CN115570389A - Aluminum alloy production equipment - Google Patents

Abstract

The invention relates to the technical field of aluminum alloy processing, more specifically, an aluminum alloy production equipment; an aluminum alloy production equipment, including a chassis, a slide plate, a shaft frame, a grinding wheel A, a grinding shaft, a grinding ring, and a driving shaft , pulley A, push block, grinding wheel B, push plate and push groove, the slide plate is slidably connected to the bottom frame, two springs are fixedly connected between the slide plate and the bottom frame, two axle frames are slidably connected on the slide plate, two The shaft brackets are all rotatably connected to the grinding shaft, and the grinding ring is slidably connected to the grinding shaft. The grinding ring clamps the grinding wheel A on the grinding shaft through five bolts. The rear end of the grinding shaft is fixedly connected with the drive shaft. The rear end is fixedly connected with pulley A, the push plate is slidably connected to the slide plate, two springs are fixedly connected between the push plate and the slide plate, a push groove is opened on the push plate, and a push block is slidingly connected in the push groove; Burrs on part cutouts are automatically cleaned.

Description

A kind of aluminum alloy production equipment

technical field

The invention relates to the technical field of aluminum alloy processing, in particular to an aluminum alloy production equipment.

Background technique

Aluminum alloy is the most widely used non-ferrous metal structural material in industry. It has been widely used in aviation, aerospace, automobile, machinery manufacturing, shipbuilding and chemical industry. With the rapid development of industrial economy, the demand for aluminum alloy structural parts is increasing, and the research on the processability of aluminum alloy is also in-depth. Aluminum alloy is currently the most widely used alloy. Aluminum is easy to process, can be made into various profiles and plates, and has good corrosion resistance. However, the strength of pure aluminum is very low, so it is not suitable for structural materials. Through long-term production practice and scientific experiments, people have gradually strengthened aluminum by adding alloying elements and using heat treatment, which resulted in a series of aluminum alloys. Aluminum alloys usually need to be cut to obtain a suitable length during use. However, due to the material characteristics of aluminum alloys, burrs often appear at the incisions of aluminum alloys. After the burrs are found, they need to be cleaned manually with a grinder, which increases labor intensity. , and it is easy to cause injury to the operator.

Current aluminum alloy production equipment lacks a kind of aluminum alloy production equipment that can automatically clean the burrs on the aluminum alloy part cut.

Contents of the invention

In order to overcome the deficiencies of the prior art, the invention provides an aluminum alloy production equipment, which can automatically clean the burrs on the cuts of aluminum alloy parts.

The technical solution adopted by the present invention to solve its technical problems is:

An aluminum alloy production equipment, comprising a base frame, a slide plate, a shaft frame, a grinding wheel A, a grinding shaft, a grinding ring, a drive shaft and a pulley A, the slide plate is slidably connected to the base frame, and the slide plate and the base frame are fixedly connected by a Two springs, slidingly connected to two axle frames on the slide plate, both axle frames are rotatably connected to the grinding shaft, and the grinding ring is slidingly connected to the grinding shaft, and the grinding ring clamps the grinding wheel A on the grinding shaft through five bolts. On the grinding shaft, the rear end of the grinding shaft is fixedly connected with the driving shaft, and the rear end of the driving shaft is fixedly connected with the belt pulley A.

It also includes a push block, a grinding wheel B, a push plate, a turning block and a push groove. The push plate is slidably connected to the slide plate, and two springs are fixedly connected between the push plate and the slide plate. A push block is slidingly connected, a spring is fixedly connected between the push block and the push plate, the front end of the push block is rotatably connected with a grinding wheel B, the grinding wheel B is driven by a drive shaft belt, and the turning block is rotatably connected on the slide plate.

It also includes a cutting shaft, a cutting piece 1 and a pulley B. The cutting piece is rotatably connected to the slide plate. The rear end of the cutting piece is fixedly connected with a cutting shaft.

Description of drawings

The present invention will be described in further detail below in conjunction with the accompanying drawings and specific implementation methods.

