CN111790896A

CN111790896A - Rotor forming mechanism and forming method thereof

Info

Publication number: CN111790896A
Application number: CN202010511502.6A
Authority: CN
Inventors: 唐海军; 陈永法; 蒋建龙
Original assignee: Jiangyin Haida Motor Punching Sheet Co ltd
Current assignee: Jiangyin Haida Motor Punching Sheet Co ltd
Priority date: 2020-06-08
Filing date: 2020-06-08
Publication date: 2020-10-20

Abstract

The invention relates to a rotor forming mechanism and a forming method thereof, wherein the mechanism comprises a die casting machine, a mechanical arm and an aluminum pool; the die casting machine is provided with a lower half die cavity with an ejection cylinder at the bottom, the rotor is ejected out of the cavity after the rotor is die-cast in the upper half die, and then the rotor is pushed out onto the conveying belt by a displacement cylinder, and the conveying belt carries the rotor to a lower station; the mechanical arm can automatically scoop aluminum liquid from the left half pool of the aluminum pool through the ingenious design of the transmission rod, the driven shaft, the driving shaft and the scoop, and then the aluminum liquid is injected into the cavity of the lower half pool; be provided with the baffle on the aluminium pond, the baffle separates into half pond on the left side and half pond on the right side with the aluminium pond, and the baffle bottom is higher than the bottom surface on the cell body, is provided with the circulation mouth between baffle bottom and cell body ground. According to the rotor forming mechanism and the forming method thereof, the quality of the cast aluminum rotor is improved, the production continuity and the automation degree are optimized, the production efficiency is improved, and meanwhile, the labor investment is reduced.

Description

Rotor forming mechanism and forming method thereof

Technical Field

The invention relates to a rotor forming mechanism and a forming method thereof.

Background

The three-phase asynchronous motor is mainly composed of stator and rotor, the rotor is mainly composed of iron core, rotor winding and rotating shaft, the rotor winding is poured into the rotor iron core slot by liquid aluminium, the conducting bar in the slot, end rings and balancing columns at two ends of the iron core are cast out, and the rotor is a solid whole. When three alternating currents are conducted to a stator of the three-phase asynchronous motor, a rotating magnetic field is generated between the stator and a rotor, the rotor winding is cut by the rotating magnetic field, induction current is formed in a closed loop because the rotor winding is made of aluminum with two closed ends, and the rotor which forms the induction current is driven to rotate by electromagnetic torque, so that the quality of cast aluminum of the rotor directly influences the quality of the formed rotor.

The existing rotor forming mechanism has the following defects:

1. the traditional cast aluminum die-casting machine has low automation degree, the rotor needs to be manually taken out after the die-casting process of the rotor is completed, and then the die-casting of the next rotor can be carried out, so that the cast aluminum die-casting efficiency of the rotor is reduced, and meanwhile, the high temperature generated in the die-casting process can burn operators for taking the rotor, thereby causing production accidents;

2. the traditional process of pouring the aluminum liquid into the cavity is completed by manually scooping the aluminum liquid from the aluminum pool by operators and pouring the aluminum liquid into the cast aluminum cavity, gas emitted by the liquid aluminum is harmful to human bodies, chronic poisoning can be caused, and the labor cost and the risk of potential human accidents are increased by manually scooping the aluminum;

3. contain a small amount of impurity in the aluminium pig, the aluminium pig melts the back in traditional aluminium pond, impurity can float on metal aluminium liquid surface, when directly ladling out aluminium liquid through ladling out the spoon, can ladle out impurity simultaneously, the electric conductive property of turning from the winding after the influence cast aluminium, and then influence three asynchronous machine's performance, and simultaneously, traditional aluminium pond is at the in-process that the aluminium pig melts, can not ladle out metal aluminium liquid with ladling out the spoon, only after the aluminium pig melts completely, just can carry out the process that aluminium liquid ladled out and follow-up cast aluminium, seriously influence rotor manufacturing process's continuity and production efficiency.

Therefore, there is a need for a rotor forming mechanism and a forming method thereof that can improve the rotor forming efficiency, reduce the labor cost, and improve the rotor quality.

Disclosure of Invention

The invention aims to overcome the defects and provide a rotor forming mechanism and a forming method thereof, which can improve the rotor forming efficiency, reduce the labor cost and improve the rotor quality.

