DE1765514B1 - CONTROL DEVICE FOR OPERATING A MULTI-PHASE ELECTRIC OVEN - Google Patents

Description

1 2

The invention relates to a control device for the basic, a control device for operating a Operation of a multi-phase electric furnace, in particular to create a multi-phase electric furnace, which the vorereines Three-phase reduction furnace, which does not adhere to the disadvantages mentioned, but rather more permanent Power consumption the furnace amperage in which is formed that on the permanent electrode stroke electrodes is kept the same among each other. 5 and lowering movements can be dispensed with.

The power consumption of multi-phase electric The oven characterized in the claim is according to the equation JV = f {U ² , R) a finding is now based on two drawings he function of the voltage applied to the oven and clarifies. It shows

Resistance of the reaction material in the oven. F i g. 1 the circuit of a three-phase electric furnace

Likewise, the power consumption of such ovens according to io and

the equation Z = / ([/, R) is a function of the control device according to the invention as shown in FIG

Furnace applied voltage and resistance of the block diagram.

In FIG via which sizes can be freely selected with the load switches 4, 5 and 6, whereby the two other transformers 7, 8 and 9 are clearly determined with voltage from the ren. Three-phase network R, S and Γ supplied.

For reasons of expediency, power and mators 7, 8 and 9 need not be more than one Electricity chosen as an independent variable. A three-phase bank is interconnected single-phase it makes technical sense to act as a control variable for only one transformer, rather it is entirely Assign the reference variable, so either the span or a three-phase transformer voltage of the power and switch the resistance to the current so that each of its phases is between two electrical or the voltage to the current and the resistance of the lies.

Power. The respective variable is to be used as a disturbance variable. With the help of the control device in FIG. 2 will be auto dealing. 25 automatically when asymmetries occur in the Möller

If the current strength is kept constant, the resistance changes the furnace current strength in the electrodes.

Furnace voltage as a disturbance variable only in the context of the fact that the voltage is kept the same among each other

Furnace schedule. On the other hand, the one between the electrodes is changed. The as well as

Resistance of the reaction material in the oven Control elements A, B, C, D and E are used

from arbitrary external interventions, such as for example 30 known as such; the invention relates to them

Feeding, tapping, moving electrodes and the like, not, but rather the interconnection of the controller

as well as unpredictable internal processes, in their entirety.

such as material and gas movements, so- If the actual value of the power groove deviates

how temperature and state changes of the reac- from the desired setpoint of the power N _so u change

tion good disturbed. 35 the controller A changes the setpoints of the electrode currents

In a known control device for operation Isoii in controller B. The changed setpoints of the electrode currents I _so ii mentioned in the introduction of multi-phase electric furnaces are both in the two-way point controlled according to the equation C ₁ with the actual value of the

J ₁ trode 1 flowing electrode current ZiSi ₁ as well as in

R = - ■ ρ 4o the two-position controller C ₂ with the actual value of the

1 electrode 2 flowing through electrode current Iut ₂

worked with an impedance control, namely the and in the two-position controller C ₃ with the actual value

type that changes in the specific Möllerwider- the current flowing through the electrode 3 / is ₈

Status by reversely acting changes in the compared.

The electrode distance h from the furnace floor is compensated 45 On the basis of the comparison made, the currents become. In this way, the ohmic value is generated in each of the three controllers C ₁ , C ₂ and C _3, a resistance of the reaction material in the oven control command. The hold in the two- _{position controller C 1} essentially constant, which with a convincing control command acts on the load switch drive 4 inevitably a constant voltage and on the load switch drive 6. This is therefore the result of the current intensity. Changes to the ohmic 50 required because it has not yet been determined whether the voltage resistance of the reaction material in the oven U ₁ or the voltage U _{z is} to be changed, i.e. whether the load switch drive 4 or the load switch drive 6 are equaled by changes in the current path . To do this, it is necessary to use the electrodes that you are about to kick in the action. This is because only the electrical conditions prevailing in the furnace should be changed, the currents linked to it should be constantly raised or lowered accordingly. To 55 differ the least from each other. _{The two-point controllers C 2} and C _{3 are} missing for the Stellbe implementation of such lifting and lowering movements. The electrodes are elaborate hoists required- control command of the two-position controller C ₂ thus acts on the borrowed. Furthermore, it is necessary for the secure sealing of the load switch drive 4 and the load switch drive 5. Furnace against the electrodes, entangled in the same way, the setting command of the two-point built electrode holder, which the electrode controller C ₃ on the load switch drive 5 and on the movements, and stuffing boxes to load switch drive 6.

use. Such electrode holders do not give. In the controller D ₁ , the actual value of the

seldom cause serious operational disruptions. An electrode 1 flowing current Zi-Si ₁ with the actual value

Another disadvantage of the known procedure is the current Iut ₂ , in flowing through the electrode 2

in that flexible leads to the electrodes for 65 the controller Z) ₂ the actual value of the through the electrode 2

