RU168090U1 - PLASMA SOURCE OF LIGHT RADIATION - Google Patents

Abstract

The utility model relates to plasma technology, in particular to controlled plasma devices, and can be used to solve a wide range of technical problems in testing materials, devices, and equipment samples for resistance to light radiation from natural and technogenic factors, in photochemistry and in light technologies processing of materials. A powerful and reliable plasma light source is proposed, capable of operating both in quasi-continuous mode and in the mode of forming relatively short impulses hs with a complex temporal shape and with steep fronts, which ensures the stability of the formation of predetermined temporal forms at high light emission intensity throughout the life of the nodes of the formation of a stabilized arc gas discharge. This technical effect is achieved by the fact that in a plasma light source including a controlled power source , a control unit, the input of which is connected to the output of the synchronizer, a stabilized gas discharge forming unit, the input of which is connected with the output of the gas discharge initiation unit and with the cathode of the separation diode, and the output signal sensor, it is new that it additionally includes a controlled constant voltage converter connected between the output of the controlled power source and the anode of the separation diode, two additional diodes and a matching unit, additional cathodes diodes are connected to the control input of a controlled power source, the anode of the first diode through the matching unit is connected to the output of the output signal sensor, the anode th

Description

The utility model relates to plasma technology, in particular to controlled plasma devices, and can be used to solve a wide range of technical problems in testing materials, devices, and equipment samples for resistance to light radiation from natural and technogenic factors, in photochemistry and in light technologies processing materials.

To solve these problems, emitters with high brightness and a large luminous area are required, capable of generating light pulses with a given complex temporal shape in a wide range of durations, including short pulses of several tens of milliseconds with fairly steep fronts.

The most promising plasma sources of light radiation that meet the requirements of the problem being solved are sources based on a high-current device stabilized by the walls of the device or by the magnetic field of an arc discharge. The formation of such a discharge can be carried out, for example, in gas discharge lamps that are sufficiently long compared with the diameter of the bulb, when the boundaries of the discharge are rigidly defined by the inner walls of the bulb. In an open atmosphere, the formation of an arc discharge can be carried out, for example, in trays, the role of one missing wall in which is played by a magnetic field pressing the plasma to the bottom of the tray, a magnetically pressed arc discharge. The parallel inclusion of several lamps located in the same plane can be used to increase the radiating surface of the tube emitter.

Known plasma light source [US Pat. RF №2370002, IPC H05H 1/50, prior. 20.10.2008], including a controlled power source, the control input of which is connected to the output of the control unit, the input of which is connected to the synchronizer, and the output is through an isolation diode with the input of the stabilized arc gas discharge forming unit, the output of which is connected to the housing, and the gas initiation unit discharge, the output of which is connected to the input of the stabilized arc gas discharge forming unit, and the control input is connected to the synchronizer output.

Such a device with a controlled power source, for example, a thyristor rectifier, allows for a long time to obtain a bright plasma with a given time profile, a large emitting surface and with a spectrum close to the radiation spectrum of a completely black body. However, such a plasma light source is not sufficiently reliable in the initial stage of discharge formation.

Closest to the proposed solution is a plasma light source [Pat. RF №149862, IPC H05H 1/50, prior. 09/30/2014], including a controlled power source, the control input of which is connected to the first output of the control unit, the first input of which is connected to the synchronizer, and the output through the controlled key and the diode is connected to the input of the stabilized arc gas discharge forming unit, combined with the output of the initiation unit gas discharge, the anode of the diode is connected to the housing through a capacitor, the second output of the control unit is connected to the first input of the comparison circuit, the output of which is connected to the second input the control unit’s house, and the second input - with the output of the output signal sensor, for example, a current sensor, the synchronizer output being connected directly to the control electrode of the controlled key, and to the control input of the gas discharge initiation unit through the delay unit, the amount of time delay of which is determined by the condition from the parameters of the plasma light source.

Such a plasma light source has increased reliability in the initial stage of the formation of an arc discharge due to the optimization of the time of initiation of the arc discharge relative to the beginning of the transient process of turning on the thyristor power source. The implementation of such a source makes it possible to reliably obtain for a long time a bright plasma with a given time profile and a large radiating surface. However, with this solution of the plasma light source, it is not possible to generate relatively short pulses, for example, with fronts of less than 20 ms. In its implementation, due to the filtering properties of the capacitor, the ripple in the form of a light pulse can be slightly reduced. But increasing the capacitance of the capacitor to reduce the level of ripple further increases the already quite long fronts of the generated light pulses.

