JPH0257889A - Electrode elevation control method for dc arc furnace - Google Patents

Abstract

PURPOSE:To prevent interruption of the generation of an arc and to enable excellent control of elevation of an electrode by a method wherein during boring, the melting speed of a substance to be melted is added as a correction amount to a command value of the moving speed of a moving electrode. CONSTITUTION:A voltage Vr applied on a moving electrode 4 to dissolve scraps 2 in a DC arc furnace 1 is detected by a voltage detector 10, and according to a voltage deviation (Vd - Vr) between the detecting voltage Vr and a set voltage Vd set by a voltage setter 11, control of the moving speed and elevation of the moving electrode 4 are effected. During boring being one of the operation patterns of the DC arc furnace 1, the melting speed of the scraps 2 is added as a correction amount to a command value of the moving speed of the moving electrode 4. Further, a scrap dissolving speed set value from a scrap melting speed setter 21 is provided to a subtractor 23 to control elevation of the moving electrode 4.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a method for controlling the elevation of a DC arc furnace electrode, which controls the position of a movable electrode (also referred to as an arc electrode) in a DC arc furnace. The present invention relates to a method for controlling the electrode elevation of a DC arc furnace, which takes into account the melting speed and controls the electrode position without arc breakage even during the boring period.

(Prior art) Generally, in a DC arc furnace for steelmaking, for example, an arc is generated from a movable electrode, and materials to be melted such as scrap (hereinafter referred to as scrap), which are melting raw materials, are melted at the bottom of the furnace. However, when the scrap is melted, the shape of the scrap changes from moment to moment, and the arc voltage changes accordingly, so the desired arc voltage can be obtained reliably. That is, in order to connect the arc reliably, it is necessary to control the movable electrode in a complicated manner.

For this reason, conventionally, as shown in FIG. 2, after filling the inside of a DC arc furnace 1 with scrap 2 and closing a furnace lid 3 on the top of the furnace, a movable electrode such as a carbon electrode is inserted from the top of the furnace lid 3. Insert the furnace transformer 5, thyristor converter 6. A desired arc current is always passed between the movable electrode 4 and the bottom electrode 8 via the smoothing reactor 7, and the movable electrode 4 is moved while controlling its position so that a predetermined voltage is applied to the arc. An arc is generated from the tip of the electrode 4 to sequentially melt the scrap 2. (The operating stage in which the movable electrode 4 is lowered while melting the scrap 2 to create a hole is called the boring stage.) In other words, when this arc occurs, the movable electrode 4 and the bottom electrode 8 The voltage detector 10 detects the voltage Vr between the two, and the adjustment unit 12 performs a proportional-integral calculation so that the voltage deviation between the detected voltage Vr and the set voltage Vd predetermined by the voltage setter 11 becomes zero. , and gives the obtained operation output (control signal) to the electric motor 13 for lifting and lowering the electrode. The electric motor 13 for lifting and lowering the electrode rotates forward or backward based on the operation output, and the winch 14 rotates the wire 15 with one end as a fixed end.
By winding or unwinding the other end, this wire 1
The mast 16 is controlled to rise and fall via 5. At this time, the holder arm 17 horizontally fixed to the upper part of the mast 16 moves up and down together, so that the movable electrode 4 is raised and lowered via this holder arm 17, and a predetermined position is placed between the movable electrode 4 and the hearth bottom electrode 8. voltage is applied, and a desired arc is generated from the tip of the movable electrode 4.

Therefore, in this type of electrode elevation control method, when the set voltage is smaller than the detected voltage (Vd-Vr<0), the movable electrode 4 is lowered, and the set voltage is larger than the detected voltage (Vd-Vr<0).
d-Vr>0), control is performed to raise the movable electrode 4. In controlling the arc current, the arc current is detected from the DC output side of the Cyrisk converter 6 or the output side of the hearth bottom electrode 8, and this detected current! A gate control angle α is determined by an automatic current regulator so that the current deviation between the current value and the set current 1d becomes zero, and the gate of the SIRISK converter 6 is controlled according to this gate control angle α.

(Problem to be Solved by the Invention) By the way, in the electrode elevation control method as described above, basically the voltage between the movable electrode 4 and the furnace bottom electrode 8, that is, the arc voltage, and the arc length are proportional to each other. It is assumed that the arc voltage and the electrode position are also in a proportional relationship, and the arc voltage is controlled by controlling the movable electrode 4 to move up and down. That is, when the movable electrode 4 is raised, the arc voltage increases proportionally, and when the movable electrode is lowered, the arc voltage decreases proportionally. However, especially during the boring period, since the arc voltage and the vertical position of the movable electrode are not necessarily in a proportional relationship, good control cannot be performed and there is a problem that arc breakage occurs. That is, this is due to the fact that during the boring period, the position of the scrap, which is the opposite electrode of the movable electrode, changes as it melts. Therefore, since it is not possible to accurately grasp the arc length based only on the position of the movable electrode, it is necessary to accurately grasp the relationship between the arc voltage and the position of the movable electrode to perform control.