Fig. 1 is the structural representation of a kind of aluminum alloy production equipment among the present invention;

Fig. 2 is the structural representation of underframe and slide plate in the present invention;

Fig. 3 is the structural representation of slide plate and turning block among the present invention;

Fig. 4 is the structural representation of grinding wheel B and push plate among the present invention;

Fig. 5 is the structural representation of slide plate and cutting piece among the present invention;

Fig. 6 is the structural representation of gear B and gear C in the present invention;

Fig. 7 is the structural representation of clamp ring and underframe among the present invention;

Fig. 8 is the plane view of clamp ring and friction wheel E among the present invention;

Fig. 9 is a schematic structural view of clamping blocks in the present invention;

Fig. 10 is a structural schematic diagram of friction wheel D and friction wheel E in the present invention;

Fig. 11 is the plane view of electromagnet and grinding shaft in the present invention;

Fig. 12 is a schematic structural view of a collection box in the present invention;

Fig. 13 is the structural representation of guide wheel and underframe among the present invention;

Fig. 14 is a structural schematic diagram of a brake block and a slide plate in the present invention.

detailed description

Referring to Figures 1 to 3, the process of grinding the burrs on the outer surface of the aluminum alloy cut can be obtained according to the figures:

The present invention comprises bottom frame 1, slide plate 2, axle frame 3, grinding wheel A4, grinding shaft 5, pressure grinding ring 6, driving shaft 7 and pulley A8, and slide plate 2 is slidingly connected on the bottom frame 1, and slide plate 2 and bottom frame 1 Two springs are fixedly connected between them, and two axle frames 3 are slidably connected on the slide plate 2, and the two axle frames 3 are both rotatably connected to the grinding shaft 5, and the grinding ring 6 is slidingly connected to the grinding shaft 5, and the grinding ring 6. The grinding wheel A4 is clamped on the grinding shaft 5 by five bolts. The rear end of the grinding shaft 5 is fixedly connected to the driving shaft 7, and the rear end of the driving shaft 7 is fixedly connected to the pulley A8. Accompanied by the appearance of burrs, burrs will affect the connection between various aluminum alloy parts during use, causing problems such as unstable connection and uneven connection. Therefore, burrs are generally found at the incision, and the burrs need to be manually polished with a grinder It is clean, but it is easy to cause splashing and hurt the operator when grinding burrs manually, so use this equipment when you want to clean burrs, and the rotation of the pulley A8 will drive the drive shaft 7 to rotate, and the rotation of the drive shaft 7 will drive the grinding shaft 5 to rotate , on the grinding shaft 5, the grinding wheel A4 is clamped on the grinding shaft 5 by five bolts and the pressure grinding ring 6, so that the grinding wheel A4 will follow the grinding shaft 5 to rotate, and the grinding wheel A4 is a rough grinding sheet. The rotation of the wheel A4 will grind the aluminum alloy in contact with it. After the grinding wheel A4 has been polished for a long time to smooth the surface, the process of replacing the grinding wheel A4 is that the two axle frames 3 are slidably connected to the skateboard 2, and then the skateboard 2 is provided with two round holes, by inserting the pin shafts into the two round holes to slide the two slide plates 2 relatively stationary in the slide plate 2, and then slide the front-end axle frame 3 out of the slide plate 2, and then the After the five nuts are unscrewed, remove the grinding ring 6 from the grinding shaft 5, then remove the smooth grinding wheel A4 from the five bolts, and then put the new grinding wheel A4 into the five bolts, Then put in the grinding ring 6 and tighten the nuts of the five bolts, so that a new grinding wheel A4 will be clamped on the grinding shaft 5, and then when there is a burr in the aluminum alloy, it will touch the rotating grinding wheel After A4, the grinding wheel A4 can polish the burrs on the aluminum alloy through friction, so as to achieve the effect of grinding the burrs on the outer surface of the aluminum alloy cut.