The purpose of the invention is realized as follows:

a method of forming a rotor, the method comprising the steps of:

step 1: manually placing the aluminum block into the right half pool of the aluminum pool;

step 2: the mechanical arm controls a scooping spoon to scoop aluminum liquid in the left half pool of the aluminum pool, and then the aluminum liquid is poured into the lower half-die cavity;

and step 3: manually placing the rotor lamination right above the lower half-mold cavity;

and 4, step 4: the hydraulic cylinder pushes the hydraulic rod to move downwards, the hydraulic rod drives the middle beam to move downwards along the upright post, the upper half die presses the rotor lamination downwards until the rotor lamination is completely pressed into the lower half die cavity, and after the rotor lamination is kept for a period of time, the hydraulic cylinder pulls the hydraulic rod upwards;

and 5: ejecting a thimble on a piston rod of the ejection cylinder out of the lower half die cavity through a hole at the bottom of the lower half die cavity;

step 6: after the cast-aluminum rotor completely ejects out of the lower half mold cavity, the piston rod of the displacement cylinder pushes the push block at the front end to push the cast-aluminum rotor to the conveying belt, and the conveying belt conveys the cast-aluminum rotor to the next station.

A rotor forming mechanism comprises a die casting machine, a mechanical arm, an aluminum pool, a displacement cylinder, a push block and a conveying belt; the die casting machine, the mechanical arm and the aluminum pool are sequentially arranged from left to right; the die casting machine comprises an operating table, an upper cross beam, an upright post, a lower half die cavity and an upper half die; a conveying belt, a lower half mold cavity and a displacement cylinder are sequentially arranged on the operating platform from left to right; the displacement cylinder is connected with the push block through a piston rod; an ejection cylinder is arranged below the lower half mold cavity, a piston rod of the ejection cylinder is provided with a thimble which is inserted into a hole at the bottom of the lower half mold cavity, and the thimble is attached to the hole; an anti-compression ring is arranged on the operation table at the outer edge of the upper end face of the lower half mold cavity, so that the anti-compression structural strength of the lower half mold cavity is enhanced; an upper cross beam is arranged right above the lower half die cavity and fixed on the operating platform through four stand columns, a hydraulic cylinder is arranged in the middle of the upper cross beam and connected with a hydraulic rod below, a middle beam is arranged on the hydraulic rod, a hole is formed in the middle beam to enable the stand columns to penetrate through, and the bottom surface of the hydraulic rod is connected with the upper half die.

The invention discloses a rotor forming mechanism, wherein a mechanical arm comprises a transmission box body, a first transmission rod, a second transmission rod, a third transmission rod, a fourth transmission rod, a fifth transmission rod, an arc-shaped track and a scoop; the first transmission rod and the second transmission rod are hinged through a second driven shaft, the second transmission rod and the third transmission rod are hinged through a third driven shaft, the third transmission rod and the fourth transmission rod are hinged through a fourth driven shaft, the fourth transmission rod and the first transmission rod are hinged through a third driving shaft, the fourth transmission rod and the fifth transmission rod are hinged through a first driven shaft, and the fifth transmission rod is fixed on the transmission box body through a second driving shaft; the fourth transmission shaft is connected to the arc-shaped track through the first driven shaft, and the first driven shaft moves on the arc-shaped track; the third driving shaft is fixed on the transmission box body; the third transmission rod is hinged with the scoop through the first driving shaft; the first driving shaft, the second driving shaft and the third driving shaft are respectively driven by a motor.

The invention relates to a rotor forming mechanism, wherein an aluminum pool comprises a tank body, a partition plate, a left half pool, a right half pool and a reinforcing ring; the reinforcing ring is fastened at the outer edge of the groove body for one circle; the middle part of the upper edge of the tank body is provided with front and back symmetrical grooves; the left side and the right side of the upper end of the partition plate are provided with bulges which are inserted into the grooves, the partition plate is fixed on the tank body, and the two sides of the lower end of the partition plate are abutted against the inner wall of the tank body; the bottom of the partition plate is higher than the upper bottom surface of the tank body, and a circulation port is arranged between the bottom of the partition plate and the upper ground of the tank body; the baffle has divided into left half pond and right half pond to cell body inside.

