CN110980180B - Magnetic shoe sintering electric kiln rotary line extension device and implementation method thereof - Google Patents

Abstract

The invention discloses a rotary line extension device of a magnetic tile sintering electric kiln, which comprises an electric kiln, wherein a feeding end of the electric kiln is provided with a feeding rotary line, a discharging end of the electric kiln is provided with a discharging rotary line, the discharging rotary line is connected with the feeding rotary line through a storage conveying line, one end of the discharging rotary line, which is close to the storage conveying line, is provided with a first discharging station, one end of the feeding rotary line, which is close to the storage conveying line, is provided with a second feeding station, and one side of the storage conveying line, which is far away from the electric kiln, is respectively provided with the second discharging station and the first feeding station; according to the invention, the storage conveying line is arranged, so that the rotary line can be extended, and the robot can be used for loading and unloading, thereby eliminating the loading workers who work on the magnetic shoe blanks in the night shift and the unloading workers who burn the finished magnetic shoe products.

Description

Magnetic shoe sintering electric kiln rotary line extension device and implementation method thereof

Technical Field

The invention belongs to the technical field of magnetic shoe production, and particularly relates to a device for extending a rotary line of an electric kiln for sintering magnetic shoes and an implementation method thereof.

Background

The invention aims to increase the length of a rotary line of an electric kiln, thereby solving the problems of continuous turnover of the rotary line and 24-hour work of 3 workers. And the 6-axis robot and the S-shaped repository are combined to realize that the post only needs the staff to go to the white class and does not need to go to the zero class and the night class. And because the residual heat of the kiln is diffused, the temperature around the kiln is very high, and the post belongs to a high-temperature post. The staffs in the loading and unloading post are very difficult to recruit. In order to solve the practical problems, the rotary line of the electric kiln is specially designed to be lengthened and modified.

Disclosure of Invention

The invention aims to provide a device for extending a rotary line of an electric kiln for sintering magnetic shoes, which aims to solve the problems in the background technology. The device for extending the rotary line of the magnetic shoe sintering electric kiln has the characteristics of reducing the manual use amount and reducing the labor intensity of workers.

The invention also aims to provide a method for realizing the device for extending the rotary line of the magnetic shoe sintering electric kiln.

In order to achieve the purpose, the invention provides the following technical scheme: a rotary line extension device of an electric kiln for magnetic shoe sintering comprises the electric kiln, a feeding rotary line is arranged at a feeding end of the electric kiln, a discharging rotary line is arranged at a discharging end of the electric kiln, the discharging rotary line is connected with the feeding rotary line through a storage conveying line, a first discharging station is arranged at one end of the discharging rotary line close to the storage conveying line, a second feeding station is arranged at one end of the feeding rotary line close to the storage conveying line, a second discharging station and a first feeding station are respectively arranged at one side of the storage conveying line far away from the electric kiln, a first robot and a second robot are respectively arranged at one side of the storage conveying line close to the electric kiln, and the first robot and the second blanking station are positioned at one end close to the blanking rotary line, the first loading station and the second robot are positioned at one end close to the loading rotary line, and the electric kiln, the blanking rotary line, the first robot, the second robot, the storage conveying line and the loading rotary line are respectively in signal connection with the controller.

Further, the storage conveying lines comprise a first layer conveying line, a second layer conveying line, a third layer conveying line, a fourth layer conveying line, a fifth layer conveying line and a return conveying line, wherein the first layer conveying line, the second layer conveying line, the third layer conveying line, the fourth layer conveying line, the fifth layer conveying line and the return conveying line are sequentially arranged from bottom to top.

Further, the moving direction of the first layer conveying line is from left to right, the moving direction of the second layer conveying line is from right to left, the moving direction of the third layer conveying line is from left to right, the moving direction of the fourth layer conveying line is from right to left, the moving direction of the fifth layer conveying line is from left to right, and the moving direction of the return conveying line is from right to left.

In the invention, the ends of the first layer of conveying line, the second layer of conveying line, the third layer of conveying line, the fourth layer of conveying line, the fifth layer of conveying line, the return conveying line and the blanking rotary line are connected with baffle plates.

In the invention, the end parts of the first layer conveying line, the second layer conveying line, the third layer conveying line, the fourth layer conveying line, the fifth layer conveying line, the return conveying line, the blanking revolving line and the feeding revolving line are respectively connected with two in-place inductors, the distance between the two in-place inductors is equal to the length of the burning bearing plate, and the in-place inductors are in signal connection with the controller.