Referring to Figures 1 to 4, the process of cleaning the burrs on the inner wall of the aluminum alloy can be obtained according to the figures:

The present invention also includes push block 9, grinding wheel B10, push plate 11, turning block 12 and push groove 13, push plate 11 is slidably connected on the slide plate 2, and two springs are fixedly connected between push plate 11 and slide plate 2, push A push groove 13 is provided on the plate 11, a push block 9 is slidably connected in the push groove 13, a spring is fixedly connected between the push block 9 and the push plate 11, and a grinding wheel B10 is connected to the front end of the push block 9 in rotation, and the grinding wheel B10 and the The drive shaft 7 is driven by a belt, and the turning block 12 is connected to the skateboard 2 in rotation. The aluminum alloy often has burrs not only on the outer surface, but also the burrs on the inner wall of the cutout of the aluminum alloy profile are difficult to clean. When you want to clean the burrs on the inner wall of the aluminum alloy cutout, the skateboard 2 is slidingly connected on the bottom frame 1, the aluminum alloy position is fixed, and the left and right sliding of the slide plate 2 will cause the grinding wheel A4 to separate or contact with the outer surface of the aluminum alloy, and the left and right sliding of the slide plate 2 will also drive the push block 9, the grinding wheel B10, Push plate 11, turning block 12 and push groove 13 move left and right, turning block 12 is to be connected on the slide plate 2 in rotation, the front end of turning block 12 is provided with raised round block, and the rear end of turning block 12 is provided with long round block, long The round block is in contact with the push plate 11. When the slide plate 2 slides to the right on the bottom frame 1, it will drive the grinding wheel A4 to move to the right, and then the slide plate 2 that moves to the right will also drive the turning block 12 to move to the right. Move to the right, and then the turning block 12 moving to the right will drive the raised round block on it to move to the right together, and the raised round block will first touch the outer surface of the aluminum alloy profile at the same position in the process of moving to the right. Skateboard 2 can drive grinding wheel A4 and can continue to move to the right, but the protruding round block of turning block 12 is blocked by the circular aluminum alloy profile outer surface, turning block 12 can't continue to move to the right, so turning block 12 will cause Turning counterclockwise, turning block 12 counterclockwise will make the oblong block at the rear end of turning block 12 move forward, and the elongated block moving forward will push forward the push plate 11 that is slidably connected on the slide plate 2, and the push plate 11 will move forward The movement will drive the push block 9 slidingly connected in the push groove 13 to move forward, and the push plate 11 will also push the belt driven by the grinding wheel B10 and the drive shaft 7 to move forward. When the belt moves forward on the drive shaft 7 , the diameter of the drive shaft 7 will gradually increase, and then the circumference of the belt is fixed, and the length of the belt around the drive shaft 7 will increase, and the belt will pull the grinding wheel B10 to move to the left, thus forming a The grinding wheel B10 moves forward for a certain distance, and then the grinding wheel B10 moves forward and left together. When the grinding wheel A4 touches the outer surface of the aluminum alloy profile, the grinding wheel B10 extends into the inner cavity of the circular aluminum alloy profile. And the grinding wheel A4 and the grinding wheel B10 will clamp the side wall of the circular aluminum alloy profile. During this process, the grinding wheel A4 is always rotating, and the rotation of the grinding wheel A4 will drive the grinding wheel B10 to rotate together through the belt. After the rotating grinding wheel A4 and the rotating grinding wheel B10 clamp the side wall of the circular aluminum alloy profile, the circular aluminum alloy profile itself is also rotated, so that the rotating grinding wheel A4 and the rotating grinding wheel B10 can Grinding the burrs on the inner wall and outer surface of the round aluminum alloy profile, All the burrs at the incision position of the alloy profile are cleaned up, and then when the slide plate 2 slides to the left on the bottom frame 1, the grinding wheel A4 is separated from the outer surface of the circular aluminum alloy profile, and the push plate 11 is fixedly connected to the slide plate 2 There are two springs, when the slide plate 2 slides to the left, the turning block 12 will rotate clockwise, and then the long round block will not squeeze the push plate 11, and the push plate 11 will move to the rear end under the action of the two springs , the push plate 11 moving backward will drive the push block 9 to move backward, and the backward movement of the push block 9 will drive the grinding wheel B10 connected to it to move backward together, and the grinding wheel B10 will drive in the process of moving backward The belt between the grinding wheel B10 and the drive shaft 7 moves backward together, the shaft diameter at the rear end of the drive shaft 7 is getting smaller and smaller, and a spring is fixedly connected between the push block 9 and the push plate 11, and the spring will push the push block 9 to push Move to the right in the groove 13, and the push block 9 moving to the right will drive the grinding wheel B10 to move to the right together, so that the grinding wheel B10 will be separated from the inner wall of the circular aluminum alloy profile, and then when the push plate 11 returns to the After the initial position, the grinding wheel B10 withdraws from the inner cavity of the circular aluminum alloy profile, and at the same time, the push plate 11 will turn clockwise against the turning block 12 to the initial position, so that the inner wall of the circular aluminum alloy profile cutout and The outer surface is polished smooth to achieve the effect of cleaning the burrs on the inner wall of the aluminum alloy.

