SU1022301A1 - Generator of combined unipolar discharges - Google Patents

Abstract

GENERATOR OF THE UNIPOLAR COMPUTING DISCHARGES, contain, at the very least, two spark charging circuits with a smaller and larger discharge inductors, each of which is formed by a capacitive gopltel and a common set of nimmers, and a single set of nimmers, and a single set of num- pers and a set of num- pers and a set of nimmers and a single set of nymperntheras. ignition inductance, and a poro pulse generator connected to the output of an ignition inductance coil, while the circuit with a higher discharge inductance contains an inductive coil The bones are connected in series with the capacitive storage of this circuit, which is equipped with an additional noporoKJM pulse shaper and two controllable keys, one of which is The discharge circuit with a lower inductance is connected to the discharge circuit, and the other one is connected to the discharge circuit with a higher inductance, while the input “aj-j of the forwarder is connected to the capacitance-1 tal by the storage circuit with a larger g discharge inductance, and the output with the ruling input of the corresponding r key.

Description

The invention relates to a pulse technique, in particular to generators of electrical discharges used as sources of excitation of emission optical spectra, and can be used in metallurgical, mining, machine-building, chemical and other industries in spectral analysis of the chemical composition of various metals, and also in instrumentation.

A known generator combines pulsed arc discharges containing arc and spark discharges | Circuits with a common discharge radiator and ignition inductance, a capacitor, a controlled valve in the spark discharge circuit, and a discharge current valve in the arc circuit, and the cathode is controlled the valve is connected to the positive arc electrode, and the anode is connected to the positive capacitor plate.

A disadvantage of the known generator is the dependence of the analysis results on the composition, mass properties and configuration of the angularized sample due to the presence of an arc discharge in the combined pulse, which can cause overheating of the analyzed sample and the development in the analyzed zone of processes for the selective entry of impurities into the plasma of the combined discharge.

Therefore, the combined discharge generators are more promising, providing a superposition of two spark discharges in the common discharge emitter.

Also known is a generator of unipolar combined bits, containing two spark bits. a circuit with a common discharge radiator and capacitive storage devices, one of which is connected to an alternating voltage source and the other to a unipolar voltage source, an ignition unit and an ignition control unit.

The inductance of one of the discharge circuits is smaller than the other, which ensures the superposition of hard and soft spark discharges. In this case, initially a hard phase of the combined bit 2 is formed.

A disadvantage of the known generator is the narrow range of independent control of the parameters of each discharge circuit due to the necessity of fulfilling the condition U 3 where 3 is the instantaneous value of the aperiodic discharge current in the circuit with greater inductance, and 3 is the corresponding D-i maximum current value in the reverse half wave of a hard oscillating spark.

discharge in the circuit with a lower inductance. This reason leads to a decrease in the analytical capabilities of the generator.

In addition, the known generator has a reduced accuracy and efficiency of excitation of elements that are difficult to excite due to the instability of the shape and amplitude of the current of the tail part of the oscillatory discharge and the limitation of the maximum amplitude of its discharge current by the resistance of the circuit.

The closest to that proposed by the technical essence is a generator of unipolar combined bits containing. At least two spark charge-discharge circuits with a smaller and a larger discharge inductances, each of which is formed by a capacitive drive and their common pulsed power supply to the drives and in series with an emitter and inductance of the ignition, and a threshold pulse shaper C.

In a well-known generator, electrical breakdown of a radiating emitter with a spark .. by firing causes a simultaneous start of discharge through it of capacitive storage of both circuits. At the same time, a hard phase of the aperiodic spark with a high rate of rise and the amplitude of the discharge current, which acts on the solid surface of the sample, first occurs, and immediately after it ends the soft phase of the aperiodic spark with a smaller amplitude of the discharge current and a longer duration due to the discharge circuit circuit with a higher INDUCTANCE. A superposition of the accumulator bits creates a combined pulse, the frequency of which is determined in a known generator by the frequency of the mains voltage.

