CN212792988U - Rail mounted binary channels molten iron transfer device - Google Patents

Abstract

The utility model discloses a rail type double-channel molten iron transfer device; belongs to the technical field of ladle transfer; the ladle pouring device is characterized by comprising a rail parallel to the moving direction of a casting machine, wherein one end of the rail extends to a ladle processing area, a ladle feeding conveying belt and a ladle returning conveying belt which are mutually arranged are arranged between the rail and the casting machine, and a ladle transferring trolley matched with the ladle feeding conveying belt and the ladle returning conveying belt is arranged on the rail; the ladle transfer trolley comprises a frame, a moving wheel arranged on the frame and matched with a rail and a speed reduction driving motor arranged on the frame and linked with the moving wheel, wherein a ladle conveying belt and an electric cabinet matched with a ladle feeding conveying belt and a ladle returning conveying belt are arranged on the frame, and the speed reduction driving motor is connected with the electric cabinet through a circuit; the utility model aims to provide a track type double-channel molten iron transfer device with compact structure, convenient use and good effect; the method is used for ladle transportation during pouring.

Description

Rail mounted binary channels molten iron transfer device

Technical Field

The utility model relates to a molten iron transfer device, more specifically say, especially relate to a rail mounted binary channels molten iron transfer device.

Background

After the ladle is spheroidized in the processing area, the ladle is generally transported to a casting machine for casting by adopting a crane for hoisting or a rail. The former has high working efficiency but lower safety factor. The reason why the latter has low working efficiency but higher safety factor and low efficiency is that the existing rail type molten iron transfer device adopts a single ladle for transfer, namely the spheroidized ladle is transferred to a casting machine through a transfer trolley, the spheroidized ladle is transferred to a rotary transfer trolley after casting is finished, and the transport trolley transfers an empty ladle to a processing area to reload molten iron and then transfer the reloaded molten iron to the casting machine. The mode has the defects that the casting machine and the transfer trolley are idle or have long waiting time, and the working efficiency is lower.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to the not enough of above-mentioned prior art, provide a compact structure, convenient to use and respond well rail mounted binary channels molten iron transfer device.

The technical scheme of the utility model is realized like this: a rail type double-channel molten iron transfer device comprises a rail parallel to the moving direction of a casting machine, wherein one end of the rail extends to a molten iron ladle processing area, a ladle feeding conveying belt and a ladle returning conveying belt which are mutually arranged are arranged between the rail and the casting machine, and a molten iron ladle transfer trolley matched with the ladle feeding conveying belt and the ladle returning conveying belt is arranged on the rail; the bag feeding conveying belt and the bag returning conveying belt are respectively connected with an external main controller through circuits.

The ladle transfer trolley comprises a frame, a moving wheel and a speed reduction driving motor, wherein the moving wheel is arranged on the frame and matched with a rail, the speed reduction driving motor is arranged on the frame and linked with the moving wheel, an electric cable winder is arranged at the bottom of the frame, a ladle conveying belt and an electric cabinet are arranged on the frame and matched with the ladle conveying belt and the ladle returning conveying belt, and the speed reduction driving motor and the electric cable winder are respectively connected with the electric cabinet through circuits.

In the rail-mounted double-channel molten iron transfer device, a first ladle inlet inductive switch is arranged on the end surface of the ladle inlet conveying belt opposite to the ladle transfer trolley, a first ladle inlet position speed reduction inductive switch and a first ladle inlet position stop inductive switch which are matched with the first ladle inlet inductive switch are arranged on the ladle transfer trolley, the first ladle inlet inductive switch is connected with the electric cabinet through a circuit, and the first ladle inlet position speed reduction inductive switch and the first ladle inlet position stop inductive switch are respectively connected with an external main controller through a circuit; when the first ladle inlet induction switch is opposite to the first ladle inlet position stop induction switch, the ladle conveying belt corresponds to the ladle inlet conveying belt.

In the rail-mounted double-channel molten iron transfer device, a first ladle-returning induction switch is arranged on the end surface of the ladle-returning conveying belt opposite to the ladle transfer trolley, a first ladle-returning position speed-reducing induction switch and a first ladle-returning position stop induction switch which are matched with the first ladle-returning induction switch are arranged on the ladle transfer trolley, the first ladle-returning induction switch is connected with the electric cabinet through a circuit, and the first ladle-returning position speed-reducing induction switch and the first ladle-returning position stop induction switch are respectively connected with an external main controller through a circuit; when the first packet returning induction switch is opposite to the first packet returning position stop induction switch, the ladle conveying belt corresponds to the packet returning conveying belt.