Referring to Figure 1 to Figure 6, the process of cutting aluminum alloy profiles can be obtained according to the diagrams:

The present invention also comprises cutting shaft 14, cutting piece 15 and pulley B16, and cutting piece 15 is rotatably connected on the slide plate 2, and the rear end of cutting piece 15 is fixedly connected with cutting shaft 14, and is fixedly connected with belt pulley B16 on cutting shaft 14, and belt pulley B16 and The pulley A8 is driven by a belt, the rotation of the pulley B16 will drive the pulley A8 to rotate through the belt, the rotation of the pulley A8 will drive the grinding wheel A4 to rotate, and then the rotation of the pulley B16 will drive the cutting shaft 14 to rotate, and the cutting shaft 14 will drive the cutting blade 15 rotates, and the rotating cutting piece 15 can cut the aluminum alloy profile that touches it, the slide plate 2 slides left and right on the chassis 1, the aluminum alloy profile is located between the cutting piece 15 and the grinding wheel A4, and then the aluminum alloy profile Keeping the position still, moving the slide plate 2 to the left will drive the cutting piece 15 to move to the left together, and the cutting piece 15 moving to the left will touch the aluminum alloy profile, and then the slide plate 2 will drive the cutting piece 15 to continue to move to the left, The rotating cutting piece 15 can cut the aluminum alloy profiles encountered, and then move the slide plate 2 to the right after cutting, so that the cutting piece 15 returns to the starting position, so as to obtain the effect of cutting the aluminum alloy profiles.

With reference to Fig. 1 to Fig. 6, can obtain the process that cutting piece 15 rotates automatically according to showing in the figure:

The present invention also comprises gear B17, motor 18 and gear C19, and gear B17 is fixedly connected to the rear end of cutting shaft 14, and motor 18 is fixedly connected on the slide plate 2, and the output shaft of motor 18 is fixedly connected with gear C19, and gear C19 and gear B17 engages the transmission, the motor 18 will drive the fixedly connected gear C19 on the output shaft to rotate, the rotation of the gear C19 will drive the gear B17 to rotate, the rotation of the gear B17 will drive the belt pulley B16 to rotate, and the rotation of the belt pulley B16 will drive the cutting shaft 14 to rotate. The cutting shaft 14 will drive the cutting piece 15 to rotate, and then the belt pulley B16 will drive the belt pulley A8 to rotate through the belt transmission. The rotation of the belt pulley A8 will drive the drive shaft 7 to rotate, and the drive shaft 7 will drive the grinding wheel A4 to rotate, and the drive shaft 7 will rotate. It will drive the grinding wheel B10 to rotate again, so that the grinding wheel A4, the grinding wheel B10 and the cutting disc 15 will rotate simultaneously, so as to obtain the effect of the automatic rotation of the cutting disc 15.

Referring to Figure 1 to Figure 10, the process of clamping the aluminum alloy profile can be obtained according to the figure:

The present invention also includes friction wheel E24, pull plate 25, clamping block 26, clamping ring 27 and clamping groove 28, clamping ring 27 is rotatably connected on the chassis 1, and clamping ring 27 is provided with four clamping grooves 28, four clamping grooves The slot 28 is slidably connected with a clamp block 26, and one end of the four pull plates 25 is rotatably connected with the clamp block 26, and the other ends of the four pull plates 25 are all rotatably connected to the friction wheel E24, and the aluminum alloy profile is passed through the friction wheel E24. round hole in the wheel E24, then rotate the friction wheel E24 clockwise, and the clockwise rotation of the friction wheel E24 will drive one end of the four pull plates 25 to rotate clockwise, and the other ends of the four pull plates 25 are rotated and connected with clips. Block 26, the length of four draw plates 25 is constant, when four draw plates 25 turn clockwise, can drive the other end of four draw plates 25 to move closer to the center, the other end of four draw plates 25 just Can drive four clamping blocks 26 to move closer to the center in four clamping grooves 28, and the four clamping blocks 26 that move closer to the center can clamp the aluminum alloy profiles that pass through the friction wheel E24 round hole, when the four clamping blocks 26 After the aluminum alloy profile is clamped, the friction wheel E24 continues to rotate so that the four clamping blocks 26 clamp the aluminum alloy profile and then drive the clamp ring 27 to rotate clockwise. When you want to loosen the aluminum alloy profile, turn the friction wheel E24 rotates counterclockwise, and the counterclockwise rotation of the friction wheel E24 will drive the four pull plates 25 to rotate counterclockwise, and the four pull plates 25 that rotate counterclockwise will push the four clamping blocks 26 to the outside in the four clamping grooves 28, The four clamping blocks 26 will loosen the aluminum alloy profile, so as to obtain the effect of clamping the aluminum alloy profile.