A powerful and reliable plasma light source is proposed, capable of operating both in a quasi-continuous mode and in the mode of forming relatively short pulses with a complex temporal shape and with steep fronts, which ensures the stability of the formation of predetermined time shapes at high light emission intensity over the entire lifetime of the nodes the formation of a stabilized arc gas discharge.

Such a technical effect is achieved in that in a plasma light source including a controlled power source, a control unit, the input of which is connected to the synchronizer output, a stabilized gas discharge forming unit, the input of which is connected to the output of the gas discharge initiation unit and to the cathode of the separation diode, and the sensor of the output signal, new is that it is additionally introduced into it controlled between the output of the controlled power source and the anode of the diode diode controlled a dc voltage converter, two additional diodes and a matching unit, the cathodes of additional diodes are connected to the control input of the controlled power source, the anode of the first diode is connected to the output of the output signal sensor through the matching unit, the anode of the second diode is connected to the first output of the control unit, the second output of which is connected to the control input of the DC / DC converter, the control input of the gas discharge initiation unit being connected to the synchronizer output, and the output sensor with I drove formed as a current sensor.

If it is necessary to obtain the maximum correspondence of the temporary forms of the control voltage of the DC-DC converter and the light pulse, then the controlled DC-DC converter is performed with feedback on the output current (see Section 2 of the Formula).

If it is necessary to obtain the minimum pulsation of the light pulse, then the matching unit is performed in the form of a threshold element (see paragraph 3 of the Formula).

If it is necessary to obtain minimum voltage spikes at the input of the DC-DC converter, then the threshold element of the matching unit is performed with the current response level found from the condition:

I _POR ≈0.9⋅I _OGR ,

where I _POR is the response current of the threshold element of the matching unit, A;

I _OGR is the limiting current of the controlled DC-DC converter, A (see paragraph 4 of the Formula).

The drawing shows a functional diagram of the claimed plasma light source, including a controlled power supply 1, a control unit 2, a synchronizer 3, a stabilized arc gas discharge forming unit 4, a gas discharge initiating unit 5, an isolation diode 6, an output signal sensor 7, a constant converter 8 voltage, additional diodes 9 and 10 and block 11 matching.

The device operates as follows.

The temporary pulse shape of the control voltage of the controlled DC / DC converter 8 is set and entered into the memory of the control unit 2, but at the same time, there is no control voltage at the second output of the control unit 2, and therefore also at the control input of the controlled DC / DC converter 8. At the first output of the control unit 2 and, accordingly, at the cathode of the diode 10, a voltage is constantly present to control the power source 1 of such a value that provides the required voltage at its output that is safe for the controlled DC-converter 8. Therefore, at the output of the controlled DC-converter 8, an open circuit voltage is present, usually not exceeding a few percent of the maximum. There is no current at its output, because a gas discharge in the stabilized gas discharge generator unit 4 has not yet been initiated and the stabilized gas discharge formation unit 4 is in a non-conductive state. The gas discharge initiation unit 5 is restored to its initial state, but there is no voltage at its output due to the absence of a triggering pulse from its output of the synchronizer 3 at its control input.

The start of the plasma light source is carried out by supplying a triggering pulse from the output of the synchronizer 3 simultaneously to the input of the control unit 2 and to the control input of the gas discharge initiation unit 5. The control unit 2 with the arrival of the triggering pulse begins to generate, taking into account the time form specified in its memory, the control voltage and feeds it from its second output to the control input of the controlled DC converter 8. The same pulse of the synchronizer 3 simultaneously arrives at the control input of the gas discharge initiation unit 5. Own internal keys are switched on in the gas discharge initiation unit 5 with the arrival of the triggering pulse, and a pulsed voltage sufficient to break the interelectrode gap and initiate the gas discharge in the stabilized gas-gas arc generation unit 4 appears at its output. The interelectrode gap of the stabilizer gas discharge generator unit 4 is punctured by the pulse voltage applied from the gas discharge initiation unit 5, and a gas discharge is initiated in it. The diode 6 prevents the flow of energy from the node 5 initiating a gas discharge to the output of the controlled DC converter 8. An electric current starts to flow through the node 4 of the stabilized arc gas discharge former from the gas discharge initiation node 5. This current begins the formation in node 4 of the shaper of a stabilized arc gas discharge of the emitting plasma layer. Thus, for a while, while the current flows from the gas discharge initiation unit 5, the conductivity of the stabilized arc gas discharge generator unit 4 is ensured.