In the rail type double-channel molten iron transfer device, a second ladle inlet position speed reducing induction switch and a second ladle inlet position stopping induction switch are arranged on one side surface of the ladle transfer trolley away from the ladle inlet conveying belt, induction blocks matched with the second ladle inlet position speed reducing induction switch and the second ladle inlet position stopping induction switch are arranged on the side edge of the rail corresponding to the ladle processing area, and the second ladle inlet position speed reducing induction switch and the second ladle inlet position stopping induction switch are respectively connected with the electric cabinet through circuits; when the second ladle inlet position stop induction switch is in contact with the induction block, the ladle transfer trolley stops at the end part of the rail of the ladle processing area.

In the rail type double-channel molten iron transfer device, the end part of the rail positioned at the side edge of the ladle conveying belt is provided with the limiting block matched with the moving wheel.

In the rail type double-channel molten iron transfer device, the ladle conveying belt is a roller conveying belt, each roller is linked through a chain and a chain wheel, and one of the rollers is connected with a ladle inlet speed reducing motor; a third ladle feeding position speed reduction inductive switch and a third ladle feeding position stop inductive switch which are matched with the ladle are arranged at the near end part of the discharge end of the ladle feeding conveying belt, and the third ladle feeding position speed reduction inductive switch and the third ladle feeding position stop inductive switch are respectively connected with an external main controller circuit; when the third ladle inlet position stop induction switch detects the ladle, the ladle inlet conveying belt stops working, and the ladle is positioned at the discharge end of the ladle inlet conveying belt and is also a ladle inlet station of the casting machine.

In the rail-type dual-channel molten iron transfer device, the ladle-returning conveyer belt is a roller conveyer belt, each roller is linked through a chain and a chain wheel, and one of the rollers is connected with a ladle-returning speed reduction motor; a second ladle-withdrawing position speed-reducing inductive switch and a second ladle-withdrawing position stop inductive switch which are matched with the ladle are arranged at the near end part of the discharge end of the ladle-withdrawing conveying belt, and the second ladle-withdrawing position speed-reducing inductive switch and the second ladle-withdrawing position stop inductive switch are respectively connected with an external main controller through circuits; when the second ladle-returning position stop induction switch detects the ladle, the ladle-returning conveyer belt stops working, and the ladle is positioned at the discharge end of the ladle-returning conveyer belt and is also the ladle-returning position of the ladle transfer trolley.

In the rail-type dual-channel molten iron transfer device, a second ladle inlet inductive switch is arranged on the end surface of the ladle inlet conveyer belt opposite to the casting machine, a second ladle outlet inductive switch is arranged on the end surface of the ladle outlet conveyer belt opposite to the casting machine, and the second ladle inlet inductive switch and the second ladle outlet inductive switch are respectively connected with an external main controller through circuits; a fourth ladle inlet position speed reducing induction switch and a fourth ladle inlet position stopping induction switch which are matched with the second ladle inlet induction switch are arranged on the casting machine, and a third ladle outlet position speed reducing induction switch and a third ladle outlet position stopping induction switch which are matched with the second ladle outlet induction switch are arranged on the casting machine; the fourth ladle inlet position speed reduction inductive switch, the fourth ladle inlet position stop inductive switch, the third ladle outlet position speed reduction inductive switch and the third ladle outlet position stop inductive switch are respectively connected with a control system circuit of the casting machine.

In the above track type dual-channel molten iron transfer device, a near-end portion of a tail end of the ladle conveyor belt in the conveying direction is provided with a fifth ladle position deceleration induction switch and a fifth ladle position stop induction switch which are matched with the ladle, and the fifth ladle position deceleration induction switch and the fifth ladle position stop induction switch are respectively connected with the electric cabinet through circuits; when the fifth ladle inlet position stop induction switch detects the ladle, the ladle conveying belt stops working, and the ladle is completely positioned on the ladle conveying belt; and a protective baffle matched with the ladle is fixedly connected to the frame corresponding to the output end of the ladle conveying belt.