Referring to Figure 1 to Figure 10, the process of automatic left and right movement of the skateboard 2 can be obtained according to the figures shown in the figure:

The present invention also includes a cam 20, a friction wheel C21, a friction shaft 22 and a friction wheel D23. The cam 20 is fixedly connected to the gear C19, the friction shaft 22 is rotatably connected to the chassis 1, and the rear end of the friction shaft 22 is fixedly connected to the friction wheel C21. , the friction wheel C21 and the cam 20 are frictionally driven, the front end of the friction shaft 22 is fixedly connected with the friction wheel D23, the friction wheel D23 is frictionally driven with the friction wheel E24, the friction wheel C21 is frictionally driven with the cam 20, the cam 20 rotates clockwise, and the cam 20 will Pushing against the outer surface of the friction wheel C21 drives the friction wheel C21 to rotate counterclockwise. When the cam 20 is rotating, there is a section of protrusion on the cam 20. When the convex part of the cam 20 rotates to the contact position with the friction wheel C21 Finally, the convex part of the cam 20 will be on the friction wheel C21, and then the cam 20 will move to the left as a whole, and then the cam 20 will drive the motor 18 to move to the left, and the motor 18 will drive the slide plate 2 to the left on the chassis 1 Later, when the protrusion on the cam 20 rotates past the contact position with the friction wheel C21, the two springs between the skateboard 2 and the bottom frame 1 will return to the initial position, and the two springs will push the skateboard 2 on the bottom. Frame 1 moves to the right. During this process, the cam 20 has been frictionally transmitting the friction wheel C21. The counterclockwise rotation of the friction wheel C21 will drive the friction wheel D23 to rotate counterclockwise through the friction shaft 22, and the counterclockwise rotation of the friction wheel D23 will Drive the friction wheel E24 to rotate clockwise, and the clockwise rotation of the friction wheel E24 will drive the four clamping blocks 26 to clamp the aluminum alloy profile. When the slide plate 2 continues to move to the left, the friction wheel C21 will continue to rotate. After the friction wheel E24 can drive four clamping blocks 26 to clamp the aluminum alloy profile, it will drive the clamping ring 27 to rotate clockwise on the underframe 1. When the cam 20 passes through the raised part, it will continue to rotate. The slide plate 2 that moves on the right side will drive the grinding wheel A4 to touch the outer surface of the aluminum alloy profile, and when the aluminum alloy profile is polished like this, the aluminum alloy profile itself will be clamped and rotated by four clamping blocks 26, so that Get the effect that the skateboard 2 moves left and right automatically.

Referring to Figure 1 to Figure 11, the process of preventing the polished burrs from splashing can be obtained according to the figures:

The present invention also includes an electromagnet 30. The electromagnet 30 is arranged inside the grinding shaft 5. After the electromagnet 30 is powered on, it will generate a magnetic force. The grinding wheel A4 and the grinding wheel B10 can not only grind burrs on aluminum alloy materials, but also can polish general The burrs on the incision of the round metal profile. In order to have a certain hardness, the aluminum alloy will also be mixed with iron powder during the casting process. The aluminum alloy profile with a small amount of iron powder will be attracted by the magnet, although the magnetic effect on the aluminum alloy Not as good as other metals, but when the burrs on the aluminum alloy profile are ground into powder, the electromagnet 30 will also magnetically attract the metal powder on the surface of the grinding wheel A4, which can prevent the powder after grinding the burrs from splashing and polluting the processing environment , in order to obtain the effect of preventing the burrs from being polished from splashing.