The invention relates to a rotor forming mechanism, wherein a supporting layer is arranged on a groove body; the supporting layer is provided with a heat-insulating layer; a heating layer is arranged on the heat-insulating layer; an aluminum pool lining is arranged on the heating layer.

Compared with the prior art, the invention has the beneficial effects that:

1. the rotor forming mechanism is provided with a die casting machine, a lower half-die cavity with an ejection cylinder at the bottom is arranged on the die casting machine, a rotor can be ejected out of the cavity after the rotor is well cast with aluminum, then a displacement cylinder pushes the rotor out of a conveying belt, and the conveying belt carries out the next station below a rotor conveying belt; the automatic rotor aluminum casting and shifting-out device reduces the labor investment, improves the production efficiency, effectively avoids the potential damage of high operation temperature to operators and reduces the probability of manual production accidents;

2. according to the rotor forming mechanism, the mechanical arm is ingenious in design of the transmission rod, the driven shaft, the driving shaft and the scooping spoon, so that molten aluminum can be automatically scooped from the left half pool of the aluminum pool and then injected into the lower half-die cavity, the investment of labor cost is reduced, and the harm of gas emitted by the molten aluminum to operators is reduced;

3. the rotor forming mechanism is provided with an aluminum tank, a partition plate is arranged on the aluminum tank, the bottom of the partition plate is higher than the upper bottom surface of a tank body, a circulation port is arranged between the bottom of the partition plate and the upper ground of the tank body, an aluminum block is melted in a right half tank, impurities float on aluminum liquid in the right half tank, and the aluminum liquid with high cleanliness flows to the left half tank through the circulation port at the bottom; the high-cleanness aluminum liquid in the left half pool can be used for the next aluminum casting production, so that the cleanness degree of the aluminum liquid is improved, and the quality of the aluminum casting rotor is further improved; the rotor forming mechanism and the forming method thereof are provided with the left half pool and the right half pool, the middle of the left half pool and the right half pool are separated by the partition plate, the scooping spoon can directly scoop aluminum liquid in the left half pool while melting aluminum blocks in the right half pool, and the aluminum liquid is supplied to the next step of cast aluminum production, so that the continuity of a rotor manufacturing process is optimized, and the production efficiency is improved.

Drawings

Fig. 1 is a schematic structural diagram of a rotor forming mechanism and a forming method thereof according to the present invention.

Fig. 2 is a schematic structural view of the die-casting machine of fig. 1.

Fig. 3 is a schematic structural diagram of the robot arm in fig. 1.

FIG. 4 is a schematic structural diagram of the aluminum cell in FIG. 1.

Fig. 5 is a cross-sectional view of the aluminum cell of fig. 1.

Fig. 6 is a schematic structural view of the trough body in fig. 4.

Fig. 7 is a schematic structural view of the separator of fig. 4.

Wherein: the device comprises a die casting machine 1, an operation table 1.1, an upper crossbeam 1.2, a hydraulic rod 1.3, a middle beam 1.4, an upright post 1.5, an anti-compression ring 1.6, a lower half-die cavity 1.7, an ejection cylinder 1.8, an upper half die 1.9, a mechanical arm 2, a transmission box body 2.1, a first transmission rod 2.2, a second transmission rod 2.3, a third transmission rod 2.4, a fourth transmission rod 2.5, a fifth transmission rod 2.6, an arc-shaped rail 2.7, a scoop 2.8, a first driven shaft 2.9, a second driven shaft 2.10, a third driven shaft 2.11, a fourth driven shaft 2.12, a first driving shaft 2.13, a second driving shaft 2.14, a third driving shaft 2.15, an aluminum tank 3, a tank body 3.1, a partition plate 3.2, a left half tank 3.3, a right half tank 3.4, a ring 3.5, a circulation opening 3.6, an aluminum tank lining 3.7, a heat-insulation layer 3.9, a heat-insulation layer 3.2, a cylinder 3.6, a support layer and a support layer displacement block.