In the rail type double-channel molten iron transfer device, the feeding end of the ladle conveying belt is provided with the auxiliary induction switch matched with the ladle, and the auxiliary induction switch is connected with the electric cabinet circuit.

The above structure is adopted in the utility model, through set up into a packet conveyer belt and move back a packet conveyer belt between track and casting machine, reunion ladle transports the dolly for in the pouring process, two ladles participate in simultaneously transporting, the casting machine can advance to wrap at once and continue the pouring after moving back a packet, work efficiency is showing and is improving, when the pouring, the ladle transports the dolly then can transport empty package to the processing district and pack again. The structure greatly improves the pouring efficiency while ensuring the production safety.

Drawings

The present invention will be described in further detail with reference to the following examples, which are not intended to limit the invention.

Fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a schematic side view of the present invention;

fig. 3 is a schematic structural view of the ladle transfer trolley of the utility model.

In the figure: 1. a track; 2. a bag feeding conveyer belt; 2a, a first packet inlet inductive switch; 2b, a third bag-entering position speed reduction inductive switch; 2c, a third package inlet position stop induction switch; 2d, a second bag inlet inductive switch; 3. an unpacking and conveying belt; 3a, a first unpacking inductive switch; 3b, a second speed reduction inductive switch at the packet withdrawing position; 3c, a second packet withdrawing position stop induction switch; 3d, a second unpacking inductive switch; 4. a ladle transfer trolley; 4a, a frame; 4b, a moving wheel; 4c, reducing the speed of the driving motor; 4d, an electric cable winder; 4e, a ladle conveyer belt; 4f, an electric cabinet; 4g, a first bag inlet position speed reduction inductive switch; 4h, stopping the inductive switch at the first packet inlet position; 4i, a first bag withdrawing position speed reducing induction switch; 4j, a first packet-withdrawing position stop induction switch; 4k, a second packet-entering position speed-reducing inductive switch; 4l, a second package inlet position stop induction switch; a 4m and fifth bag-entering position speed-reducing inductive switch; 4n, a fifth packet inlet position stop induction switch; 5. an induction block; 6. a limiting block; 7. a protective baffle; 8. an auxiliary inductive switch.

Detailed Description

Referring to fig. 1 to 3, the utility model discloses a rail-mounted double-channel molten iron transfer device, including a rail 1 parallel to the moving direction of a casting machine, wherein one end of the rail 1 extends to a ladle processing area, a ladle feeding conveyer belt 2 and a ladle returning conveyer belt 3 which are mutually arranged are arranged between the rail 1 and the casting machine, and a ladle transfer trolley 4 matched with the ladle feeding conveyer belt 2 and the ladle returning conveyer belt 3 is arranged on the rail 1; the bag feeding conveying belt and the bag returning conveying belt are respectively connected with an external main controller through circuits.

The ladle transfer trolley 4 comprises a frame 4a, a moving wheel 4b arranged on the frame 4a and matched with the track 1, and a speed reduction driving motor 4c arranged on the frame 4a and linked with the moving wheel 4b, wherein an electric cable winder 4d is arranged at the bottom of the frame 4a, a ladle conveying belt 4e and an electric cabinet 4f which are matched with the ladle conveying belt 2 and the ladle returning conveying belt 3 are arranged on the frame 4a, and the speed reduction driving motor 4c and the electric cable winder 4d are respectively in circuit connection with the electric cabinet 4 f.

Preferably, a first ladle inlet induction switch 2a is arranged on the end face of the ladle inlet conveying belt 2 opposite to the ladle transfer trolley 4, a first ladle inlet position speed reduction induction switch 4g and a first ladle inlet position stop induction switch 4h which are matched with the first ladle inlet induction switch 2a are arranged on the ladle transfer trolley 4, the first ladle inlet induction switch 2a is connected with the electric cabinet through a circuit, and the first ladle inlet position speed reduction induction switch 4g and the first ladle inlet position stop induction switch 4h are respectively connected with the external master controller through a circuit; when the first ladle inlet induction switch 2a is opposite to the first ladle inlet position stop induction switch 4h, the ladle conveying belt 4e corresponds to the ladle inlet conveying belt 2.