Referring to Fig. 1 to Fig. 12, the process of collecting metal powder can be obtained as shown in the figure:

The present invention also includes a brush 31 and a collection box 32, the brush 31 is fixedly connected to one of the shaft frames 3, the collection box 32 is slidably connected to the two shaft frames 3, and the slide plate 2 slides left and right on the bottom frame 1 , when the skateboard 2 slides to the left end, the cutting piece 15 will cut the metal profile it touches, and then when the slide plate 2 slides to the right end, the grinding wheel A4 and the grinding wheel B10 will grind the cut position of the metal profile, and put it on the bottom frame A contact point is set between 1 and skateboard 2, and when the skateboard 2 slides to the right, the contact is connected, and the electromagnet 30 is energized to generate a magnetic force, and the polished metal powder is magnetically attracted to the grinding wheel A4, and then on the skateboard 2. When the left end slides, the contact separation electromagnet 30 breaks the electromagnetic force and weakens, and the hairbrush 31 fixedly connected on one of the axle frames 3, the hairbrush 31 is in contact with the outer surface of the grinding wheel A4, and when the electromagnet 30 breaks the electromagnetic force weakens, Hairbrush 31 can brush off the metal powder adsorbed on the grinding wheel A4, and the metal powder brushed off can drop in the collection box 32, so that the metal powder adsorbed on its outer surface can be cleaned every time the grinding wheel A4 is polished. To make the grinding wheel A4 keep the best grinding effect and grind the burrs, after the collection box 32 is full of metal powder, the operator can extract the collection box 32 from the two shaft brackets 3, and the metal in the collection box 32 The powder is dumped to get the process of collecting the metal powder.

Referring to Figures 1 to 13, according to the figures shown in the figure, the process of cutting out the aluminum alloy profile can be obtained:

The present invention also includes four guide wheels 29, the four guide wheels 29 are all slidingly connected on the bottom frame 1, and springs are fixedly connected between the four guide wheels 29 and the bottom frame 1, and the operator places the aluminum alloy profiles on the bottom frame 1. On the frame 1, the bottom frame 1 will drag the aluminum alloy profile, and then the four guide wheels 29 sliding on the bottom frame 1 will touch the outer surface of the aluminum alloy profile, and the four guide wheels 29 will be under the action of the four springs. The outer surface of the aluminum alloy profile is always in contact with the four guide wheels 29, and the four guide wheels 29 can rotate. When the aluminum alloy profile rotates, the four guide wheels 29 will roll on the outer surface of the aluminum alloy profile. The spring of a guide wheel 29 can prevent the aluminum alloy profile from swinging from side to side during rotation, so that the aluminum alloy profile kerf cut and polished can be more even, so that the effect of cutting out the aluminum alloy profile kerf can be obtained evenly.

Referring to Figures 1 to 14, the process of preventing the turning block 12 from rotating at a large angle clockwise can be obtained according to the figures shown in the figures:

The present invention also includes a brake block 33, the brake block 33 is fixedly connected on the slide plate 2, the angle of rotation of the turning block 12 is limited by the brake block 33 fixedly connected on the slide plate 2, when the cutting piece 15 cuts the aluminum alloy profile , the cut part will fall on the slide plate 2, and the dropped part will fall on the right side of the turning block 12. When the slide plate 2 slides to the right, the turning block 12 will also move to the right, and the turning block 12 Push the cut aluminum alloy profile to move to the right, and then the raised round piece on the turning block 12 will touch the outer surface of the aluminum alloy profile, and then the turning block 12 will rotate counterclockwise, and the turning block 12 that rotates counterclockwise will Drive the oblong block to move forward, and the forward-moving oblong block can push the cut aluminum alloy profile out of the slide plate 2, so that the cut aluminum alloy profile falls from the slide plate 2, and then when the slide plate 2 moves to the left, push The two springs fixedly connected between the plate 11 and the slide plate 2 will push the push plate 11 to move to the rear end, and the push plate 11 moving to the rear end will rotate clockwise against the turning block 12, but the turning block 12 rotates clockwise. Can encounter the blocking of brake block 33 in the middle, make turning block 12 can't clockwise larger angle, obtain the effect that prevents turning block 12 from turning larger angle clockwise with this.

