SU751549A1 - Pulse generator for electroerosion machine - Google Patents

Description

one

The invention of oshosiis to the field of electrophysical processing methods and, in particular, relates to pulse generators for EDM machines.

Generators consisting of an auto-oscillator, pulse duration shaping stages, a pulse-potential coincidence block, a POWER amplifier, output semiconductor switches, a power source, an amplifier, an electronic sensor 1 are known.

The drawback of such generators is that they do not allow current pulses to be produced for the maximum possible duration determined by the state of the erosion gap.

The aim of the invention is to improve the performance of EDM machines, which can be achieved by creating a current pulse generator having a maximum possible duration determined by the state of the erosion gap, while maintaining the maximum possible frequency of these pulses, which allows to increase the average current value during processing and most increase the removal of metal per unit of time while maintaining the class purity of processing.

To do this, in the pulse generator, the output of the auto generator is connected to the input of a pulse width generator, the output of which is connected to a pulse input of a potential-potential coincidence unit, the output of which is connected to the input of a power amplifier and electronic sensor input. This allows current pulses to be received with a maximum frequency at a given inductance of a chain that connects the power source with an erosion gap and with a maximum of eleven duration, determined by the state of the erosion gap.

FIG. i shows the generator schematic diagram; in fig. 2 - graphki illustrating the operation of the device.

The self-oscillator 1 is connected to a pulse-width driver 2, the output of which is connected to a pulse input of a pulse-notional coincidence unit 3, whose output is connected to the input of a preliminary power amplifier 4, the output of which is connected to the inputs of output semiconductor switches 5 connected in series between the power source b and erosion interval 7. To the erosion gap 7 through the signal amplifier 8 its input is connected to an electronic sensor 9, made on the basis of the Schmitt trigger. Electronic sensor output

9 is connected to the potential input of the pulse-notional coincidence unit 3. The input of the electronic sensor 9 is additionally connected to the output of the pulse-potential coincidence unit 3.

The generator works as follows.

The pulse frequency is set by the self-oscillator 1, the signals from which (Fig. 2, a) go to the input of the driver 2 of the pulse duration. Shaper 2 produces pulses (Fig. 2, b) of the maximum possible constant duration, which determines the class of processing purity at a given pulse frequency of the oscillator 1. These pulses are formed in such a way that they are located at the end of the period of pulses produced by the oscillator 1, and their duration determined by the position of the leading edge with a fixed position of the trailing edge of the pulse.

From the output of the imaging unit 2, the signals are fed to the pulse input of an impulse-potential coincidence unit 3. Then, the pulses are amplified by a preamplifier of power 4, and then they are used to trigger the semiconductor switches 5 connected to the power supply source 6 and the same with the erosion gap 7. The sensor 9 and the immersion-matched block of coincidences 3 represent the feedback rate over the duration of the current pulse in the erosion gap 7. The link wound from the output pulse potential coincidence unit 3 to the input of electronic sensor 9 allows sensor 9 to be connected to the erosion gap 7 only at the end of the pulse coming from the output of the potential potential coincidence unit 3.

In the initial state, the potential input of the coincidence unit is excited, i.e. the pulse from the output of the imaging unit passes to the input of the preamplifier of power and to the input of the electronic sensor. In this case, the input of the electronic sensor is disconnected from the erosion gap, and the output keys are opened, a voltage is applied to the erosion gap, and its breakdown occurs. By filing a pulse from the output of the coincidence unit, the electronic sensor connects to the erosive point and analyzes it.

electrical condition. If the erosion state is abnormal, the sensor overturns and blocks the potential input of the coincidence unit. After the current drops in the erosion gap to zero, the sensor returns to its original state and unlocks the input of the soviadeia unit. In this case, it may be that a portion of the pulse from the imaging unit does not pass to the input of the preamplifier. If the state of the erosion gap at the time when the electronic sensor is connected to it will be normal, the next current pulse will have the maximum specified duration.

Thus, the processing is performed by pulses of variable current, but having a maximum value, determined by the state of the erosion gap after each discharge. Since the passage of a subsequent current pulse through the erosion gap is possible only after the current drops to zero in it, the short circuit mode is excluded, and

The treatment is carried out with the maximum frequency-response of pulses, determined by the inductance of the circuits connecting the power source to the erosion gap.

Claims (1)

Invention Formula A pulse generator for electrical erosion machines, comprising an oscillator connected in a series circuit, a pulse width former and a power preamplifier connected to semiconductor switches connected in series between the power source and the erosion gap to which through a signal amplifier A sensor is connected, the output of which is connected to the potential input of the impulse-potential coincidence unit, characterized in that, in order to increase the processing capacity, it is convenient An impulse coincidence unit is connected between the impulse duration driver and a pre-power amplifier, the output of the impulse-potential coincidence unit also connected with the sensor input. Ptochniki information taken into account and examination 1. Copyright certificate of the USSR 301972, cl. In 23P 1/02, 1969.