Meanwhile, a first ladle-returning induction switch 3a is arranged on the end face of the ladle-returning conveying belt 3 opposite to the ladle transfer trolley 4, a first ladle-returning position speed-reducing induction switch 4i and a first ladle-returning position stop induction switch 4j which are matched with the first ladle-returning induction switch 3a are arranged on the ladle transfer trolley 4, the first ladle-returning induction switch 3a is in circuit connection with the electric cabinet 4f, and the first ladle-returning position speed-reducing induction switch 4i and the first ladle-returning position stop induction switch 4j are respectively in circuit connection with an external main controller; when the first ladle-returning induction switch 3a is opposite to the first ladle-returning position stop induction switch 4j, the ladle conveying belt 4e corresponds to the ladle-returning conveying belt 3.

Through setting up first packet position sensor switch and first packet position speed reduction sensor switch 4g and the cooperation of first packet position stop sensor switch 4h of advancing. Meanwhile, a first bag-withdrawing induction switch 3a is matched with a first bag-withdrawing position speed-reducing induction switch 4i and a first bag-withdrawing position stop induction switch 4 j. Two mutual inductance ends are sensors, so that the ladle transfer trolley can form an independent control unit without being connected with an external master controller and can be matched with a ladle feeding conveying belt and a ladle returning conveying belt. In addition, the weight of the ladle is large, high-temperature molten iron is filled in the ladle, and the deceleration induction and the stop induction are arranged, so that the motor is prevented from being damaged when the motor is suddenly stopped, and the molten iron in the ladle is prevented from shaking and splashing due to the sudden stop of the conveying belt.

Further preferably, a second ladle-entering position deceleration induction switch 4k and a second ladle-entering position stop induction switch 4l are arranged on one side surface of the ladle transfer trolley 4 away from the ladle-entering conveying belt 2, an induction block 5 matched with the second ladle-entering position deceleration induction switch 4k and the second ladle-entering position stop induction switch 4l is arranged on the side edge of the rail 1 corresponding to the ladle processing area, and the second ladle-entering position deceleration induction switch 4k and the second ladle-entering position stop induction switch 4l are respectively in circuit connection with the electric cabinet 4 f; when the second ladle-entering position stop induction switch 4l is in contact with the induction block 5, the ladle transfer trolley 4 stops at the end of the rail 1 of the ladle processing area. In order to improve the safety, the end part of the track 1 positioned at the side edge of the bag feeding conveyer belt 2 is provided with a limiting block 6 matched with the moving wheel 4 b. The effect of this structure lies in controlling ladle transport dolly and slowing down earlier then stopping when getting into the ladle processing district, avoids stopping suddenly and causes the damage to the motor, also avoids the dolly to stop suddenly and causes the ladle to take place to remove because of inertia.

In this embodiment, the bag feeding conveyor belt 2 is a roller conveyor belt, each roller is linked through a chain and a sprocket, and one of the rollers is connected with a bag feeding speed reducing motor; a third ladle inlet position speed reducing induction switch 2b and a third ladle inlet position stopping induction switch 2c which are matched with the ladle are arranged at the near end part of the discharge end of the ladle inlet conveying belt 2, and the third ladle inlet position speed reducing induction switch 2b and the third ladle inlet position stopping induction switch 2c are respectively connected with an external main controller through circuits; when the third ladle inlet position stop induction switch 2c detects the ladle, the ladle inlet conveying belt 2 stops working, and the ladle is positioned at the discharge end of the ladle inlet conveying belt 2 and is also a ladle inlet station of the casting machine.

Correspondingly, the package-withdrawing conveying belt 3 is a roller conveying belt, each roller is linked through a chain and a chain wheel, and one roller is connected with a package-withdrawing speed-reducing motor; a second ladle-withdrawing position speed-reducing induction switch 3b and a second ladle-withdrawing position stopping induction switch 3c which are matched with the ladle are arranged at the near end part of the discharge end of the ladle-withdrawing conveying belt 3, and the second ladle-withdrawing position speed-reducing induction switch 3b and the second ladle-withdrawing position stopping induction switch 3c are respectively connected with an external main controller through circuits; when the second ladle-returning position stop inductive switch 3c detects the ladle, the ladle-returning conveyer belt 3 stops working, and the ladle is positioned at the discharge end of the ladle-returning conveyer belt 3 and is also the ladle-returning station of the ladle transfer trolley 4.