Further, the first blanking station, the second blanking station, the first loading station and the second loading station are manual stations.

Further, the method for realizing the extension device of the rotary line of the magnetic shoe sintering electric kiln comprises the following steps:

when workers leave work, the conveying lines are returned to be out of work, the first robot conveys the burning bearing plate provided with the sintered magnetic tiles on the blanking rotary line to the left end of the first-layer conveying line, and meanwhile, the second robot conveys the burning bearing plate provided with the blank magnetic tiles at the right end of the fifth-layer conveying line to the blanking rotary line;

when the burning bearing plate with the sintered magnetic tiles moves from the left end to the right end of the first layer conveying line, the second robot carries the burning bearing plate with the sintered magnetic tiles to the right end of the second layer conveying line, when the burning bearing plate with the sintered magnetic tiles moves from the right end to the left end of the second layer conveying line, the first robot carries the burning bearing plate with the sintered magnetic tiles to the left end of the third layer conveying line, and until the burning bearing plate with the sintered magnetic tiles moves to the position, corresponding to the second blanking station, on the fifth layer conveying line, a worker starts working;

thirdly, a worker A places the burning bearing plate filled with the blank magnetic shoe on a feeding rotary line at a second feeding station, and a worker B takes down the sintered magnetic shoe and the burning bearing plate from the feeding rotary line at a first discharging station and places the sintered magnetic shoe and the burning bearing plate on a turnover support;

fourthly, taking out the magnetic tiles sintered in the off-duty time on the fifth layer conveying line from the burning bearing plate at the second blanking station by a worker C, and then putting the blank magnetic tiles into an empty burning bearing plate by a worker D;

(V) when the return conveying line starts to work, the burning bearing plate with the blank magnetic tiles moves to the right end of the fifth layer conveying line, the second robot carries the burning bearing plate with the blank magnetic tiles to the right end of the return conveying line, when the burning bearing plate with the blank magnetic tiles moves from the right end to the left end of the return conveying line, the first robot carries the burning bearing plate with the blank magnetic tiles from the left end of the return conveying line to the left end of the first layer conveying line, when the burning bearing plate with the blank magnetic tiles moves from the left end to the right end of the first layer conveying line, the second robot carries the burning bearing plate with the blank magnetic tiles to the right end of the second layer conveying line, when the burning bearing plate with the blank magnetic tiles moves from the right end to the left end of the second layer conveying line, the first robot carries the burning bearing plate with the blank magnetic tiles to the left end of the third layer conveying line until the burning bearing plate with the blank magnetic tiles moves to the position, corresponding to the second blanking station, on the fifth layer conveying line, the worker starts to leave work, and the cycle is performed.

In the method for realizing the magnetic shoe sintering electric kiln rotary line extension device, the storage conveying line comprises a first layer conveying line, a second layer conveying line, a third layer conveying line, a fourth layer conveying line, a fifth layer conveying line and a return conveying line, wherein the first layer conveying line, the second layer conveying line, the third layer conveying line, the fourth layer conveying line, the fifth layer conveying line and the return conveying line are sequentially arranged from bottom to top, the moving direction of the first layer conveying line is from left to right, the moving direction of the second layer conveying line is from right to left, the moving direction of the third layer conveying line is from left to right, the moving direction of the fourth layer conveying line is from right to left, the moving direction of the fifth layer conveying line is from left to right, the moving direction of the return conveying line is from right to left, the first layer conveying line, the second layer conveying line, the third layer conveying line and the fourth layer conveying line are sequentially arranged from bottom, The fifth layer transfer chain, the tip that returns transfer chain and unloading gyration line all is connected with the baffle, the first layer transfer chain, the second floor transfer chain, the third layer transfer chain, the fourth layer transfer chain, the fifth layer transfer chain, return the transfer chain, the tip of unloading gyration line and material loading gyration line all is connected with two inductors that target in place, two distance that target in place between the inductor equals the length of holding the fever board, inductor and controller signal connection target in place, first unloading station, the second unloading station, first material loading station and second material loading station are the worker's station.

