KR101027211B1 - System for manless control of charging car in coke plant - Google Patents

Abstract

One aspect of the present invention relates to a charging vehicle unmanned control system of the coke plant, and more particularly to a system for unmanned control of the position and operation of the charging vehicle until the charging car in the coke plant is completed from the coal mining.

The present invention is a position measuring header is provided on each side of the door of the coke oven, the position measuring header is attached to the RFID tag having the position information of the door of the coke oven; A position measuring sensor attached to a charging vehicle for charging coal in the coke oven, the position measuring sensor generating a current signal corresponding to the position information read from the RFID tag at a position separated from the positioning header by a specific distance; A motion detection sensor unit for detecting a motion of a facility provided in a door or a charging vehicle of a coke oven and generating a current signal corresponding to the operation of the facility; A position control unit which receives the current signal generated from the position measuring sensor and controls the position of the charging vehicle so that the charging vehicle can be stopped at one side of the door or the colvin side of the coke oven corresponding to the target position; And an operation control unit for receiving the current signal generated from the position measuring sensor or the motion detection sensor unit to control the operation of the facility.

Coke oven, charging car, unmanned control, position sensor, current signal

Description

System for manless control of charging car in coke plant}

One aspect of the present invention relates to a charging vehicle unmanned control system of the coke plant, and more particularly to a system for unmanned control of the position and operation of the charging vehicle until the charging car in the coke plant is completed from the coal mining.

In general, a coke oven has a rectangular box structure in which an oven into which coal is charged and a combustion chamber for burning fuel gas to supply heat required for coal drying are alternately connected. A partition is formed between the oven and the combustion chamber as a refractory brick such as silica brick, and conducts the heat of combustion generated in the combustion chamber through the partition, thereby supplying heat to the coal in the oven and distilling it.

1 is a perspective view illustrating a conventional coke oven, and FIG. 2 is a longitudinal cross-sectional view illustrating a conventional coke oven. As shown in Figure 1 and 2, the upper surface of the oven 10 is provided with a plurality of charging holes 21 for charging coal, the outer surface of the plurality of doors 22 having a refractory brick on the inner surface On the other hand, the charging vehicle 30 running along the rail 31 in the upper portion of the oven 10 is provided with a plurality of feeder cones 32 to charge the coal through the charging port (21).

The coal in the corbin 40 is supplied into the hopper 50 of the charging vehicle 30 when the gate 42 is opened, and the coal in the hopper 50 is hollow feeder tube 54 when the bunker gate 52 is opened. After supplying to the feeder cone 32, the lower end is in close contact with each charging hole 21 through the oven 10 is supplied to the coal drying operation.

Accordingly, the dry distillation coke in the oven 10 is moved from the extruder side to the opposite transfer car (not shown) side by an extruder (not shown) with both doors 22 open at the end of the coal distillation operation charged in the oven 10. Extruded and discharged.

As described above, in the coke factory, the operator has operated the charging vehicle manually and then operated by manually operating the respective devices provided in the charging vehicle.

Therefore, since the method of operating the apparatus provided in the charging vehicle is different depending on the sixth sense and the time of the operator, equipment accidents frequently occur due to the malfunction of the apparatus. In addition, there is a fear that the operation of the coke plant may be stopped, resulting in human and physical damage.

One aspect of the present invention aims at a system system for improving the efficiency of charging operation by controlling the position and operation of the charging vehicle unattended until the charging vehicle is completed from the coal mining in the coke plant.

One aspect of the present invention, a position measuring header is provided on each side of the door of the coke oven, the position measuring header is attached to the RFID tag having the position information of the door of the coke oven; A position measuring sensor attached to a charging vehicle for charging coal in the coke oven and generating a current signal corresponding to the position information read from the RFID tag at a position spaced apart from the position measuring header by a specific distance; A motion detection sensor unit for detecting a motion of a facility provided in a door or a charging vehicle of the coke oven and generating a current signal corresponding to the operation of the facility; A position control unit which receives the current signal generated by the position measuring sensor and controls the position of the charging vehicle so that the charging vehicle can be stopped at one side of the door or the colvin side of the coke oven corresponding to a target position; And an operation control unit for receiving a current signal generated from the position measuring sensor or the operation detecting sensor unit and controlling the operation of the facility.