Detailed Description

Referring to fig. 1 to 7, the present invention relates to a rotor forming mechanism and a forming method thereof, the method includes:

step 1: manually putting the aluminum block into the right half pool 3.3 of the aluminum pool 3;

step 2: the mechanical arm 2 controls the scooping spoon 2.8 to scoop aluminum liquid in the left half pool 3.4 of the aluminum pool 3, and then the aluminum liquid is poured into the lower half-die cavity 1.7;

and step 3: manually placing the rotor lamination right above the lower half-mold cavity 1.7;

and 4, step 4: the hydraulic cylinder pushes the hydraulic rod 1.3 to move downwards, the hydraulic rod 1.3 drives the middle beam 1.4 to move downwards along the upright post 1.5, the upper half die 1.9 presses the rotor lamination downwards until the rotor lamination is completely pressed into the lower half die cavity 1.7, and after the rotor lamination is kept for a period of time, the hydraulic cylinder pulls the hydraulic rod 1.3 upwards;

and 5: a thimble on a piston rod of the ejection cylinder 1.8 ejects the cast-aluminum rotor out of the lower half mold cavity 1.7 through a hole at the bottom of the lower half mold cavity 1.7;

step 6: after the cast-aluminum rotor completely ejects out of the lower half mold cavity 1.7, the piston rod of the displacement cylinder 4 pushes the push block 5 at the front end to push the cast-aluminum rotor to the conveyer belt 6, and the conveyer belt 6 transmits the cast-aluminum rotor to the next station.

The rotor forming method is based on a rotor forming mechanism and comprises a die casting machine 1, a mechanical arm 2, an aluminum pool 3, a displacement cylinder 4, a push block 5 and a conveying belt 6; the die casting machine 1, the mechanical arm 2 and the aluminum pool 3 are sequentially arranged from left to right; the die casting machine 1 comprises an operating table 1.1, an upper cross beam 1.2, an upright post 1.5, a lower half die cavity 1.7 and an upper half die 1.9; a conveying belt 6, a lower half mold cavity 1.7 and a displacement cylinder 4 are sequentially arranged on the operating table 1.1 from left to right; the displacement cylinder 4 is connected with a push block 5 through a piston rod; an ejection cylinder 1.8 is arranged below the lower half-mold cavity 1.7, a piston rod of the ejection cylinder 1.8 is provided with a thimble which is inserted into a hole at the bottom of the lower half-mold cavity 1.7, and the thimble is attached to the hole; an anti-pressing ring 1.6 is arranged on the operating table 1.1 at the outer edge of the upper end face of the lower half-mold cavity 1.7, so that the anti-pressing structural strength of the lower half-mold cavity 1.7 is enhanced; an upper beam 1.2 is arranged right above the lower half-die cavity 1.7, the upper beam 1.2 is fixed on an operation table 1.1 through four upright posts 1.5, a hydraulic cylinder is arranged in the middle of the upper beam 1.2 and connected with a hydraulic rod 1.3 below, an intermediate beam 1.4 is arranged on the hydraulic rod 1.3, a hole is formed in the intermediate beam 1.4 to enable the upright posts 1.5 to penetrate through, and the bottom surface of the hydraulic rod 1.3 is connected with an upper half-die 1.9.

The mechanical arm 2 comprises a transmission box body 2.1, a first transmission rod 2.2, a second transmission rod 2.3, a third transmission rod 2.4, a fourth transmission rod 2.5, a fifth transmission rod 2.6, an arc-shaped track 2.7 and a scoop 2.8; the first transmission rod 2.2 is hinged with the second transmission rod 2.3 through a second driven shaft 2.10, the second transmission rod 2.3 is hinged with the third transmission rod 2.4 through a third driven shaft 2.11, the third transmission rod 2.4 is hinged with the fourth transmission rod 2.5 through a fourth driven shaft 2.12, the fourth transmission rod 2.5 is hinged with the first transmission shaft 2.2 through a third driving shaft 2.15, the fourth transmission rod 2.5 is hinged with the fifth transmission rod 2.6 through a first driven shaft 2.9, and the fifth transmission rod 2.6 is fixed on the transmission box body 2.1 through a second driving shaft 2.14; the fourth driving rod 2.5 is connected to the arc-shaped track 2.7 through the first driven shaft 2.9, and the first driven shaft 2.9 moves on the arc-shaped track 2.7; the third driving shaft 2.15 is fixed on the transmission case body 2.1; the third transmission rod 2.4 is hinged with the scoop 2.8 through a first driving shaft 2.13; the first driving shaft 2.13, the second driving shaft 2.14 and the third driving shaft 2.15 are respectively driven by a motor.