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

1. according to the invention, the storage conveying line is arranged, so that the rotary line can be extended, and the robot can be used for loading and unloading, thereby eliminating the loading workers for the magnetic shoe blanks in the night shift and the unloading workers for burning the finished magnetic shoe products;

2. the working environment temperature of the electric kiln is high, when workers work, refrigerating facilities such as air conditioners and fans on posts need to work, workers only need to work for eight hours, and the refrigerating facilities do not need to work during the rest time of the workers, so that the use of electric power resources can be reduced;

3. the invention is beneficial to relieving the problem of difficult post recruitment, can reduce the use amount of manpower and the labor intensity of workers, and has low equipment cost and high stability.

Drawings

FIG. 1 is a schematic top view of the present invention;

FIG. 2 is a schematic front view of the present invention;

FIG. 3 is a schematic view of the storage conveyor line of the present invention;

FIG. 4 is a schematic view of the structure of FIG. 2 at A according to the present invention;

in the figure: 1. electric kiln; 2. blanking a rotary line; 3. a first blanking station; 4. a first robot; 5. a second blanking station; 6. a first feeding station; 7. a second robot; 8. storing the conveying line; 81. a first layer of conveying line; 82. a second layer of conveyor lines; 83. a third layer of conveying line; 84. a fourth layer of conveying lines; 85. a fifth layer conveying line; 86. returning to the conveying line; 9. a second feeding station; 10. a baffle plate; 11. an in-place sensor; 12. and (4) feeding a rotary line.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Examples

Referring to fig. 1-4, the present invention provides the following technical solutions: a magnetic shoe sintering electric kiln rotary line extension device comprises an electric kiln 1, a feeding end of the electric kiln 1 is provided with a feeding rotary line 12, a discharging end of the electric kiln 1 is provided with a discharging rotary line 2, the discharging rotary line 2 is connected with the feeding rotary line 12 through a storage conveying line 8, one end, close to the storage conveying line 8, of the discharging rotary line 2 is provided with a first discharging station 3, one end, close to the storage conveying line 8, of the feeding rotary line 12 is provided with a second feeding station 9, one side, far away from the electric kiln 1, of the storage conveying line 8 is respectively provided with a second discharging station 5 and a first feeding station 6, one side, close to the electric kiln 1, of the storage conveying line 8 is respectively provided with a first robot 4 and a second robot 7, the first robot 4 and the second discharging station 5 are located at one end, close to the discharging rotary line 2, the first feeding station 6 and the second robot 7 are located at one end, close to the feeding rotary line 12, the electric kiln 1, the blanking rotary line 2, the first robot 4, the second robot 7, the storage conveying line 8 and the feeding rotary line 12 are respectively in signal connection with a controller.

Further, the storage conveyor line 8 includes a first layer conveyor line 81, a second layer conveyor line 82, a third layer conveyor line 83, a fourth layer conveyor line 84, a fifth layer conveyor line 85 and a return conveyor line 86, wherein the first layer conveyor line 81, the second layer conveyor line 82, the third layer conveyor line 83, the fourth layer conveyor line 84, the fifth layer conveyor line 85 and the return conveyor line 86 are sequentially arranged from bottom to top.

Further, the moving direction of the first layer conveyor line 81 is from left to right, the moving direction of the second layer conveyor line 82 is from right to left, the moving direction of the third layer conveyor line 83 is from left to right, the moving direction of the fourth layer conveyor line 84 is from right to left, the moving direction of the fifth layer conveyor line 85 is from left to right, and the moving direction of the return conveyor line 86 is from right to left.

Further, the ends of the first layer conveying line 81, the second layer conveying line 82, the third layer conveying line 83, the fourth layer conveying line 84, the fifth layer conveying line 85, the return conveying line 86 and the blanking rotary line 2 are connected with the baffle 10.

Through adopting above-mentioned technical scheme, set up through baffle 10 and carry on spacingly to holding fever board.

Furthermore, the end parts of the first layer conveyor line 81, the second layer conveyor line 82, the third layer conveyor line 83, the fourth layer conveyor line 84, the fifth layer conveyor line 85, the return conveyor line 86, the blanking rotary line 2 and the feeding rotary line 12 are all connected with two in-place inductors 11, the distance between the two in-place inductors 11 is equal to the length of the burning bearing plate, and the in-place inductors 11 are in signal connection with the controller.

By adopting the technical scheme, whether the burning bearing plate is in place or not is detected by the in-place inductor 11.

