drive conveying mechanism (5) and press from both sides material mechanism (4) synchronous motion.

2. A high-precision finish machining system for aluminum alloy according to claim 1, wherein the supporting mechanism (3) comprises a base (31), the base (31) is arranged on one side of the cutting machine (2), the base (31) is fixedly connected to the base (1), a tray (32) is fixedly connected to the top end of the base (31), a turntable (33) is rotatably connected to the top end of the tray (32), a fixing shaft (34) is fixedly connected to the inside of the base (31), the fixing shaft (34) penetrates through the tray (32) and extends to the inside of the turntable (33), the fixing shaft (34) is rotatably connected to the turntable (33), a sleeve (35) is sleeved on the outside of the fixing shaft (34), the sleeve (35) is fixedly connected to the bottom end of the turntable (33), a discharging groove (39) is formed in one side of the tray (32), and a plurality of balls (391) are arranged on the tray (32).

3. A high-precision finish machining system for aluminum alloy according to claim 2, wherein the supporting mechanism (3) further comprises a driving motor (38), the driving motor (38) is installed inside the base (31), a driving member (37) is fixedly connected to a motor shaft of the driving motor (38), a grooved wheel (36) is fixedly connected to a bottom end of the sleeve (35), the grooved wheel (36) and the driving member (37) are used in cooperation, and the driving motor (38) drives the sleeve (35) to intermittently rotate through the driving member (37) and the grooved wheel (36).

4. A high-precision finish machining system for aluminum alloy according to claim 3, wherein the clamping mechanism (4) comprises a driving disc (41), the driving disc (41) is rotatably arranged inside the rotary disc (33), the top end of the driving disc (41) is fixedly connected with the top end of the fixed shaft (34), a limiting sliding groove (42) is formed inside the driving disc (41), a plurality of first sliding rods (43) are slidably connected inside the rotary disc (33), a first sliding block (44) is fixedly connected to one end of each first sliding rod (43), the first sliding blocks (44) are slidably connected with the driving disc (41) through the limiting sliding grooves (42), and the driving disc (41) drives the first sliding rods (43) to axially reciprocate through the limiting sliding grooves (42) and the first sliding blocks (44).

5. A high accuracy finish machining system of aluminum alloy according to claim 4, characterized in that said clamping mechanism (4) further comprises an adjusting plate (45), one end of said first sliding rod (43) located outside of the rotary table (33) is fixedly connected with said adjusting plate (45), said first sliding rod (43) is fixedly connected with a U-shaped synchronization frame (46), said synchronization frame (46) is slidably connected inside of the rotary table (33), two ends of said synchronization frame (46) are respectively provided with a second sliding block (47), said second sliding block (47) is provided with an inclined plate (48) which is obliquely arranged, said second sliding block (47) is provided with a second sliding rod (49), said second sliding rod (49) is slidably connected with the rotary table (33), said second sliding rod (49) is slidably connected with the inclined plate (48), said second sliding block (47) drives the second sliding rod (49) to move through the inclined plate (48), one end of said second sliding rod (49) located outside of the rotary table (33) is fixedly connected with a clamping plate (491), said adjusting plate (45) and two clamping plates (45) clamp the workpiece together.

6. A high precision finishing system for aluminium alloy according to claim 3, characterized in that the conveying mechanism (5) comprises a first conveyor (51) and a second conveyor (52), one side of the base (31) is provided with the first conveyor (51) and the other side is provided with the second conveyor (52), the first conveyor (51) and the tray (32) are flush, the second conveyor (52) is located at the bottom side of the discharge chute (39), and the first conveyor (51) and the second conveyor (52) are jointly mounted at the top side of the base (1).

7. A high-precision finish machining system for aluminum alloy according to claim 6, characterized in that the synchronizing mechanism (6) comprises a transmission case (61), a transmission case (61) is arranged on one side of the base (31), the transmission case (61) is installed on the top side of the base (1), a first transmission shaft (63) is rotatably connected between the base (31) and the transmission case (61), a second transmission shaft (66) for driving the first conveyor (51) to rotate extends into the transmission case (61), a second bevel gear (64) is fixedly connected to one end of the first transmission shaft (63) and a third bevel gear (65) is fixedly connected to the other end of the first transmission shaft, a first bevel gear (62) is fixedly connected to a motor shaft of the driving motor (38), the first bevel gear (62) is meshed with the second bevel gear (64), a shaft seat (68) is installed inside the transmission case (61), the second transmission shaft (66) is rotatably connected with the shaft seat (68), a fourth bevel gear (67) is fixedly connected to the second transmission shaft (66), and the fourth bevel gear (65) is meshed with the third bevel gear (65).

8. A high-precision finish machining system for aluminum alloy according to claim 7, characterized in that the synchronizing mechanism (6) further comprises a third transmission shaft (69) for driving the third transmission shaft (69) of the second conveyor (52) to extend into the transmission box (61), one end of each of the second transmission shaft (66) and the third transmission shaft (69) located inside the transmission box (61) is fixedly connected with a lug (694), the inner part of the lug (694) is movably connected with a universal ball (695), the universal ball (695) is slidably connected with a telescopic rod (693), the inner part of the transmission box (61) is fixedly connected with a third slide bar (691), the third slide bar (691) is movably connected with a bar sleeve (692), and the two telescopic rods (693) and the bar sleeve (692) are welded together.

Images