The aluminum pool 3 comprises a tank body 3.1, a partition plate 3.2, a left half pool 3.3, a right half pool 3.4 and a reinforcing ring 3.5; the reinforcing ring 3.5 is fastened at the outer edge of the tank body 3.1 by a circle to protect the strength and stability of the tank body 3.1 structure; the middle position of the upper edge of the tank body 3.1 is provided with a front and back symmetrical groove 3.11; the left side and the right side of the upper end of the partition plate 3.2 are provided with protrusions 3.12, the protrusions 3.12 are inserted into the grooves 3.11, the partition plate 3.2 is fixed on the tank body 3.1, and two sides of the lower end of the partition plate 3.2 are abutted against the inner wall of the tank body 3.1; the bottom of the partition plate 3.2 is higher than the upper bottom surface of the tank body 3.1, and a circulation port 3.6 for the flow of aluminum liquid is arranged between the bottom of the partition plate 3.2 and the upper ground of the tank body 3.1; the partition plate 3.2 divides the interior of the tank body 3.1 into a left half tank 3.3 and a right half tank 3.4, aluminum liquid in the right half tank 3.4 flows to the left half tank 3.3 through the flow opening 3.6 under the action of atmospheric pressure, the right half tank 3.4 is used for melting aluminum blocks, and the left half tank 3.3 is used for providing aluminum industry for the next production process.

The tank body 3.1 is provided with a supporting layer 3.10, and the supporting layer 3.10 is used for supporting the whole tank body 3.1 structure; the supporting layer 3.10 is provided with a heat-insulating layer 3.9, and the heat-insulating layer 3.9 can slow down the loss speed of the temperature of the aluminum pool to the periphery through the tank body 3.1; a heating layer 3.8 is arranged on the heat-insulating layer 3.9, and the heating layer 3.8 is used for providing heat for the aluminum pool; an aluminum pool lining 3.7 is arranged on the heating layer 3.8, and the aluminum pool lining 3.7 is directly contacted with aluminum liquid.

In addition: it should be noted that the above-mentioned embodiment is only a preferred embodiment of the present patent, and any modification or improvement made by those skilled in the art based on the above-mentioned conception is within the protection scope of the present patent.

Claims

1. A method of forming a rotor, comprising: the method comprises the following steps:

step 1: manually putting the aluminum block into the right half pool (3.3) of the aluminum pool (3);

step 2: the mechanical arm (2) controls the scooping spoon (2.8) to scoop aluminum liquid in the left half pool (3.4) of the aluminum pool (3), and then the aluminum liquid is poured into the lower half-mold cavity (1.7);

and step 3: manually placing the rotor lamination right above the lower half-mold cavity (1.7);

and 4, step 4: the hydraulic cylinder pushes the hydraulic rod (1.3) to move downwards, the hydraulic rod (1.3) drives the middle beam (1.4) to move downwards along the upright post (1.5), the upper half mold (1.9) presses the rotor lamination downwards until the rotor lamination is completely pressed into the lower half mold cavity (1.7), and after the rotor lamination is kept for a period of time, the hydraulic cylinder pulls the hydraulic rod (1.3) upwards;

and 5: a thimble on a piston rod of the ejection cylinder (1.8) ejects the rotor after aluminum casting out of the lower half mold cavity (1.7) through a hole at the bottom of the lower half mold cavity (1.7);

step 6: after the rotor after aluminum casting completely ejects out of the lower half mold cavity (1.7), a piston rod of the displacement cylinder (4) pushes a push block (5) at the front end, the rotor after aluminum casting is pushed to a conveying belt (6), and the conveying belt (6) conveys the rotor after aluminum casting to the next station.