In an embodiment of the present invention, the facility is any one of the rising pipe cover, bunker gate, dust collector, hand valve operation, U-tube, lead lifter, screw feeder, the unmanned vehicle control system of the coke plant to provide.

In an embodiment of the present invention, the position control unit, a position calculation unit for calculating the current position of the charging vehicle by counting the number of pulse signals generated from the encoder attached to the idle wheel of the charging vehicle; And a driving unit operating the motor provided in the charging vehicle to drive the charging vehicle to the calculated target position.

In an embodiment of the present invention, the operation control unit receives a current signal generated from the motion detection sensor unit, and provides the unmanned vehicle control system of the coke plant, characterized in that for operating the facility in the initial state.

Another aspect of the invention, the first step of driving the charging vehicle to the door of the coke oven corresponding to the target position; A second step of opening the riser by operating the riser cover provided in the door of the coke oven; A third step of driving the charged vehicle to a colvin storing coal; A fourth step of operating the bunker gate provided in the charging vehicle to open a call hopper of the charging vehicle to load coal stored in the colvin into the charging vehicle; A fifth step of driving the charging vehicle to a door of the coke oven corresponding to a target position; And a sixth step of charging coal in the coke oven.

In an embodiment of the present invention, the first step and the fifth step, the charging vehicle for charging the coal into the coke oven approaching the positioning header which is installed on each side of the door of the coke oven; The current corresponding to the positional information read from the RFID tag by the position sensor attached to the charging vehicle at a position spaced apart from the positioning header to which the RFID tag having the position information of the door of the coke oven is attached. Generating a signal; And controlling the position of the charging vehicle so that the charging vehicle can be stopped at one side of the door of the coke oven corresponding to the target position.

In an embodiment of the present invention, between the fourth step and the fifth step, operating the bunker gate in an initial state to close the call hopper, and further comprising the step of driving the charging vehicle to the standby position To provide an unmanned vehicle control method of the coke plant.

In an embodiment of the present invention, between the fifth step and the sixth step, the unmanned control of the coke plant further comprising the step of closing the riser by operating the riser cover to an initial state. Provide a method.

In an embodiment of the present invention, the sixth step may include: closing the riser by operating the riser cover, and cleaning the periphery of the charge of the charge vehicle by operating the dust collector of the charge vehicle; Opening a water valve by manipulating an ordinal valve manipulator provided in the charging vehicle, and sending a gas generated during charging by connecting a U-tube provided in the charging vehicle to a door of the coke oven; Operating a lead lifter provided in the charging vehicle to lift a lead; And charging coal in the coke oven by operating a screw feeder provided in the charging car.

In an embodiment of the present invention, after the sixth step, the dust collector, the water valve operation, the U-tube, the lead lifter, the screw peter further comprising the step of operating in the initial state of the coke Provide unmanned control method of charging vehicle of factory.

According to an aspect of the present invention, in the coke plant can be unmanned control of the position and operation of the charging vehicle until the charging vehicle is completed from the coal mining to reduce the working time to increase the efficiency of the work.

According to another aspect of the present invention, it is possible to control the charging vehicle by the unmanned control system in the coke factory, not the sixth sense or time of the operator, thereby reducing equipment accidents than when manually controlled.

According to another aspect of the present invention, the coke plant can be controlled by the unmanned control system rather than the operator's sense or time of view, so that the operation of the coke plant is less likely to be stopped, resulting in human injury and Physical damage is reduced.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention may be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. Shapes and sizes of the elements in the drawings may be exaggerated for more clear description, elements denoted by the same reference numerals in the drawings are the same element.

3A is a configuration diagram of a charging vehicle unmanned control system of a coke plant of the present invention, and FIG. 3B is a detailed configuration diagram of the vehicle PLC of FIG. 3A. As shown in Figures 3a and 3b, the unmanned vehicle control system of the coke plant is a position measurement header 100, position measurement sensor 210, motion detection sensor unit 201 to 207, vehicle PLC 300, The server 400 includes a PLC 400, a first display means 500, and a second display means 600.

The position measurement header 100 is installed at one side of the door of the coke oven, and is attached with an RFID tag 110 having position information of the door of the coke oven. The RFID tag 110 is composed of an IC chip, an antenna, and a binder to transmit and receive predetermined data in a non-contact manner with the reader 210a of the position sensor 210. Inductive coupling, electromagnetic backscattering coupling, surface acoustic waves, etc. may be used depending on the height of the frequency used, and data may be transmitted and received with the reader 210a in a full duplex, half duplex, or sequential manner using electromagnetic waves.