Due to the conductivity of the node 4 of the shaper stabilized arc gas discharge, he is now ready to receive current from the controlled Converter 8 constant voltage. And therefore, as soon as the voltage at the discharge gap from the gas discharge initiation unit 5 becomes less than the voltage at the output of the controlled DC / DC converter 8, the isolation diode 6 opens and the current of the converter 8 starts flowing through the formed plasma in the interelectrode gap of the stabilized gas-gas discharge generator unit 4 together with the current node 5 initiating a gas discharge. Due to its high frequency properties, usually tens of kilohertz for the current level of semiconductor devices, a controlled DC voltage converter 8 even before the initiating discharge ends provides a current set by the control voltage at its output. If the total current of both sources exceeds the value of the arc discharge current corresponding to the minimum of its current-voltage characteristic, then the discharge reliably picks up the current of the controlled DC / DC converter 8 and then continues to burn stably, consuming ultimately the current only from the controlled DC / DC converter 8, the value of which is determined preset control voltage.

The appearance and growth of current in the node 4 of the shaper stabilized arc gas discharge leads to an increase in current consumption controlled by the Converter 8 constant voltage from a controlled power source 1. Due to the existence of internal resistance at the controlled power source 1 and its power circuits, under the conditions of constant control voltage, the output voltage of the controlled power source 1 begins to decrease. On the other hand, with an increase in the gas discharge current, the voltage drop across the interelectrode gap also increases. Thus, with an increase in gas discharge current, the input voltage of the controlled DC-converter 8 decreases, and the output voltage increases. As a result, the voltage drop across the controlled DC / DC converter 8 becomes so small that it loses its control function. Those. regardless of the magnitude of the control voltage, a further increase in current in the node 4 of the stabilized gas discharge former becomes impossible. In this case, the output current is limited by a controlled DC voltage converter 8 at a certain level (I _GI ), the value of which depends on the load resistance when such a current flows through it and the internal resistance of the controlled power supply 1. The limitation of the gas discharge current leads to a limitation of the intensity of the generated light pulse. It is impossible to correct the control voltage of the thyristor rectifier 1 directly from the control unit 2 by preliminary setting the start and duration of the increase in the control voltage of the controlled power supply 1 at a certain time due to the significant instability of the gas discharge and its current-voltage characteristic and, in particular, because of the high probability premature current interruption and gas discharge extinction.

In the proposed technical solution, the elimination of the mode of limiting the intensity of the light pulse is carried out by correcting the control voltage of the controlled power source 1 by the voltage of the sensor 7 of the output signal supplied to the control input of the controlled power source 1 through the matching unit 11 and diode 9. The matching unit provides coordination of the output voltage of the sensor 7 of the output signal with the desired control signal level of the controlled power supply 1. At the beginning of the formation of the front of the output signal, the voltage at the output of the matching unit 11 is less than the voltage supplied through the diode 10 to the control input of the controlled power supply 1. The diode 9 is closed by this voltage, and the correction circuit does not affect the value of the output voltage of the controlled power source 1. When, with an increase in the intensity of the output signal, the voltage at the output of the matching unit 7 becomes higher than the voltage at the first output of the control unit 2, the diode 9 opens, closing the diode 10, and the control voltage of the controlled power supply 1 starts to increase along with the growth of the output signal. Accordingly, the output voltage of the controlled power supply 1 also rises, pushing the beginning of the operation of the controlled constant voltage converter 8 in the current limiting mode to the high current region. Closed in this mode of operation, the diode 10 does not allow the output voltage of the matching unit 11 to act on the control unit 2.

As the sensor 7 of the output signal, one could use a photosensor, which was quite effective in the prototype device. However, in this case, the photosensor does not always correctly reflect the temporal shape of the output signal. So, for example, when various samples are irradiated with powerful light pulses, as a rule, various fumes are emitted into the atmosphere, fumes of materials from the irradiated surface, etc., especially when working with open discharges, which include a magnetically pressed arc discharge. Therefore, the photosensors cannot provide accurate and timely switching of the control channels of the controlled power source 1. If we use the output current sensor of the controlled DC converter 8 as the output signal sensor 7, then regardless of the structural changes of the stabilized gas discharge former 4, the appearance of fumes or combustion products of the test samples near it, the switching current will always remain constant. The latter guarantees reliable, stable operation of the plasma light source under any conditions of its use.