Claims (10)

1. An aluminum alloy production facility which characterized in that: including chassis (1), slide (2), pedestal (3), wheel A (4) polish, polish axle (5), press and grind ring (6), drive shaft (7) and belt pulley A (8), slide (2) sliding connection is on chassis (1), two springs of fixedly connected with between slide (2) and chassis (1), sliding connection has two pedestals (3) on slide (2), two pedestals (3) all rotate to be connected on polishing axle (5), press and grind ring (6) through five bolted connection on polishing axle (5), wheel A (4) polish through pressing grinding ring (6) and five bolt centre grippings on polishing axle (5), it has drive shaft (7) to polish axle (5) rear end fixedly connected with, drive shaft (7) rear end fixedly connected with belt pulley A (8).

2. An aluminium alloy production apparatus according to claim 1, wherein: still include ejector pad (9), wheel B (10) polishes, push pedal (11), turn over piece (12) and push away groove (13), push pedal (11) sliding connection is on slide (2), two springs of fixedly connected with between push pedal (11) and slide (2), push away groove (13) have been seted up on push pedal (11), sliding connection has ejector pad (9) in pushing away groove (13), spring of fixedly connected with between ejector pad (9) and push pedal (11), ejector pad (9) front end rotates and is connected with wheel B (10) of polishing, wheel B (10) of polishing passes through belt transmission with drive shaft (7), turn over piece (12) and rotate to be connected on slide (2).

3. An aluminium alloy production apparatus according to claim 2, wherein: still including cutting axle (14), cutting piece (15) and belt pulley B (16), cutting piece (15) rotate to be connected on slide (2), and cutting piece (15) rear end fixedly connected with cuts axle (14), fixedly connected with belt pulley B (16) on cutting axle (14), and belt pulley B (16) pass through belt drive with belt pulley A (8).

4. An aluminum alloy production apparatus according to claim 3, characterized in that: still include gear B (17), motor (18) and gear C (19), gear B (17) fixed connection is in the rear end of cutting axle (14), and motor (18) fixed connection is on slide (2), fixedly connected with gear C (19) on the output shaft of motor (18), and gear C (19) and gear B (17) meshing transmission.

5. An aluminum alloy production apparatus according to claim 4, characterized in that: still include friction pulley E (24), arm-tie (25), clamp splice (26), clamp ring (27) and double-layered groove (28), clamp ring (27) rotate to be connected on chassis (1), four clamp grooves (28) have been seted up on clamp ring (27), equal sliding connection has clamp splice (26) in four clamp grooves (28), the one end of four arm-tie (25) all rotates and is connected with clamp splice (26), the other end of four arm-tie (25) all rotates and connects on friction pulley E (24).

6. An aluminum alloy production apparatus according to claim 5, characterized in that: still include cam (20), friction pulley C (21), friction axle (22) and friction pulley D (23), cam (20) fixed connection is on gear C (19), friction axle (22) rotate to be connected on chassis (1), friction axle (22) rear end fixedly connected with friction pulley C (21), friction pulley C (21) and cam (20) friction drive, friction axle (22) front end fixedly connected with friction pulley D (23), friction pulley D (23) and friction pulley E (24) friction drive.

7. An aluminum alloy production apparatus according to claim 1, characterized in that: the grinding machine also comprises an electromagnet (30), wherein the electromagnet (30) is arranged in the grinding shaft (5).

8. An aluminium alloy production apparatus according to claim 7, wherein: the novel multifunctional electric heating cooker also comprises a brush (31) and a collecting box (32), wherein the brush (31) is fixedly connected to one of the shaft brackets (3), and the collecting box (32) is connected to the two shaft brackets (3) in a sliding mode.

9. An aluminium alloy production apparatus according to claim 5, wherein: still include four guide pulleys (29), four equal sliding connection of guide pulley (29) are on chassis (1), equal two springs of fixedly connected with between four guide pulleys (29) and chassis (1).

10. An aluminium alloy production apparatus according to claim 2, wherein: the device also comprises a brake block (33), and the brake block (33) is fixedly connected to the sliding plate (2).

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