The position measuring sensor 210 is attached to the charging vehicle 200 for charging coal in the coke oven, and at a position spaced apart from the positioning header 100 by a specific distance, the reader 210a inside the RFID tag 110 Generates a current signal corresponding to the position information read from The first signal generator 210b and the second signal generator 210c of the position measurement sensor 210 generate current signals of 4 mA and 20 mA, respectively, at positions spaced apart from the position measurement header 100 by a specific distance.

The motion sensor unit 201 to 207 detects the operation of the equipment provided in the coke oven or the charging vehicle, and generates a current signal corresponding to the operation of the equipment. The first sensor 201 and the second sensor 202 , A third sensor 203, a fourth sensor 204, a fifth sensor 205, a sixth sensor 206, and a seventh sensor 207. Such equipment includes riser covers, bunker gates, dust collectors, water valve actuators, U-tubes, lid lifters, and screw feeders.

The first sensor 201 detects the operation of the riser cover for opening and closing the riser provided in the door of the coke oven to generate a current signal, and the second sensor 202 opens and closes the call hopper of the charging vehicle 200. Detects the operation of the bunker gate to generate a current signal. In addition, the third sensor 203 detects the operation of the dust collector for cleaning the surroundings of the charging port of the charging vehicle 200 to generate a current signal, and the fourth sensor 204 is the eye water valve provided in the charging vehicle 200. Detects the operation of the handed-operated valve manipulator to generate a current signal. In addition, the fifth sensor 205 is provided in the charging vehicle 200 to detect the operation of the U-tube connected to the door of the coke oven to generate a current signal, the sixth sensor 206 is provided in the charging vehicle The current signal is generated by detecting the operation of the lead lifter for lifting the lid. In addition, the seventh sensor 207 is provided in the charging vehicle 200 to detect the operation of the screw feeder for charging coal into the door of the coke oven to generate a current signal.

The vehicle PLC 300 receives a current signal generated from the position measuring sensor 210 so that the charging vehicle 200 may stop at one side of a door or a coal bin of a coke oven corresponding to a target position. Position control unit 310 for controlling the position of the), the position measuring sensor 210 or the current signal generated from the motion sensor unit (201 to 207) to receive the riser cover, bunker gate, dust collector, hand water valve manipulator, Operation control unit 320 for controlling the operation of the U-tube, lead lifter, screw feeder, respectively. The operation control unit 320 may receive a current signal generated from the motion detection sensor unit 201 to 207 to operate the dust collector, the hand valve control unit, the U-tube, the lead lifter, the screw feeder to an initial state.

Looking in detail with respect to the position control unit 310 composed of a position calculation unit 311 and the driving unit 312 as follows.

The position calculator 311 calculates the current position of the charged vehicle 200 by counting the number of pulse signals generated from an encoder attached to an idle wheel of the charged vehicle 200. The encoder detects the number of revolutions of the idle wheel, and the position calculator 311 can calculate the position by counting the number of pulses generated from the encoder and measuring the moved distance.

The driving unit 312 operates the motor provided in the charging vehicle 200 to drive the charging vehicle 200 to the calculated target position. The driving principle of driving the charging vehicle 200 in the driving unit 312 is to accelerate to a constant speed from a stationary position, and then decelerate stepwise to reach a target position.

The position information and operation status of the charged vehicle 200 stored in the vehicle PLC 300 may be confirmed through the first display means 500.

The server PLC 400 receives and stores location information and operation status from the vehicle PLC 300 provided for each charging vehicle 200, thereby storing the charging vehicle stored in the server PLC 400 through the second display means 600. The location information and operation status of the 200 can be confirmed.

RS-485 communication is used as the communication method used in the position measuring sensor 210, the vehicle PLC 300, the server PLC 400, the first display means 500, the second display means 600.

Figure 4a is a graph of the current signal generated by the position measurement sensor of the present invention, Figure 4b is a graph comparing the current signal generated by the position measurement sensor according to the distance from the position measurement header.