Current, coolant and measuring lines required flowing current IiSt ₂ . with the actual value of the

are. Electrodes 3 flowing current Ii _S t _s and in the Reg-

In contrast, the object of the invention is to Z) ₃ the actual value of the value flowing through the electrode 3

5 is greater than the absolute amount of the difference

in the controller .E ₁ then compared which of the two amounts is the largest. In the event that the absolute amount of the difference

IiSt ₁ - listi

is less than the absolute amount of the difference

IiSt ₃ - IiSt ₁ ,

the release command for the load switch drive 4 occurs. For the other case that the absolute amount of the difference

IiSt ₃ - IiSt ₁

is less than the absolute amount of the difference

IiSt ₁ - listi,

the release command for the load switch drive 6 occurs.

The same applies to the other controllers. The difference found in the controller D ₁

IiSt ₁ -

Current ItSt _{3 with the actual value of the current Z 8} -Si ₁ flowing through the electric while in the other case that the absolute amount is compared. The absolute difference is the difference determined in controller D ₁

IiSt ₁ Jisti

is with the absolute amount of the controller D ₃

detected difference the release command for the load switch drive 5 takes place.

The control device according to the invention is characterized in that, if the actual value (groove) deviates from the nominal value (N _so ii) of the furnace output, a regulator (A) controls the nominal values of the electrode currents (I _so u) in a regulator ( B) changed; that one compares the changed setpoint values (I _so u) of the electrode currents in further controllers (C ₁ , C ₂ , C ₃ ) with the actual values of the electrode currents (ItSt ₁ , Iistz, IiSt ₃ ); that if the changed setpoint values (I _so u) deviate from the actual values of the electrode currents (ItSt ₁ , IiSt ₂ , IiSt ₃ ) , setting commands to the step switch drives (4, 5, 6) of the respective electrode (1, 2, 3 ) there are adjacent furnace transformers (7, 8, 9); that in further controllers (D ₁ , D ₂ , D ₃ ) the differences between the actual values of the electrode currents flowing through the respective electrode and its adjacent electrodes on both sides are formed in a manner known per se, and that via further controllers (E ₁ , E ₂ , E ₃ ) only that tap changer drive is released whose associated furnace transformer is located between the electrodes having the smaller current difference.

In this way one arrives at a control device for operating a multiphase electric furnace, the the aforementioned task of the invention is fully met. In particular, the previously necessary, expensive one is no longer necessary mechanical device to move the heavy electrodes up and down quickly and accurately. The electricity and water supply lines to the electrodes can be made rigid, reducing the reactance of the furnace. In addition, the reaction in the oven takes place more calmly when that is happening Continuous raising and lowering of the electrodes caused by the restlessness of the reaction process in the furnace does not take place and the electrodes are only continuously relocated according to their consumption.

Claims (1)

Claim: Control device for the automatic operation of a multiphase electric furnace, in particular a three-phase reduction furnace, in which the furnace amperage in the electrodes is kept the same with constant power consumption, characterized in that if the actual value (groove) deviates from the nominal value (Nsoii) of the furnace output the setpoint values of the electrode currents (Isou) are changed in a controller (B) by a controller (A) ; that the changed setpoint values (Isou) of the electrode currents are compared in further controllers (C ₁ , C ₂ , C ₃ ) with the actual values of the electrode currents (ZiSi ₁ , IiSt ₂ , IiSt ₃ ) ; that if the changed setpoints (I _so ii) deviate from the actual values of the electrode currents (ItSt ₁ , Iut ₂ , IiSt ₃ ) , setting commands to the tap changer drives (4, 5, 6) of the respective electrode (1, 2, 3 ) there are adjacent furnace transformers (7, 8, 9); that in further controllers (D ₁ , D ₂ , D ₃ ) in a manner known per se the differences between the actual values of the respective electrode and its adjacent electrodes on both sides flow is in the controller E ₂ with the difference determined in the controller D ₂ IiSt ₂ - IiSt ₃ controlled for their absolute amount. In the event that the absolute amount of the difference Hst% Hst ₃ is greater than the absolute amount of the difference IiSt ₁ - · 40 the release command is issued for the load switch drive 4. For the other case that the absolute value of the difference 50 IiSt ₁ - is greater than the absolute amount of the difference IiSt ₂ - IiSt ₃ ■> the release command for the load switch drive 5 occurs. The same happens in the controller E ₃ . The difference found in the controller D ₃ IiSt ₃ - IiSt ₁ is in the controller E ₃ with the difference determined in the controller D ₂ listi - IiSt ₃ , DO compared. Here, too, it applies that, in the event that the absolute amount of the difference listi - IiSt ₃ is greater than the absolute amount of the difference the release command for the load switch drive 6 is issued, Electrode currents are formed and that via further controllers (E ₁ , E ₂ , E _z ) only that tap changer drive is released whose associated furnace transformer is located between the electrodes having the smaller current difference. 1 sheet of drawings