Further, the first blanking station 3, the second blanking station 5, the first loading station 6 and the second loading station 9 are manual stations.

Further, the method for realizing the extension device of the rotary line of the magnetic shoe sintering electric kiln comprises the following steps:

when workers leave work, the return conveying line 86 does not work, the first robot 4 conveys the burning bearing plate provided with the sintered magnetic tiles on the blanking revolving line 2 to the left end of the first-layer conveying line 81, and meanwhile, the second robot 7 conveys the burning bearing plate provided with the blank magnetic tiles at the right end of the fifth-layer conveying line 85 to the blanking revolving line 12;

when the burning bearing plate with the sintered magnetic tiles moves from the left end to the right end of the first layer conveying line 81, the second robot 7 carries the burning bearing plate with the sintered magnetic tiles to the right end of the second layer conveying line 82, when the burning bearing plate with the sintered magnetic tiles moves from the right end to the left end of the second layer conveying line 82, the first robot 4 carries the burning bearing plate with the sintered magnetic tiles to the left end of the third layer conveying line 83, and until the burning bearing plate with the sintered magnetic tiles moves to the position, corresponding to the second blanking station 5, on the fifth layer conveying line 85, a worker starts working;

thirdly, a worker A places the burning bearing plate filled with the blank magnetic shoe on the feeding rotary line 12 at the second feeding station 9, and a worker B takes down the sintered magnetic shoe and the burning bearing plate from the blanking rotary line 2 at the first blanking station 3 and places the sintered magnetic shoe and the burning bearing plate on a turnover support;

fourthly, taking out the sintered magnetic tiles of the fifth layer conveying line 85 from the work-on and work-off time from the burning bearing plate at the second blanking station 5 by a worker C, and then putting the blank magnetic tiles into an empty burning bearing plate by a worker D;

(V) the return conveying line 86 starts working, the burning bearing plate with the blank magnetic tiles moves to the right end of the fifth-layer conveying line 85, the second robot 7 conveys the burning bearing plate with the blank magnetic tiles to the right end of the return conveying line 86, when the burning bearing plate with the blank magnetic tiles moves from the right end to the left end of the return conveying line 86, the first robot 4 conveys the burning bearing plate with the blank magnetic tiles to the left end of the first-layer conveying line 81 from the left end of the return conveying line 86, when the burning bearing plate with the blank magnetic tiles moves from the left end to the right end of the first-layer conveying line 81, the second robot 7 conveys the burning bearing plate with the blank magnetic tiles to the right end of the second-layer conveying line 82, when the burning bearing plate with the blank magnetic tiles moves from the right end to the left end of the second-layer conveying line 82, the first robot 4 conveys the burning bearing plate with the blank magnetic tiles to the left end of the third-layer conveying line 83 until the burning bearing plate with the blank magnetic tiles moves to the position, corresponding to the second-layer blanking station 5, on the fifth-layer conveying line 85 At that time, the worker starts to leave work, and the cycle is performed.

The model of the electric kiln 1 in the embodiment is RA13-118 × 4500 × 15/UM, which is sold by 48 th research institute of Chinese electronic technology group; the model of the blanking rotary line 2 and the feeding rotary line 12 is KSH01-50-B400-L1500-500-30-G-B, and is sold by Yihe Dada manufacturers; the first robot 4 and the second robot 7 are in the model of IRB 260-30/1.5 and are sold by ABB manufacturers; the model of the storage conveying line 8 is 20000 x 600 x 2000-6, and the storage conveying line is sold by a new assembly line equipment manufacturer of Dongguan Wan; the in-place sensor 11 is model number E3Z-B812M, sold by Ohioron manufacturers; the controller is model FX3U-128MR/ES-A, sold by Mitsubishi, Japan.

Example 2

The present embodiment is different from embodiment 1 in that: specifically, one more station is added to one side of the second blanking station 5 and one side of the first loading station 6 respectively.

Through adopting above-mentioned technical scheme, carry out the unloading of magnetic shoe by two workman, two workmans carry out the material loading of magnetic shoe, reduce workman's intensity of labour.