As shown in FIGS. 4A and 4B, the reader 210a of the position measurement sensor 210 generates a current signal corresponding to the position information read from the RFID tag 110 of the position measurement header 100. 4A illustrates an example in which the position measuring sensor 210 is positioned at a distance of 90 mm from the position measuring header 100, and in FIG. 4B, the position measuring sensor 210 is 120 mm from the position measuring header 100, respectively. An example is shown in the case of being spaced apart by 90 mm, 60 mm.

In FIG. 4A, the first signal generator 210b and the second signal generator 210c of the position measurement sensor 210 respectively output current signals of 4 mA and 20 mA at positions spaced apart from the position measurement header 100 by a specific distance. Generate.

In FIG. 4B, when the distance between the position measurement sensor 210 and the position measurement header 100 is 120 mm, 90 mm, and 60 mm, respectively, the first signal generator 210b and the second signal generation of the position sensor 210 are generated. It can be seen that when the magnitude of the current signal generated by the unit 210c is different and the distance is 60 mm apart, the magnitude of the current signal is saturated so that a current signal of more than 20 mA or less than 4 mA cannot be generated.

5 is a graph showing the speed of the charging vehicle according to the moving distance until the charging vehicle reaches the target position when the charging vehicle of the present invention travels to the target position. As shown in Fig. 5, when the charging vehicle starts and moves at any stationary position, it runs at a different speed depending on the distance traveled. That is, the principle of driving the charging vehicle takes a method of accelerating to a constant speed from a stationary position and then decelerating stepwise to reach the target position. Details are as follows.

Sections 0 to a are sections in which the charging vehicle accelerates to a speed of v ₃ at an arbitrary position where the vehicle is stopped, and sections a to b are sections that travel at a speed of v ₃ .

Sections b to c are sections that decelerate from the speed of v _{3 to} the speed of v ₂ , and sections c to d are sections that travel at the speed of v ₂ .

The d ~ e section is a section that decelerates from the speed of v _{2 to} the speed of v ₁ , and the e ~ f is a section running at the speed of v ₁ .

f ~ g section is the section to decelerate at the speed of v ₁ and stop at the target position.

6 is a flowchart of a charging vehicle unmanned control method of the coke plant of the present invention. Referring to Figure 6 along with Figures 3a and 3b, the charging vehicle unmanned control method of the coke plant includes the steps S100 ~ S1000.

First, the position control unit 310 drives the charging vehicle 200 to the door of the coke oven corresponding to the target position (S100), and the operation control unit 320 operates by raising the riser cover provided at the door of the coke oven. Open the tube (S200). The reason why the operation control unit 320 opens the riser is to discharge the gas before charging the coal into the coke oven.

Thereafter, the position controller 310 drives the charging vehicle 200 to a colvin storing coal (S300), and the operation controller 320 operates the bunker gate provided in the charging vehicle 200 to charge the charging vehicle ( Open the call hopper of 200) to load the coal stored in the colvin to the charging vehicle 200 (S400).

Thereafter, the operation control unit 320 operates the bunker gate to an initial state to close the call hopper (S500), and the position control unit 310 drives the charging vehicle 200 to the standby position (S600). The reason why the operation controller 320 operates the bunker gate in an initial state is to drive the charging vehicle 200 to the standby position.

Thereafter, the position controller 310 drives the charging vehicle 200 to the door of the coke oven corresponding to the target position (S700), and the operation controller 320 operates the riser cover to an initial state to close the riser. (S800). The reason why the operation controller 320 operates the riser cover to the initial state is because the riser tube is opened and gas discharge is completed.

Thereafter, the operation control unit 320 charges coal into the coke oven (S900), and operates the dust collector, the water valve operator, the U-tube, the lead lifter, and the screw peter in an initial state (S1000). The reason why the operation control unit 320 operates the dust collector, the water hand valve operation unit, the U-tube, the lead lifter, and the screw peter in the initial state is to complete all the operations of the charging vehicle 200 and to drive to the standby position.

7 is a flowchart illustrating a method of driving the charging vehicle of FIG. 6 to a door of a coke oven corresponding to a target position. Referring to FIG. 7 together with FIGS. 3A and 3B, a method (S100) of driving the charging vehicle 200 to a door of a coke oven corresponding to a target position is as follows.

First, the charging vehicle 200 for charging coal in the coke oven approaches the position measurement header 100 which is installed on each side of the door of the coke oven (S110).