The present invention was made in order to solve the above-mentioned problems, and its purpose is to solve the problem by taking into consideration the dissolution rate of the material to be melted, so that even during the boring period, no breakage occurs and the present invention is extremely satisfactory. An object of the present invention is to provide a method for controlling the elevation of electrodes in a DC arc furnace, which allows for precise control.

(Means and operations for solving the problem) In order to achieve the above object, the present invention detects the voltage applied to the movable electrode that melts the material to be melted in the DC arc furnace, and In a DC arc furnace electrode lifting/lowering control method that controls the moving speed and lifting/lowering of a movable electrode according to the voltage deviation from a predetermined set voltage, the movable electrode is By adding the dissolution rate of the material to be melted as a correction amount to the command value of the moving speed of It is possible to perform good electrode elevation control without arc breakage.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a diagram showing an example of the overall configuration of an electrode elevation control system for a DC arc furnace to which the method of the present invention is applied, and the same parts as in FIG. Only the different parts will be described here.

As shown in FIG. 1, this system includes a voltage detector 10,
Voltage setting device 11, subtractor 18, and speed setting controller 19
, a rise/fall switching circuit 20, a scrap melting speed setting device 21, a switch 22, an adder 23, a speed detector 24, and a speed controller 25.

Here, the voltage detector 10 detects the voltage V' between the movable electrode 4 and the furnace bottom electrode 8, and the voltage setter 11 sets the set voltage Vd in advance. Reference numeral 18 indicates a voltage deviation (Vd
-Vr). Further, the speed setting controller 19 inputs the voltage deviation from the subtracter 18, performs a proportional integral calculation so that the voltage deviation becomes zero, and outputs a speed setting value (absolute value).

On the other hand, the rise/fall switching circuit 20 inputs the voltage deviation from the subtracter 18 and the speed setting value from the speed setting controller 19, and changes the speed setting value to positive or negative depending on the polarity of the voltage deviation. It adds polarity and outputs it as a moving speed command value in the upward or downward direction. In other words, when the voltage deviation is positive, the moving speed command value in the upward direction (+Uo
), and when the voltage deviation is negative, a downward moving speed command value (Uo) is output. Further, the scrap melting speed setting device 21 has a scrap melting speed setting value Us
This outputs the following. Furthermore, the switch 22 is manually closed by an operator only when the DC arc furnace 1 is in the boring period. Furthermore, subtractor 2
3 is a moving speed command value (+Uo) or (-Uo) in the upward or downward direction from the upward/downward switching circuit 20 and a scrap melting speed set value Us from the scrap melting speed setting device 21 which is the correction amount thereof. This is to subtract and output. On the other hand, the speed detector 24 is connected to the electrode lifting motor 13.
The rotational speed of the movable electrode 4, that is, the vertical movement speed of the movable electrode 4 is detected. In addition, the speed controller 25 inputs the corrected moving speed command value from the subtractor 23 and the detected speed from the speed detector 24, performs proportional integral calculation so that the deviation between the two becomes zero, and outputs the operation output. (control signal) is given to the electric motor 13 for lifting and lowering the electrode.

Next, a method for controlling the electrode elevation of the DC arc furnace in this embodiment will be explained.

Now, by igniting the thyristor converter 6, a DC voltage is applied between the movable electrode 4 and the furnace bottom electrode 8 of the DC arc furnace 1, and the movable electrode 4 and the scrap 2 are ignited by contact, and the movable electrode 4 An arc is generated from the tip of the DC arc furnace 1, and the operation of the DC arc furnace 1 is started, and the process moves to the boring stage, which is the first stage. At this point, the operator manually closes the switch 22.