In conclusion, the rotary line can be extended by arranging the storage conveying line, and the robot can be used for loading and unloading, so that a loading worker who cancels a magnetic shoe blank in the night shift and a blanking worker who burns a magnetic shoe finished product are eliminated; the working environment temperature of the electric kiln is high, when workers work, refrigerating facilities such as air conditioners and fans on posts need to work, workers only need to work for eight hours, and the refrigerating facilities do not need to work during the rest time of the workers, so that the use of electric power resources can be reduced; the invention is beneficial to relieving the problem of difficult post recruitment, can reduce the use amount of manpower and the labor intensity of workers, and has low equipment cost and high stability.

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

Claims (8)

1. A method for realizing a rotary line extension device of an electric kiln for sintering magnetic tiles is characterized by comprising the following steps:

when workers leave work, the return conveyor line (86) does not work, the first robot (4) conveys the burning bearing plate provided with the sintered magnetic tiles on the blanking rotary line (2) to the left end of the first-layer conveyor line (81), and meanwhile, the second robot (7) conveys the burning bearing plate provided with the blank magnetic tiles at the right end of the fifth-layer conveyor line (85) to the feeding rotary line (12);

when the burning bearing plate with the sintered magnetic tiles moves from the left end to the right end of the first layer conveying line (81), the second robot (7) conveys the burning bearing plate with the sintered magnetic tiles to the right end of the second layer conveying line (82), when the burning bearing plate with the sintered magnetic tiles moves from the right end to the left end of the second layer conveying line (82), the first robot (4) conveys the burning bearing plate with the sintered magnetic tiles to the left end of the third layer conveying line (83), and workers start working when the burning bearing plate with the sintered magnetic tiles moves to the position, corresponding to the second blanking station (5), on the fifth layer conveying line (85);

thirdly, a worker A places the burning bearing plate filled with the blank magnetic shoe on a feeding rotary line (12) at a second feeding station (9), and a worker B takes down the sintered magnetic shoe and the burning bearing plate from a discharging rotary line (2) at a first discharging station (3) and places the sintered magnetic shoe and the burning bearing plate on a turnover support;

fourthly, taking out the sintered magnetic tiles of the fifth layer conveyor line (85) in the working time from the work place to the work place from the burning bearing plate by a worker C at the second blanking station (5), and then putting the blank magnetic tiles into an empty burning bearing plate by a worker D;

(V) the return conveying line (86) starts to work, the burning bearing plate filled with the blank magnetic tiles moves to the right end of the fifth conveying line (85), the second robot (7) conveys the burning bearing plate filled with the blank magnetic tiles to the right end of the return conveying line (86), when the burning bearing plate filled with the blank magnetic tiles moves from the right end to the left end of the return conveying line (86), the first robot (4) conveys the burning bearing plate filled with the blank magnetic tiles to the left end of the first layer conveying line (81) from the left end of the return conveying line (86), when the burning bearing plate filled with the blank magnetic tiles moves from the left end to the right end of the first layer conveying line (81), the second robot (7) conveys the burning bearing plate filled with the blank magnetic tiles to the right end of the second layer conveying line (82), when the burning bearing plate filled with the blank magnetic tiles moves from the right end to the left end of the second layer conveying line (82), the first robot (4) conveys the burning bearing plate filled with the blank magnetic tiles to the left end of the third layer (83), and (3) starting workers to leave work until the burning bearing plate filled with the blank magnetic tiles moves to the position corresponding to the second blanking station (5) on the fifth-layer conveying line (85), and circulating.

2. The method for realizing the extension device of the rotary line of the magnetic shoe sintering electric kiln according to the claim 1 is characterized in that: the storage conveying line (8) comprises a first layer conveying line (81), a second layer conveying line (82), a third layer conveying line (83), a fourth layer conveying line (84), a fifth layer conveying line (85) and a return conveying line (86), wherein the first layer conveying line (81), the second layer conveying line (82), the third layer conveying line (83), the fourth layer conveying line (84), the fifth layer conveying line (85) and the return conveying line (86) are sequentially arranged from bottom to top, the moving direction of the first layer conveying line (81) is from left to right, the moving direction of the second layer conveying line (82) is from right to left, the moving direction of the third layer conveying line (83) is from left to right, the moving direction of the fourth layer conveying line (84) is from right to left, the moving direction of the fifth layer conveying line (85) is from left to right, and the moving direction of the return conveying line (86) is from right to left, the ends of the first layer conveying line (81), the second layer conveying line (82), the third layer conveying line (83), the fourth layer conveying line (84), the fifth layer conveying line (85), the return conveying line (86) and the blanking revolving line (2) are connected with a baffle (10), first layer transfer chain (81), second floor transfer chain (82), third layer transfer chain (83), fourth layer transfer chain (84), fifth layer transfer chain (85), return transfer chain (86), the tip of unloading gyration line (2) and material loading gyration line (12) all is connected with two inductors (11) that target in place, two distance that target in place between inductor (11) equals the length of holding the fever board, inductor (11) and controller signal connection target in place, first unloading station (3), second unloading station (5), first material loading station (6) and second material loading station (9) are the worker's station.