Subsequently, at a position separated from the positioning header 100 to which the RFID tag 110 having the position information of the door of the coke oven is attached, the position measuring sensor 210 attached to the charging vehicle 200 is A current signal corresponding to the positional information read from the RFID tag 110 is generated (S120).

Thereafter, the position control unit 310 controls the position of the charging vehicle 200 so that the charging vehicle 200 can be stopped at one side of the door of the coke oven corresponding to the target position (S130).

Steps S100 and S800 of FIG. 6 are the same, and steps S110 to S130 are also applied to step S800.

8 is a flow chart of a method of charging coal into the coke oven of FIG. 6. Referring to FIG. 8 together with FIGS. 3A and 3B, a method of charging coal in a coke oven is as follows.

First, the operation control unit 320 operates the riser cover to close the riser (S910), and operates the dust collector of the charging vehicle 200 to clean the vicinity of the charging opening of the charging vehicle 200 (S920).

Thereafter, the operation control unit 320 operates the ordinal valve manipulator provided in the charging vehicle 200 to open the eye valve (S930), and connects the U-tube provided in the charging vehicle 200 to the door of the coke oven. To send the gas generated during charging (S940).

Thereafter, the operation control unit 320 operates the lead lifter provided in the charging vehicle 200 to lift the lead (S950).

Thereafter, the operation control unit 320 operates the screw feeder provided in the charging vehicle 200 to charge coal into the coke oven (S960).

The present invention is not limited by the above-described embodiment and the accompanying drawings. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims, .

1 is a perspective view showing a conventional coke oven.

2 is a longitudinal sectional view showing a conventional coke oven.

3A is a configuration diagram of a charging vehicle unmanned control system of a coke plant of the present invention.

3B is a detailed configuration diagram of the vehicle PLC of FIG. 3A.

Figure 4a is a graph of the current signal generated by the position measuring sensor of the present invention.

Figure 4b is a graph comparing the current signal generated by the position sensor according to the distance from the position measurement header.

5 is a graph showing the speed of the charging vehicle according to the moving distance until the charging vehicle reaches the target position when the charging vehicle of the present invention travels to the target position.

6 is a flowchart of a charging vehicle unmanned control method of the coke plant of the present invention.

7 is a flowchart illustrating a method of driving the charging vehicle of FIG. 6 to a door of a coke oven corresponding to a target position.

8 is a flow chart of a method of charging coal into the coke oven of FIG. 6.

                 <Description of the symbols for the main parts of the drawings>

100: position measurement header 110: RFID tag

200: charging vehicle 201: first sensor 202: second sensor 203: third sensor 204: fourth sensor 205: fifth sensor 206: sixth sensor 207: seventh sensor 210: position measuring sensor 210a: reader

210b: first signal generator 210c: second signal generator

300: vehicle PLC 310: position control unit

311: position calculation unit 312: driving unit

320: operation control unit 400: PLC for the server

500: first display means 600: second display means

Claims (10)

Position measuring headers respectively installed at one side of a door of a coke oven and having an RFID tag having position information of the door of the coke oven; A position measuring sensor attached to a charging vehicle for charging coal in the coke oven and generating a current signal corresponding to the position information read from the RFID tag at a position spaced apart from the position measuring header by a specific distance; A motion detection sensor unit for detecting a motion of a facility provided in a door or a charging vehicle of the coke oven and generating a current signal corresponding to the operation of the facility; A position control unit which receives the current signal generated by the position measuring sensor and controls the position of the charging vehicle so that the charging vehicle can be stopped at one side of the door or the colvin side of the coke oven corresponding to a target position; And An operation control unit which receives a current signal generated from the position measuring sensor or the motion detection sensor unit and controls the operation of the facility; Charging vehicle unmanned control system of the coke plant, comprising a. The method of claim 1, Said equipment is any one of a rising pipe cover, a bunker gate, a dust collector, a water valve operator, a U-tube, a lead lifter, and a screw feeder. The method of claim 1, The position control unit, A position calculator for counting the number of pulse signals generated from an encoder attached to an idle wheel of the charged vehicle to calculate a current position of the charged vehicle; And A driving unit operating the motor provided in the charging vehicle to drive the charging vehicle to the calculated target position; Charging vehicle unmanned control system of the coke plant, comprising a. The method of claim 1, And the operation control unit receives a current signal generated from the operation detection sensor unit and operates the facility in an initial state. delete delete delete delete delete delete

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