However, the known generator has a low efficiency of exciting a hard phase spectrum due to the dependence of the intensity of this spectrum on the structure and physicochemical properties of the sample when the hard discharge phase is applied to the hard surface of the angulated portion of the sample and the reduced rate of entry of the analyzed elements into the discharge plasma from the solid analyzed zone ;

In addition, in the known generator, the frequency of the combined bits does not exceed the setter frequency, which limits its use in the rapid determination of the chemical composition of materials. These reasons lead to a narrowing of analytical capabilities. The purpose of the invention is to increase the efficiency of the excitation of the spectrum by providing an electronically controlled shift of the hard phase of the combined spark pulse relative to this pulse and the spread of functionality. This goal is achieved by the fact that a generator of unipolar combined bits, containing at least two spark charge-discharge circuits, respectively, with smaller and with larger discharge inductances, each of which is formed by a bone store and a common pulsed source. power supply of the accumulators and successively connected by the discharge-emitter and the inductance of the ignition, and the threshold forkofovatel pulses connected to the output of the inductance under the Gig, while the circuit with a greater inverse The inductance contains an inductance coil connected in series with a capacitive drive of this circuit, equipped with an additional threshold pulse shaper and two: controllable keys, one of which is included in the discharge circuit with a smaller inductance and the other in a discharge circuit with a higher inductance , while the input of each driver is connected to it with a bone accumulator of the circuit with a higher discharge inductance, and the output - with the control input of the corresponding control key. The sensing element of each driver is made in the form of an electromagnetic relay having a release threshold. In order to provide an increased power of discharge pulses when a spectrum of difficult-to-excitable elements is excited, an electrical discharge is used as the key element of the controlled contour key with a smaller discharge inductance. FIG. 1 shows a block diagram of the proposed generator; FIG. 2 discharge current diagrams in the emitter. The generator has two spark variable-discharge circuits with a spade and a higher discharge inductance. : A circuit with a lower inductance contains a capacitive drive 1 and a gate 2 discharge current, and a circuit with a higher discharge inductance capacitive drive 3 and an adjustable discharge inductance 4. Charges 5 and 6 of the charge current are connected to the charge circuit of drives 1 and 3. The circuits also contain for them a pulsed power source 7 and a series-connected discharge-emitter 8 and an ignition inductance 9, which is connected to the threshold shaper 10 pulses. . In razr. A lower circuit with a lower inductance includes a control key 11, and a bit circuit with a higher inductance is included; S is a control key 12. The generator is equipped with an additional driver 13 pulses. The inputs of the shaper 10 and 13 are connected to the capacitive drive 3, and the outputs from the control input of the respective controlled keys 11 and 12. At the same time, at least one input element of the shaper 10 and 13 includes an element of the drive's size. Sensitive elements are installed at the entrance of forgars 10 and 13, which have a specific release threshold (response). The corresponding reference voltages II are brought to the terminals 14 and 15 of the formers 10 and 13, and, equal to the voltage of their response threshold. In order to provide an increased power of the discharge pulses, when the spectrum of difficult-to-excitement elements is excited, the control key 11 contains an electric disconnector as a key element. At a lower power of the discharge pulses, for example, a thyristor circuit can be used as the key 11. The generator works as follows dim image l. In the initial state, the switching power supply is connected to the mains (but not included), the controlled keys 11 and 12 are closed, the voltages on the accumulators 1 and 3 are equal to zero. The shaper 10 is adjusted to the voltage of the release threshold TS and the shaper 13 is set to the voltage of the release threshold U. The values of the voltages 11 and U should be chosen from the conditions: o, V. allowing the start of the hard discharge phase to shift relative to the beginning of the combined discharge pulse. The switching power supply 7 is adjusted to charge drives 1 and 3 with a given frequency up to a given voltage U;; For normal operation of the generator voltage values. U. and, and should be chosen from the condition 1,, o,) (d) When switching to the pulsed power supply source 7, the accumulators 1 and 3 are charged through the gates 5 and 6 by the pulse of the alternating