When switching the control channels and the corresponding change in the control voltage of the controlled power source 1, its output voltage also changes, providing an extension of the current range. However, the expansion of the current range in this case leads to the obligatory change of the given temporal shape of the generated light pulse. To eliminate the influence of the changing input voltage of the controlled constant voltage converter 8 on the time shape of the generated light pulse, the controlled constant voltage converter 8 can be made with current feedback. The relatively long reaction of the feedback circuit in this case does not impair the reliability of the proposed device. Moreover, the presence of current feedback in the considered node of the device leads to an additional increase in the reliability of starting a gas discharge after its initiation due to the initial maximum high output voltage of a controlled DC voltage converter 8 with current feedback. (see paragraph 2 of the Formula).

In a mode close to the current limiting mode of the controlled DC / DC converter 8, increased ripples are usually observed on the temporary form of the generated current pulse and, accordingly, on the light pulse. To lower the level of these ripples, it is proposed to execute block 7 matching in the form of a threshold element. In this case, when the specified switching current of the control of the controlled power source 1 is reached, the output signal of the matching unit 7, and hence the control voltage of the controlled power source 1, will not be relatively slow, but will jump up to a predetermined, up to the limit value. In this case, increased pulsations, if they appear, only near the limit values of the intensity of the generated light pulse (see paragraph 3 of the Formula).

Using the matching unit 11 in the form of a threshold element leads to a jump in the input voltage of the controlled DC / DC converter 8 at the time of switching the control channels of the controlled power supply 1. The magnitude of this jump is greater, the smaller the set value of the switching current. It would seem that you need to choose the switching current extremely large. But then, when the device is turned on, relatively high-resistance loads may not even accelerate the discharge current to the level of the switching current. To ensure the minimum magnitude of the input voltage surge of the controlled DC-converter 8 when working with relatively high-resistance gas discharges, for example, gas discharge lamps, the threshold element of the matching unit 11 must be made with the current response level found from the relation:

I _POR ≈0.9⋅I _OGR ,

where I _POR is the response current of the threshold element of the matching unit, A;

I _OGR - current limitation of the controlled DC-DC converter, A.

With this selection of the switching level in the threshold element of the matching unit 7, the control channels of the controlled power source 1 are guaranteed to switch at the minimum output voltage surge, regardless of the type and nature of the load (see paragraph 4 of the Formula).

Thus, the introduction of an additional high-frequency controlled converter 8 of a direct voltage and an almost inertialess correction circuit of the control voltage of a controlled power source 1 by an external signal into the plasma light source provided the formation of powerful light pulses of short duration with steep fronts, high reliability of the start of the gas discharge load, as well as extended range of working intensities.

A mock-up of a powerful plasma light source was made at the enterprise. As a stabilized arc gas discharge, we used both a magnetically pressed discharge in an open atmosphere with a radiating surface area of 16 cm ² (length 8 and width 2 cm) and a lamp panel of 14 short xenon lamps of type INP-16/250. The PP-PPPT-6.5k-600-I-UHL4 converter, operating according to the PWM method with a pulse repetition rate of 12 kHz, was used as a controlled DC-DC converter. The converter could provide a load current of up to 6500 A at a supply voltage of 600 V. The converter was controlled using feedback on the output current, i.e. under normal conditions, the temporary form of the converter output current fully corresponds to the temporary form of the control voltage. The converter was powered by a controlled power source, made in the form of a six-pulse thyristor rectifier type KTEU-4000. The total filter capacity at the output of the thyristor rectifier was about 58 mF; the filter was shunted with a resistance of 143 ohms. The isolation for the magnetically pressed discharge was carried out through a separation diode of the type D173-2000. Decoupling with the use of a lamp panel was carried out for each lamp - through three series-connected isolation diodes of type D143-800. A K75-100 capacitor charged to a voltage of about 2000 V with a capacity of 100 μF and an operating voltage of 3000 V was selected as the site for initiating a gas discharge. This capacitor was connected to the magnetically pressed discharge unit via an IRT-6 ignitron. When using a lamp panel, such a capacitor was connected via an additional current-limiting circuit directly to the electrode of each xenon lamp. And the lamp panel lamps were ignited from an auxiliary pulse generator with an output pulse amplitude of about 20 kV. The magnetically pressed discharge was ignited using an initiator made of aluminum foil. Such a power system with an electric power of up to 4 MW provided current pulses with an amplitude of up to 6500 A at a voltage of about 600 V and a duration of up to 5 seconds in a low-resistance (50-80 mOhm) gas-discharge load. The functions of the synchronizer and the control unit were performed by a personal computer with additional amplifiers on both channels of the control unit. An instrument based on the Hall effect with galvanic isolation between the power and measuring circuits of the HAX 5000-S type was used as a stabilized gas discharge current sensor. To coordinate the output voltage of the current sensor (not more than 4 V) with the required control voltage of the thyristor rectifier (up to 8 V), a special circuit of the matching unit with an amplifying transistor operating in key mode was developed. This, firstly, provided the required threshold nature of switching the output signal and, secondly, made it possible to quite simply adjust the value of the switching control current channels by changing the value of the input current-limiting resistor of this transistor. The signals from the first output of the control unit and from the output of the matching unit through two diodes of type 1N4002 were fed to the control input of the thyristor rectifier.