3. The rotary line extension device for a magnetic shoe sintering electric kiln used in the method for realizing the rotary line extension device for a magnetic shoe sintering electric kiln according to claim 1 or 2, characterized in that: comprises an electric kiln (1), a feeding end of the electric kiln (1) is provided with a feeding rotary line (12), a discharging end of the electric kiln (1) is provided with a discharging rotary line (2), the discharging rotary line (2) is connected with the feeding rotary line (12) through a storage conveying line (8), one end of the discharging rotary line (2) close to the storage conveying line (8) is provided with a first discharging station (3), one end of the feeding rotary line (12) close to the storage conveying line (8) is provided with a second feeding station (9), one side of the storage conveying line (8) far away from the electric kiln (1) is respectively provided with a second discharging station (5) and a first feeding station (6), one side of the storage conveying line (8) close to the electric kiln (1) is respectively provided with a first robot (4) and a second robot (7), and the first robot (4) and the second discharging station (5) are positioned at one end close to the discharging rotary line (2), the first feeding station (6) and the second robot (7) are positioned at one end close to the feeding rotary line (12), and the electric kiln (1), the blanking rotary line (2), the first robot (4), the second robot (7), the storage conveying line (8) and the feeding rotary line (12) are respectively in signal connection with the controller.

4. The rotary line extension device for the magnetic shoe sintering electric kiln used in the realization method of the rotary line extension device for the magnetic shoe sintering electric kiln according to claim 3, characterized in that: store transfer chain (8) and include first layer transfer chain (81), second floor transfer chain (82), third layer transfer chain (83), fourth floor transfer chain (84), fifth layer transfer chain (85) and return transfer chain (86), wherein, first layer transfer chain (81), second floor transfer chain (82), third layer transfer chain (83), fourth floor transfer chain (84), fifth layer transfer chain (85) and return transfer chain (86) set gradually from supreme down.

5. The rotary line extension device for the magnetic shoe sintering electric kiln used in the realization method of the rotary line extension device for the magnetic shoe sintering electric kiln according to claim 4, characterized in that: the moving direction of the first layer conveying line (81) is from left to right, the moving direction of the second layer conveying line (82) is from right to left, the moving direction of the third layer conveying line (83) is from left to right, the moving direction of the fourth layer conveying line (84) is from right to left, the moving direction of the fifth layer conveying line (85) is from left to right, and the moving direction of the return conveying line (86) is from right to left.

6. The rotary line extension device for the magnetic shoe sintering electric kiln used in the realization method of the rotary line extension device for the magnetic shoe sintering electric kiln according to claim 5, characterized in that: the end parts of the first layer conveying line (81), the second layer conveying line (82), the third layer conveying line (83), the fourth layer conveying line (84), the fifth layer conveying line (85), the return conveying line (86) and the blanking rotary line (2) are all connected with a baffle (10).

7. The rotary line extension device for the magnetic shoe sintering electric kiln used in the realization method of the rotary line extension device for the magnetic shoe sintering electric kiln according to claim 6, characterized in that: the end parts of the first layer conveying line (81), the second layer conveying line (82), the third layer conveying line (83), the fourth layer conveying line (84), the fifth layer conveying line (85), the return conveying line (86), the blanking rotary line (2) and the feeding rotary line (12) are respectively connected with two in-place inductors (11), the distance between the two in-place inductors (11) is equal to the length of a burning bearing plate, and the in-place inductors (11) are in signal connection with the controller.

8. The rotary line extension device for the magnetic shoe sintering electric kiln used in the realization method of the rotary line extension device for the magnetic shoe sintering electric kiln according to claim 7, characterized in that: the first blanking station (3), the second blanking station (5), the first loading station (6) and the second loading station (9) are manual stations.

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