SU869080A1 - Electrohydraulic drive for displacement of electric arc furnace electrode - Google Patents

Description

The invention relates to electrothermics, and relates, in particular, to glass-melting and ore furnace metal furnaces.

In existing constructions of electric arc furnaces, the movement of the electrodes ® is carried out using a hydraulic drive consisting of a plunger hydraulic cylinder, a reversible pump and a feed tank of £ 11

.. 10

The disadvantages of this drive are low reliability and durability due to the continuous operation of reversible pumps, as well as low efficiency.

A hydraulic drive for mixing electrodes of arc steel furnaces with a capacity of 6, 12, 25 and 50 tons is known. [2J The control of plunger-type hydraulic cylinders for moving the electrodes is carried out using hydraulic booster. The energy for moving the electrodes is supplied from the pump-storage station (NAS), which consists of a feed tank, a gas-hydraulic accumulator with inductive liquid level sensors, power pumps, control pumps and shut-off control hydraulic equipment.

Power pumps (on and off) are controlled by induction sensors depending on the level of the working fluid in the hydraulic cylinder of the battery.

When lowering the liquid to the lower working level, the power pumps turn on, and when rising to the upper working level they turn off.

The closest in technical essence to the proposed is an electro-hydraulic actuator, displacement z electrode electric arc furnace, containing _e gazogidravlicheskogo conductive battery with the sensors of the upper and intermediate level of working fluid which exits through a control unit electrically svlzany with primary and backup engines groups pumps, all output lines pumps connected to each other (foot and

869060 with the specified output, the battery, and through the hydraulic booster - with the hydraulic cylinder for moving the electrode, and the pump inlet pipelines - with the supply tank Гз]

When lowering the liquid in the battery to the sensor of the intermediate working level, the pumps of the first (main) group are turned on, and when the battery is empty to the sensor of the lower working level, the pumps of the second (backup) group are turned on in parallel. All pumps turn off when the battery is full up to the upper working level sensor.

The sensors of the upper and lower levels are emergency, they give a signal to disconnect the battery from the power line, duplicate signals to turn off or turn on the power pumps and give a command to turn on the alarm.

The disadvantage of the considered Hydraulic drive scheme is the large installed capacity of the pumps, since the pumps of the reserve group are turned on when the battery is empty, and at this time the consumer's need for the required performance is ensured only due to the operation of the pumps.

Unprotected - reduction of the power of the pumps in the hydraulic drive of the electric arc furnace by connecting a backup group of pumps before emptying the gas-hydraulic accumulator.

To achieve this goal, the drive is equipped with a time relay, the input of which is electrically connected to the output of the intermediate level sensor, and the output through the control unit - with the pumps of the reserve group.

The drawing shows a diagram of a hydraulic drive of an electric arc furnace.

The circuit contains a gas-hydraulic accumulator 1 connected to the pressure pipe 2 with pumps 3, one of which is the main one, and two are reserve, and through the hydraulic booster 4 with the plunger hydraulic cylinder 5 of the electrode movement. 7 working levels. The operation of the pumps is controlled by the control unit 8 according to the signals from the level sensors and turnip 9 time connections 10 and 11, respectively. The feed unit 12 is connected to the pumps and the hydraulic booster by pipelines 13 and 14.

The device operates as follows.

When the battery 1 is full, the working fluid is in it at the level 5 of the sensor 6, the pumps 3 do not work. When the hydraulic booster 4, depending on the signals from a regulator (not shown), connects the hydraulic cylinder 5 to the pressure line 2, the liquid from the accumulator 10 enters the cylinder, the liquid level in the accumulator will begin to decrease. After the liquid drops below the level of the sensor 7, the control unit 8, upon a signal from the level sensor 7, by communication 10 15 turns on the pump 3 of the main group. When the pump capacity is greater than the consumed liquid in the battery rises to the level sensor 6 and the control unit 8, upon a signal from this sensor 20, turns off the pump 3.

If, after turning on the pump 3 of the main group, the liquid level in the accumulator 1 after a certain period of time, for which the relay 9, 25 is configured, does not rise to the level sensor 7, then the control unit 8, by the signal of the time relay 9 through communication 11, turns on the pumps 3 of the reserve group. All pumps must work for the consumer in parallel with the ACCUMULATOR. When the battery is full up to level 6 sensor, all pumps are turned off.

The proposed hydraulic drive of electric arc furnaces has such an advantage that the introduction of a time relay instead of a permanently installed lower working level sensor in the battery for switching on the pumps of the reserve group allows you to adjust the time ^{40 for} switching on the pumps of this group, i.e.

promptly change the performance of the NAS depending on the required flow rate of the working fluid for these types of electric furnaces or technological operations of ⁴⁵ operations, which makes it possible to operate the pumps in optimal conditions together with the battery and, therefore, reduce their installed capacity.

Claims (3)

1. Kramarov A.D. and F. M „Metalf g, 1976, s, 40. -. " 2. Sapko A, I. Executive mv anism of regulating power of electric arc furnaces. M., Energie, 1969, p. 47, 3. Hydraulic circuit. Drawing J1F 220.017GZ and technical description of ONF 140.039 electric furnace SKB-61O2,