On the other hand, a voltage V' between the movable electrode 4 and the bottom electrode 8 is detected by the voltage detector 10, and this detected voltage Vr is
The voltage deviation (Vd-Vr) from the set voltage Vd is obtained. Next, the speed setting controller 19 performs a proportional integral calculation so that this voltage deviation becomes zero, and the speed setting value is changed to the increase/decrease switching circuit 20 and the scrap melting speed setting device 2.
1, respectively. Then, in the ascending/descending switching circuit 20, a moving speed command value in the ascending or descending direction is obtained depending on the positive or negative polarity of the voltage deviation from the subtracter 18. That is, when the voltage deviation is positive, a moving speed command value in the upward direction (+Uo) is obtained, and when the voltage deviation is negative, a moving speed command value in the downward direction (-Uo) is obtained, which is output to the subtracter 23. be done. Further, the scrap melting speed set value Us is output from the scrap melting speed setting device 21, and this is outputted to the subtractor 23 through the switch 22. Then, the subtracter 23 receives the moving speed command value (+Uo) or (-Uo) from the ascending/descending switching circuit 20.
), the scrap melting speed setting value Us from the scrap melting speed setting device 21 is subtracted as the correction amount. In other words, when moving in the upward direction, the corrected moving speed command value is Uo-Us, and when moving downward, the corrected moving speed command value is -(U,)+U.
A corrected movement speed command value of s) is obtained. Furthermore, the speed controller 25 calculates the deviation between the movement speed command value from the subtractor 23 and the detected speed from the speed detector 24, performs proportional integral calculation so that this deviation becomes zero, and calculates the operation output ( control signal) is given to the electrode lifting/lowering motor 13. Then, in accordance with the movement speed command value from the speed controller 25, the electrode elevating motor 13 rotates forward or reverse at the commanded speed, whereby the movable electrode 4 is controlled to rise or fall. Note that when the transition to the stage after the boring stage (stable stage) occurs, by opening the switch 22 at that point, the voltage difference between the voltage Vr between the movable electrode 4 and the hearth bottom electrode 8 and the set voltage Vd is determined. Normal electrode elevation control will be performed.

As described above, in this embodiment, the voltage V applied to the movable electrode 4 for melting the scrap 2 in the DC arc furnace 1 is detected by the voltage detector 10, and this detected voltage Vr is set by the voltage setting device 11. When controlling the moving speed and raising/lowering of the movable electrode 4 according to the voltage deviation from the set voltage Vd, a command for the moving speed of the movable electrode 4 is given during the boring period, which is one of the operating patterns of the DC arc furnace 1. The dissolution rate of scrap 2 is added to the value as a correction amount.

Therefore, during the boring period of the DC arc furnace 1, the arc voltage Vr and the movable electrode 4 are
By being able to perform control with a good understanding of the relationship between the position of

In the above embodiment, a case has been described in which the operator manually opens and closes the switch 22 to provide the scrap dissolution rate set value Us from the scrap dissolution rate setting device 21 to the subtractor 23. For example, the boring period may be determined according to the position of the movable electrode 4 or the amount of electric power input to the DC arc furnace 1, and the opening/closing operation of the switch 22 may be automatically performed.

Further, the lifting device is not limited to an electric type, but may be a hydraulic type.

(Effects of the Invention) As explained above, according to the present invention, during the boring period, which is one of the operating patterns of a DC arc furnace, the melting rate of the material to be melted is adjusted with respect to the command value of the moving speed of the movable electrode. Since it is added as a correction amount, it is possible to provide a method for controlling the electrode elevation of a DC arc furnace, which can perform extremely good control without causing arc breakage even during the boring period.

[Brief explanation of the drawing]

FIG. 1 is an overall configuration diagram showing an embodiment of an electrode elevation control system for a DC arc furnace to which the present invention is applied, and FIG. 2 is a configuration diagram showing a conventional electrode elevation control system for a DC arc furnace. 1... DC arc furnace, 2... Scrap, 4...
Movable electrode, 5... Furnace transformer, 6... Thyristor converter, 7... Smoothing reactor, 8... Hearth bottom electrode, 1
0... Voltage detector, 11... Voltage setting device, 18...
- Subtractor, 19... Speed setting controller, 20... Up/down switching circuit, 21... Scrap melting speed setting device, 22... Switch, 23... Subtractor, 24...
Speed detector, 25...speed controller. Applicant's agent Patent attorney Takehiko Suzue

Claims (1)

[Claims] A voltage applied to a movable electrode that melts a material to be melted in a DC arc furnace is detected, and the voltage applied to the movable electrode is determined according to the voltage deviation between the detected voltage and a predetermined set voltage. In a method for controlling electrode elevation of a DC arc furnace that controls movement speed and elevation, during a boring period, which is one of the operation patterns of the DC arc furnace, the movement speed of the movable electrode is adjusted to a command value of the object to be melted. A method for controlling electrode elevation in a DC arc furnace, characterized in that a melting rate of is added as a correction amount.