Through each speed reduction inductive switch of equipment and stop inductive switch, its effect is the same with above-mentioned inductive switch, all is to avoid the motor to stop suddenly and cause the damage and avoid the ladle to take place the displacement because of inertia and cause the accident simultaneously.

Further preferably, in order to enable the casting machine to decelerate first and then stop as the ladle moving trolley, a second ladle feeding induction switch 2d is arranged on the end surface of the ladle feeding conveyer belt 2 opposite to the casting machine, a second ladle returning induction switch 3d is arranged on the end surface of the ladle returning conveyer belt 3 opposite to the casting machine, and the second ladle feeding induction switch 2d and the second ladle returning induction switch 3d are respectively connected with an external master controller through circuits; a fourth ladle inlet position speed reducing induction switch and a fourth ladle inlet position stopping induction switch which are matched with the second ladle inlet induction switch 2d, and a third ladle outlet position speed reducing induction switch and a third ladle outlet position stopping induction switch which are matched with the second ladle outlet induction switch 3d are arranged on the casting machine; the fourth ladle inlet position speed reduction inductive switch, the fourth ladle inlet position stop inductive switch, the third ladle outlet position speed reduction inductive switch and the third ladle outlet position stop inductive switch are respectively connected with a control system circuit of the casting machine.

Further preferably, a fifth ladle-entering position speed-reducing induction switch 4m and a fifth ladle-entering position stopping induction switch 4n which are matched with the ladle are arranged at the near end part of the tail end of the ladle conveying belt 4e along the conveying direction, and the fifth ladle-entering position speed-reducing induction switch 4m and the fifth ladle-entering position stopping induction switch 4n are respectively in circuit connection with the electric cabinet 4 f; when the fifth ladle inlet position stop inductive switch 4n detects the ladle, the ladle conveying belt 4e stops working, and the ladle is completely positioned on the ladle conveying belt 4 e; a protective baffle 7 matched with the ladle is fixedly connected to the frame 4a corresponding to the output end of the ladle conveying belt 4 e. The fifth ladle position deceleration induction switch 4m and the fifth ladle position stop induction switch 4n also avoid damage caused by sudden stop of the motor and accidents caused by displacement of the ladle due to inertia.

Further preferably, an auxiliary induction switch 8 matched with the ladle is arranged at the feeding end of the ladle conveying belt 4e, and the auxiliary induction switch 8 is in circuit connection with the electric cabinet 4 f. The auxiliary induction switch has the function of ensuring that when the ladle completely enters the ladle conveying belt or completely moves out of the ladle conveying belt, subsequent actions are executed, and accidents caused by the fact that the ladle is not moved in place and the actions of the next step are carried out are avoided.

When the ladle transporting trolley works, a spheroidized ladle is loaded in a ladle processing area and moves towards a casting machine, when a first ladle inlet inductive switch senses a first ladle inlet position deceleration inductive switch, a deceleration driving motor on the trolley starts to decelerate at a preset speed, when the first ladle inlet inductive switch senses a first ladle inlet position stop inductive switch, the deceleration driving motor on the trolley stops working, and meanwhile, a ladle conveying belt is started to convey the ladle to the ladle conveying belt. When the auxiliary induction switch detects that the ladle is completely separated from the ladle transfer trolley, the ladle conveying belt stops and is manually started by a worker, when the third ladle inlet position speed reduction induction switch on the ladle conveying belt detects the ladle, the ladle conveying belt decelerates, and when the third ladle inlet position speed reduction induction switch detects the ladle, the ladle conveying belt stops.

The casting machine stops at the ladle returning position under the matching of the second ladle returning induction switch, the corresponding third ladle returning position deceleration induction switch and the third ladle returning position stop induction switch, the cast ladle is sent into a ladle returning conveyer belt, the ladle returning conveyer belt is started under the control of a worker, the ladle returning conveyer belt sends the empty ladle to a preset position under the matching of the second ladle returning position deceleration induction switch and the second ladle returning position stop induction switch and then stops, and the trolley waits for the ladle to be transported.