2. A rotor forming mechanism is characterized in that: comprises a die casting machine (1), a mechanical arm (2), an aluminum pool (3), a displacement cylinder (4), a push block (5) and a conveyer belt (6); the die casting machine (1), the mechanical arm (2) and the aluminum pool (3) are sequentially arranged from left to right; the die casting machine (1) comprises an operating table (1.1), an upper cross beam (1.2), an upright post (1.5), a lower half die cavity (1.7) and an upper half die (1.9); a conveying belt (6), a lower half mold cavity (1.7) and a displacement cylinder (4) are sequentially arranged on the operating table (1.1) from left to right; the displacement cylinder (4) is connected with the push block (5) through a piston rod; an ejection cylinder (1.8) is arranged below the lower half-mold cavity (1.7), a piston rod of the ejection cylinder (1.8) is provided with an ejector pin which is inserted into a hole at the bottom of the lower half-mold cavity (1.7), and the ejector pin is attached to the hole; an anti-pressing ring (1.6) is arranged on the operating table (1.1) at the outer edge of the upper end face of the lower half-mold cavity (1.7), so that the anti-pressing structural strength of the lower half-mold cavity (1.7) is enhanced; an upper cross beam (1.2) is arranged right above the lower half mold cavity (1.7), the upper cross beam (1.2) is fixed on an operation table (1.1) through four upright posts (1.5), a hydraulic cylinder is arranged in the middle of the upper cross beam (1.2), the hydraulic cylinder is connected with a hydraulic rod (1.3) below, a middle beam (1.4) is arranged on the hydraulic rod (1.3), a hole is formed in the middle beam (1.4) to enable the upright posts (1.5) to penetrate through, and the bottom surface of the hydraulic rod (1.3) is connected with an upper half mold (1.9).

3. A rotor forming mechanism according to claim 2, wherein: the mechanical arm (2) comprises a transmission box body (2.1), a first transmission rod (2.2), a second transmission rod (2.3), a third transmission rod (2.4), a fourth transmission rod (2.5), a fifth transmission rod (2.6), an arc-shaped track (2.7) and a scooping spoon (2.8); the first transmission rod (2.2) is hinged with the second transmission rod (2.3) through a second driven shaft (2.10), the second transmission rod (2.3) is hinged with the third transmission rod (2.4) through a third driven shaft (2.11), the third transmission rod (2.4) is hinged with the fourth transmission rod (2.5) through a fourth driven shaft (2.12), the fourth transmission rod (2.5) is hinged with the first transmission shaft (2.2) through a third driving shaft (2.15), the fourth transmission rod (2.5) is hinged with the fifth transmission rod (2.6) through a first driven shaft (2.9), and the fifth transmission rod (2.6) is fixed on the transmission box body (2.1) through a second driving shaft (2.14); the fourth driving rod (2.5) is connected to the arc-shaped track (2.7) through the first driven shaft (2.9), and the first driven shaft (2.9) moves on the arc-shaped track (2.7); the third driving shaft (2.15) is fixed on the transmission case body (2.1); the third transmission rod (2.4) is hinged with the scoop (2.8) through a first driving shaft (2.13); the first driving shaft (2.13), the second driving shaft (2.14) and the third driving shaft (2.15) are respectively driven by a motor.

4. A rotor forming mechanism according to claim 2, wherein: the aluminum pool (3) comprises a tank body (3.1), a partition plate (3.2), a left half pool (3.3), a right half pool (3.4) and a reinforcing ring (3.5); the reinforcing ring (3.5) is fastened on the outer edge of the groove body (3.1) for one circle; the middle position of the upper edge of the tank body (3.1) is provided with a front and back symmetrical groove (3.11); the left side and the right side of the upper end of the partition plate (3.2) are provided with protrusions (3.12), the protrusions (3.12) are inserted into the grooves (3.11), the partition plate (3.2) is fixed on the tank body (3.1), and two sides of the lower end of the partition plate (3.2) are abutted against the inner wall of the tank body (3.1); the bottom of the partition plate (3.2) is higher than the upper bottom surface of the tank body (3.1), and a circulation port (3.6) is arranged between the bottom of the partition plate (3.2) and the upper ground of the tank body (3.1); the inside of the tank body (3.1) is divided into a left half tank (3.3) and a right half tank (3.4) by the partition plate (3.2).

5. A rotor forming mechanism according to claim 4, wherein: the tank body (3.1) is provided with a supporting layer (3.10); an insulating layer (3.9) is arranged on the supporting layer (3.10); a heating layer (3.8) is arranged on the heat-insulating layer (3.9); an aluminum pool lining (3.7) is arranged on the heating layer (3.8).