In a series of launches made both with a lamp panel and with a magnetically pressed arc discharge, high reliability of pickup of the gas discharge load by the power system was obtained, and high stability of reproduction of the temporal shape of the light pulse with fairly steep fronts was confirmed. The optimal switching current of the control channels of the thyristor rectifier was about 2400 A for a low-resistance magnetically pressed discharge, and 1200 A for a relatively high-resistance lamp panel load (about 0.1 Ohm). With these settings of the threshold element of the matching unit, the maximum current reached 6400 A in the magnetically-charged discharge, and the lamp panel is 5600 A. In these experiments, at a brightness temperature of the plasma of a plasma light source based on a magnetically pressed discharge of about 5600 K in the visible region spectrum, the energy luminosity was not worse than 700 J / cm ² , and the surface radiation energy density was at the level of 4⋅10 ³ W / cm ² . The durations of the fronts of light pulses measured during the formation of pulses with a rectangular time shape did not exceed 1 ms, while in the prototype device it was not possible to obtain durations of fronts of less than 18 ms. A change in the control channels of the thyristor rectifier during pulse formation had practically no effect on the temporal shape of light pulses, which was checked during the formation of light pulses of a triangular time shape at various pulse durations from 40 ms to 5 seconds. The amplitude values of the intensities of the light pulses did not change when the voltage of the supply network changed within 10%. It should also be noted a significant reduction in ripple in the form of a light pulse. Ripples were observed mainly in the region of limiting intensities of the light pulse and could reach 7%.

When the power system was operating without increasing the control voltage of the thyristor rectifier during pulse formation, for example, if the matching unit was incorrectly configured, the discharge currents were limited and did not exceed 2600 A and 1400 A for a magnetically pressed discharge and a lamp panel, respectively, although the pulse fronts were formed quite steep. In such a regime, a sufficiently large exponentially decaying peak was always observed at the front of the rectangular pulse, which is due to the large initial energy supply in the filter capacitor of the thyristor rectifier. In this case, the “backfill" of the thyristor rectifier in this case was almost 60%: the initial voltage of about 660 V decreased when even a not very intense light pulse was formed to almost 260 V.

Thus, tests of the model of a plasma light source showed that the energy parameters of the generated light pulse in the proposed device, as well as the reliability of picking up the discharge current and the stability of the reproduction of the temporal shape of the generated light pulse from pulse to pulse, are no worse than the similar parameters obtained in known devices. And in terms of temporal dynamic parameters, the indicators are significantly increased, which allows us to simulate a more expanded set of natural and technogenic sources of light radiation, including very short ones, up to several milliseconds in duration.

Claims (7)

1. A plasma light source including a controlled power source, a control unit, the input of which is connected to the synchronizer output, a stabilized gas discharge forming unit, the input of which is connected to the output of the gas discharge initiation unit and the cathode of the separation diode, and an output signal sensor, characterized in that it additionally includes a controlled DC-converter connected between the output of the controlled power source and the anode of the dividing diode, two diodes and a matching unit, while the cathodes of additional diodes are connected to the control input of the controlled power source, the anode of the first diode is connected through the matching unit to the output of the output signal sensor, the anode of the second diode is connected to the first output of the control unit, the second output of which is connected to the control input of the DC-DC converter , the control input of the gas discharge initiation unit is connected to the output of the synchronizer, and the output signal sensor is made in the form of a current sensor. 2. The plasma light source according to claim 1, characterized in that the controllable DC-voltage converter is made with feedback on the output current. 3. The plasma light source according to claim 1, characterized in that the matching unit is made in the form of a threshold element. 4. The plasma light source according to claim 3, characterized in that the threshold element of the matching unit is made with the current response level found from the condition: I _POR ≈0.9⋅I _OGR , where I _POR is the response current of the threshold element of the matching unit, A; I _OGR - current limitation of the controlled DC-DC converter, A.

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