The trolley which sends the ladle filled with the molten iron carries out the operation of receiving the empty ladle, the ladle conveying belt is opposite to the ladle returning conveying belt under the matching of the first ladle returning induction switch, the first ladle returning position speed reduction induction switch and the first ladle returning position stop induction switch, the external main controller starts the ladle returning conveying belt to convey the empty ladle to the ladle conveying belt, when the auxiliary induction switch detects that the ladle completely passes through, the ladle conveying belt is started, when the third ladle returning position speed reduction induction switch detects the ladle, the ladle feeding conveying belt is decelerated, and when the third ladle returning position stop induction switch detects the ladle, the ladle feeding conveying belt is stopped. And after the recovery operation of the empty foundry ladles is finished, the foundry ladle transfer trolley returns to the foundry ladle processing area to reload the foundry ladles.

The above embodiment is the preferred embodiment of the present invention, which is only used to facilitate the explanation of the present invention, it is not right to the present invention, which makes the restriction on any form, and any person who knows commonly in the technical field can use the present invention to make the equivalent embodiment of local change or modification without departing from the technical features of the present invention.

Claims (10)

1. A rail type double-channel molten iron transfer device comprises a rail (1) parallel to the moving direction of a casting machine, wherein one end of the rail (1) extends to a molten iron ladle processing area, and is characterized in that a ladle feeding conveying belt (2) and a ladle returning conveying belt (3) which are mutually arranged are arranged between the rail (1) and the casting machine, and a molten iron ladle transfer trolley (4) matched with the ladle feeding conveying belt (2) and the ladle returning conveying belt (3) is arranged on the rail (1); the bag feeding conveyer belt (2) and the bag returning conveyer belt (3) are respectively connected with an external main controller through circuits;

ladle transport trolley (4) include frame (4a), set up on frame (4a) and with track (1) matched with removal wheel (4b) and set up on frame (4a) and with speed reduction driving motor (4c) that remove wheel (4b) linkage, be provided with electronic cable rolling ware (4d) bottom frame (4a), be provided with on frame (4a) with advance a packet conveyer belt (2) and move back packet conveyer belt (3) matched with ladle conveyer belt (4e) and electric cabinet (4f), speed reduction driving motor (4c) and electronic cable rolling ware (4d) respectively with electric cabinet (4f) circuit connection.

2. The rail type double-channel molten iron transfer device according to claim 1, wherein a first ladle entering induction switch (2a) is arranged on the end face of the ladle entering conveying belt (2) opposite to the ladle transfer trolley (4), a first ladle entering position speed reducing induction switch (4g) and a first ladle entering position stopping induction switch (4h) which are matched with the first ladle entering induction switch (2a) are arranged on the ladle transfer trolley (4), the first ladle entering induction switch (2a) is in circuit connection with an electric cabinet, and the first ladle entering position speed reducing induction switch (4g) and the first ladle entering position stopping induction switch (4h) are in circuit connection with an external master controller respectively; when the first ladle inlet induction switch (2a) is opposite to the first ladle inlet position stop induction switch (4h), the ladle conveying belt (4e) corresponds to the ladle inlet conveying belt (2).

3. The rail type double-channel molten iron transfer device according to claim 1, wherein a first ladle-returning induction switch (3a) is arranged on the end surface of the ladle-returning conveying belt (3) opposite to the ladle-transferring trolley (4), a first ladle-returning position speed-reducing induction switch (4i) and a first ladle-returning position stop induction switch (4j) which are matched with the first ladle-returning induction switch (3a) are arranged on the ladle-transferring trolley (4), the first ladle-returning induction switch (3a) is in circuit connection with an electric cabinet (4f), and the first ladle-returning position speed-reducing induction switch (4i) and the first ladle-returning position stop induction switch (4j) are in circuit connection with an external master controller respectively; when the first ladle-returning induction switch (3a) is opposite to the first ladle-returning position stop induction switch (4j), the ladle conveying belt (4e) is corresponding to the ladle-returning conveying belt (3).

4. The rail type double-channel molten iron transfer device according to claim 1, wherein a second ladle entering position speed reducing induction switch (4k) and a second ladle entering position stopping induction switch (4l) are arranged on one side surface of the ladle transfer trolley (4) far away from the ladle feeding conveying belt (2), an induction block (5) matched with the second ladle entering position speed reducing induction switch (4k) and the second ladle entering position stopping induction switch (4l) is arranged on the side edge of the rail (1) corresponding to the ladle processing area, and the second ladle entering position speed reducing induction switch (4k) and the second ladle entering position stopping induction switch (4l) are respectively in circuit connection with the electric control box (4 f); when the second ladle inlet position stop induction switch (4l) is in contact with the induction block (5), the ladle transfer trolley (4) stops at the end of the rail (1) of the ladle machining area.

