SU1391821A1 - Device for starting and supplying a d.c. plasma-arc unit - Google Patents

Abstract

The invention relates to the cutting of metals and can be used in the design of power sources for plasma-arc installations. The goal is to increase the reliability of work. The device contains a power source of current (sieves), a power source of the pilot arc (ITSC) and an oscillator for exciting the arc. Power switches are included in the power supply circuits of SIT, oscillator, and SPID, and current sensors are included in the output circuit of SITS and SIT. The device contains multiplexers, the output buses of which are connected to the control electrodes of the power switches, and galvanic isolation devices connected between the current sensors and the input buses of the multiplexers. The information about the operating and non-operating states of the NFID and SIT comes from current sensors to multiplexers, which, according to a predetermined algorithm, generate control signals for power switches. The latter are connected to the mains for the minimum time required for operation of the SIT, an oscillator, and an IPDC. 1 il. with W

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The invention relates to the cutting of metals and can be used in the design of power sources for plasma-arc installations.

The aim of the invention is to increase the reliability of the device and increase the durability of the plasma torch elements.

The drawing shows the scheme of the proposed device for launching and powering a plasma-arc installation.

The device contains a power source 1 of current, made in the form of an adjustable static converter, the output of which is connected to the interelectrode gap 2. The installation also contains a power source 3 of the pilot arc, whose voltage is connected to the cathode 4 and nozzle 5 of the plasma torch, and OC1 CLIER 6, made in a high-frequency generator with a high-voltage output transformer 7, the secondary winding of which is connected in series to the cathode 4 - nozzle 5. Parallel to the output terminals of the power source of the pilot arc VC so me condenser ,. torus 8. In the output circuit of the power supply source 3 of the pilot arc, a current sensor 9 is connected, made in the form of a shunt, to which the base and the emitter circuit of the transistor 10 are connected, which contains a light emitting diode of the optocoupler and a load resistance 12 in the collector circuit. in the base circuit there is a limiting resistance 13. Parallel to the output terminals of the power supply source 3, the duty of the arc is also connected to a circuit of series-connected resistors 14 and zener diode 15 to stabilize its voltage across the collector of transistor 10.

Similarly, the current sensor 16 is connected to the output circuit of the power source 1, and the input circuits of the transistor 17c are connected to the limiting resistance 18, the light-emitting diode of the optocoupler 19 and the load resistance 20, as well as the voltage stabilization circuit 21 with the zener diode 22.

The device contains power switches 23-25 in the power supply circuits of the oscillator 6, the power supply source 3 of the pilot arc and the power current source 1, for example,

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counter-included power thyristors, to the control circuits of which the output buses of multiplexers 26-28 are connected. In addition, the device contains a low-power power source 29 of the control system of the power switches 23-25, the output terminals of which are connected to the power supply and input buses of the multiplexers 26-28 and control chains containing the installation start button 30, photodiodes of the optrons 11 and 19 and current limiting resistances 31-33. The midpoints of the control chains are connected to the address buses of the multiplexers 26-28.

In the proposed device, counter-connected thyristors can be used as power switches, for example, TL and TV series. Multiplexers can serve, for example, microcircuits of the K155KP5, K155KP7 series. Shunts are used as current sensors. Dp devices of galvanic isolation can be used diode optocouplers series AOD or ZOD.

The device works as follows.

When the plasma-arc installation is connected to the mains, the power switches 23-25 are open, therefore, the mains voltage is supplied only to the control system power supply 29, the photodiodes of the optocouplers 11 and 19 are closed. When closing the start button 30 to the address buses of multiplexers 26-28, comes from control chains such a combination of high and low signals that provide high level signals on the output buses of multiplexers 26 27. These control signals include power switches 23 and 24 therefore, the supply voltage is applied to the oscillator 6 and the source 3 of the pilot arc. At the output of multiplexer 28, a low level signal is generated that prevents the power switch 25 from being turned on.

The high alternating voltage generated by the oscillator 6 and developed in the secondary winding of the transformer 7 is applied through the capacitor 8 to the cathode 4 and the nozzle 5 of the plasma torch and causes electrical breakdown of the air gap, while a control arc from the power supply source of the pilot arc lights up.

DC current flows through the sensor.

9 current and causes a voltage drop across it, which opens the transistor 10. In the collector circuit of the transistor

10 begins to flow a current, generating a glow of the light-emitting diode of the optocoupler 11 and opening the photodiode of this optocoupler. When the photodiode of the optocoupler 11 is turned on, the combination of low and high level voltages applied to the address inputs of multiplexers 26-28 is changed so that at the output of the multiplexer

26 a low level signal appears that turns off the power switch 23, therefore, the oscillator 6 is disconnected from the mains. The output signal of multiplexer 27 remains unchanged. A high level signal appears at the output of multiplexer 28, which turns on the power switch 25, while the supply voltage is applied to the power source 1 of the current. The arc that burns through the cathode 4 and the nozzle 5 is blown, and the plasma sample is blown out with a gas from the plasma torch. When the duty arc of the workpiece is touched, the output power supply circuit of the power source 1 of the current closes and the main arc arises in the electrode gap 2. A constant current flows through the current sensor 16. The voltage drop across the sensor opens the transistor 17, in this case the optocoupler 19 is triggered and the input combination of signals on the address buses of the multiplexers .26-28 is changed. As a result, the power switch 24 is turned off and the supply voltage of the grid remains applied only to the power source 1 of the current. In the event of a failure in the arc, the start-up process is resumed in the same order automatically and spontaneously. When the installation start button 30 is opened, regardless of the level of the signals removed from the control chains from the photodiodes of the optocouplers 11 and 19, low-level signals are turned on at the output pins of the multiplexers 26-28, including the power switches 23-25.

The proposed device provides increased reliability in comparison with the known technical solutions due to autostabilization of starting

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in case of possible disruption of the plasma arc burning, as well as due to the introduction of galvanic isolation devices that prevent the negative spread of high level of radio interference on the electrical circuits of the installation caused by the operation of the oscillator and the plasma arc. Automatic switching on the minimum time required for the device to operate, the oscillator - i torus, the power source of the pilot arc and the power source of current greatly increases the longevity of the plasma torch elements, minimizes the consumption of electrical energy that is consumed by individual units of the unit, therefore, reduces There are maintenance costs compared to existing devices.

Claims (1)

Formula invented A device for starting and feeding a plasma-arc direct current installation, containing a direct-acting plasma torch, a power source of current whose output is connected to the interelectrode gap, a power source of the pilot arc whose output is connected to the cathode and nozzle of the plasma torch, oscillator, the power supply of the control system and the current sensor, which is different in that, in order to increase the reliability of operation, it is equipped with three power switches, an additional sensor (current, three multiplexers and two At the same time, the power switches are included in the power supply circuit I of the power source of current, the power source of the pilot arc and the oscillator, the current sensors are included in the output circuits of the power source of the pilot arc and the power current source, the light emitting diodes of the optrons are connected to the control circuits, connected with current sensors, and photodiodes of optocouplers are included in the output circuit of the power supply of the control system, the cathodes of the photodiodes of the optocouplers are connected to the input buses of the multiplexers, the output buses of which are connected to the control electrodes ovyh switches.