current of the power source 7 to the voltage . At the moment of pause after the end of the charge pulse, the voltage on the drive 3 decreases due to the discharge through its discharge element at the input of the driver. When the voltage on drive 3 reaches the voltage and threshold of triggering device 10, the last output pulse arrives at the input of key 12 and opens it. At the same time, this pulse will go to the inductance 9 of ignition, which will provide a breakdown of the emitter-discharge 8 with a low-power high-voltage ignition spark and the discharge of accumulator 3 through it, the open key 12 and inductance 4, the discharge of accumulator 3 creates a soft phase of the combined pulse at which possible melting of the analyzed zone. As the drive 3 is discharged, the input to the driver 13 decreases. When it reaches the voltage and-) threshold of the release of the driver 13, at the output of the last VITS pulse, which opens the key 11. The drive 1, charged before the voltage and, after opening the key 11, discharges through the last, valve 2 and plasma m of the combined phase of the pulse in the discharge emitter 8. The accumulator 1 produces a hard phase of the combined pulse in the discharge emitter 8. At the end of the discharge of accumulators 1 and 3, the discharge current in the emitter 8 stops, causing the keys to close 11 and 12. Through the time interval determined by the predetermined frequency and the duty cycle of the combined bits are pulsed with the power source 7 being charged to the collectors 1 and 3. The cycle of the generator will be repeated until the power source 7 is automatically turned off after the specified number of pulses has been fired and the combined bits have been exposed. In the generator, a hard spark discharge phase occurs after the formation of a soft phase, and the magnitude of the shift of the onset of the hard phase relative to the beginning of the soft (beginning of the combined pulse) is entirely the same as the ratio of the voltages of the triggering voltage of the formers 10 and 13. The shift can be optimally adjusted by appropriate experiments in the development of analysis techniques. FIG. 2a and ff are given as an example of the plots of the discharge current of the combined pulse in the emitter at two different durations of the soft phase, set respectively by two values. FIG. 2 are indicated: the duration G of the initial soft phase of the combined pulse, the duration of the hard phase of the combined pulse, the duration 6 of the combined pulse. With an optimal ratio, and therefore, with an optimal shift of the beginning of the hard phase relative to the beginning of the combined pulse, the efficiency of excitation of its spectrum increases. This is due to the fact that at the time of the occurrence of a hard phase in the discharge emitter, a soft phase plasma already exists, which is more enriched in the analyzed vapors of the substance, and the hard discharge phase acts on the molten soft phase in the analyzed zone of the sample, rather than on firm as a prototype. Therefore, the energy of the hard phase is consumed efficiently, since it is mainly used to excite the vapor. In addition, the effect of a hard phase on the surface of the analyzed zone in the state of melting it with a soft spark discharge phase reduces the influence of the structure on the accuracy of analyzes. Thus, the proposed generator increases the efficiency of excitation of the spectra of a hard phase, especially difficult-to-excitable elements, and reduces the influence of the structure, which increases, respectively, the sensitivity and accuracy of the anchors. One of these, "provides a wider frequency range of the discharge, adjustment and precise setting of the relative predetermined shift of the soft and rigid phases of the spark discharge, regardless of the selected parameters of the discharge circuits and the availability of information about the duration of the bits constituting xymbinirovanny. These advantages of the generator greatly enhance its analytical capabilities.

Claims (1)

A UNIPOLAR COMBINED DISCHARGE GENERATOR containing at least two spark charge-discharge circuits, respectively, with a smaller and a larger discharge shared pulse power supply and sequentially switching on / off the spark-emitter and inductance ignition, and a threshold pulse shaper connected to the output of the ignition inductor, while the circuit with a larger discharge inductance contains an inductor connected in series with the capacitive storage of this circuit, about The reason is that, in order to increase the efficiency of spectrum excitation and expand functional capabilities, it is equipped with an additional threshold pulse shaper and two controlled keys, one of which is included in the discharge circuit with a lower inductance, and the other into the discharge circuit with a larger inductance, while the input of each shaper is connected to a capacitive storage circuit with a larger discharge inductance, and the output is