5. The rail type double-channel molten iron transfer device as claimed in claim 1, 2 or 4, wherein the end of the rail (1) at the side of the ladle conveying belt (2) is provided with a limit block (6) matched with the moving wheel (4 b).

6. The rail type double-channel molten iron transfer device as claimed in claim 1, wherein the ladle conveying belt (2) is a roller conveying belt, each roller is linked through chain and chain wheel connection, and one of the rollers is connected with a ladle speed reducing motor; a third ladle inlet position speed reducing induction switch (2b) and a third ladle inlet position stopping induction switch (2c) which are matched with the ladle are arranged at the near end part of the discharge end of the ladle inlet conveying belt (2), and the third ladle inlet position speed reducing induction switch (2b) and the third ladle inlet position stopping induction switch (2c) are respectively connected with an external main controller through circuits; when the third ladle inlet position stop induction switch (2c) detects the ladle, the ladle inlet conveying belt (2) stops working, and the ladle is positioned at the discharge end of the ladle inlet conveying belt (2) and is also a ladle inlet station of the casting machine.

7. The rail type dual-channel molten iron transfer device as claimed in claim 1, wherein the ladle-returning conveyer belt (3) is a roller conveyer belt, each roller is linked through a chain and a chain wheel, and one of the rollers is connected with a ladle-returning speed-reducing motor; a second ladle-withdrawing position speed-reducing induction switch (3b) and a second ladle-withdrawing position stopping induction switch (3c) which are matched with the ladle are arranged at the near end part of the discharge end of the ladle-withdrawing conveying belt (3), and the second ladle-withdrawing position speed-reducing induction switch (3b) and the second ladle-withdrawing position stopping induction switch (3c) are respectively connected with an external main controller through circuits; when the second ladle-returning position stop induction switch (3c) detects the ladle, the ladle-returning conveyer belt (3) stops working, and the ladle is positioned at the discharge end of the ladle-returning conveyer belt (3) and is also the ladle-returning station of the ladle transfer trolley (4).

8. The rail type double-channel molten iron transfer device as claimed in claim 1, wherein a second ladle feeding induction switch (2d) is arranged on the end face of the ladle feeding conveyer belt (2) opposite to the casting machine, a second ladle returning induction switch (3d) is arranged on the end face of the ladle returning conveyer belt (3) opposite to the casting machine, and the second ladle feeding induction switch (2d) and the second ladle returning induction switch (3d) are respectively connected with an external master controller circuit; a fourth ladle inlet position speed reducing induction switch and a fourth ladle inlet position stopping induction switch which are matched with the second ladle inlet induction switch (2d) are arranged on the casting machine, and a third ladle outlet position speed reducing induction switch and a third ladle outlet position stopping induction switch which are matched with the second ladle outlet induction switch (3d) are arranged on the casting machine; the fourth ladle inlet position speed reduction inductive switch, the fourth ladle inlet position stop inductive switch, the third ladle outlet position speed reduction inductive switch and the third ladle outlet position stop inductive switch are respectively connected with a control system circuit of the casting machine.

9. The rail-mounted double-channel molten iron transfer device as claimed in claim 1, wherein a fifth ladle-feeding position speed-reducing induction switch (4m) and a fifth ladle-feeding position stopping induction switch (4n) which are matched with the ladle are arranged at the near end part of the tail end of the ladle conveying belt (4e) along the conveying direction, and the fifth ladle-feeding position speed-reducing induction switch (4m) and the fifth ladle-feeding position stopping induction switch (4n) are respectively in circuit connection with the electric control box (4 f); when the fifth ladle inlet position stop induction switch (4n) detects the ladle, the ladle conveying belt (4e) stops working, and the ladle is completely positioned on the ladle conveying belt (4 e); a protective baffle (7) matched with the ladle is fixedly connected to the frame (4a) corresponding to the output end of the ladle conveying belt (4 e).

10. The rail type double-channel molten iron transfer device as claimed in claim 1 or 9, wherein an auxiliary inductive switch (8) matched with the ladle is arranged at the feeding end of the ladle conveying belt (4e), and the auxiliary inductive switch (8) is in circuit connection with the electric cabinet (4 f).

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