SU1006147A1 - Device for photocopying electric spark machining - Google Patents

Abstract

A DEVICE FOR PHOTOCOPIROL ELECTRIC BACKGROUND PROCESSING, containing a power source connected to the tool electrode and part, transverse and longitudinal feed motors with control units connected to the outputs of the photo-optical system including the radiation source, photomask, photo sensor and photo sensor processing unit, which features a separate sensor and a component that includes a radiation source, a photo pattern, a photo sensor and a photo sensor processing unit. In order to simplify the device during the electric-spark doping, the photosensor signal processing unit is designed as a Schmitt trigger, the output of which is connected to the T inputs trigger and one-shot, the outputs of which are the outputs of the photo-optical system.

Description

F (/ r.1

The invention relates to electrophysical processing methods and relates, in particular, to devices for electrospark doping.

Devices for photocopier electrospark processing are known, which contain a power source connected to the tool electrode and part, longitudinal and transverse feed motors with control units connected to the outlets of the photo-optical system.

The photooptical system is made in the form of a radiation source, a photomask and a block of signal processing of the photosensor 1.

The disadvantage of these devices is that they are not suitable for electrospark doping, as they are designed to monitor the line of the drawing, which determines the complex execution of the photosensor signal processing unit.

The aim of the invention is to simplify the device with an electric-spark alloying scientific research institute when the surface is treated, and not the line.

This goal is achieved by the fact that in the device, containing a photo-optical system, a photomask, a photo sensor (photodiode) and a signal processing unit, a photo-optical system connected to the engine control blocks of the longitudinal and transverse feeds, the photo-sensor signal processing unit is designed as a Schmitt trigger The output of which is connected to the inputs of the T-flip-flop and the one-shot, the outputs of which are the outputs of the photocopier system.

FIG. I shows a functional diagram of the device; in fig. 2 - photo mask; in fig. 3 is a diagram of the mutual arrangement of the photomask and the workpiece.

A device for automating an electric-spark doping contains a constant voltage source 1 (power supply) to which a voltage divider is connected, made on resistor 2 and photodiode 3. Parallel to photodiode 3, a capacitor 4 is connected and a Schmitt trigger 5 input, the output of which is connected to inputs T -trigger 6 and one-shot 7. The output of the T-flip-flop 6 is connected to the input of the control unit 8 for controlling the motor 9. The output of the one-shot 7 is connected to the control block 10 that controls the activation of the engine 11. Twi atel 9 through a gear mechanism 12 and the kinematic pair-screw nut 13 performs a working movement of the vibrator 14 to the y-axis. The engine 11 through the transmission mechanism 15 and the kinematic pair of screw-nut 16 moves the vibrator 14 to a new line along the axis OX.

The photomask 17 carries information about the contour of the workpiece 18 and is installed between the radiation source 19 and the photodiode 3, which is rigidly connected to the vibrator 14, which holds the electrode 20.

The photomask 17 is made of opaque material with a cut-out contour of the processed part of the product in full size.

5 The device operates as follows. Install the photomask 17 so that its position relative to the photodiode 3 corresponds to the position of the workpiece 18 relative to the strengthening electrode 20. The vibrator is set to

 the starting point of the treated surface of the product, while the photodiode 3, respectively, will occupy a position at point 21 on the photomask. Turn on the device in the network. From a source of constant voltage J2, no voltage is applied to the voltage divider consisting of resistor 2 and photodiode 3. Photodiode 3 is connected in the opposite direction to the constant voltage source. At point 21, photodiode 3 is above the cut-out part of the photomask, i.e. in the illumination zone, while the resistance of the photodiode is much less than the resistance of resistor 2 and the voltage on photodiode 3, illuminated by radiation source 19, lower than the Schmitt trigger voltage of the trigger and the signal him

output is zero. Regardless of the state of the T-flip-flop 6 and the control unit 8, the motor 9 is permanently turned on and moves the vibrator 14 along the axis of the control unit.

At the output of the one-shot 7, the signal is zero and the control unit 10 does not turn on the engine 11, thus the engine 9 uses the transmission mechanism 12 and the screw-nut pair 13 to move the vibrator 14 along the axis of the op-amp from the point

5 21 at point 22.

At point 22, photodiode 3 goes out of the illumination zone, and therefore its resistance increases; the voltage across it also increases and becomes greater than the trigger voltage of the Schmitt trigger 5;

0 while the signal at the output of the Schmitt trigger 5 goes from “O to“ 1. This causes a change in the state of the T-flip-flop 6, the control unit 8 will reverse the engine 9 and simultaneously the signal from the Schmitt trigger 5 will start the one-shot 7, which through the control unit 10 starts the engine 11; the latter, in turn, through the gear mechanism 15 and the kinematic pair of screw-nut shifts the vibrator to point 23. Engine run time 11,

 consequently, the magnitude of the displacement from point 22 to point 23 along the axis OX is determined by the one-shot 7. As a result of the reverse of the motor 9, the vibrator 14 will start moving to point 24, the photodiode 3 will enter the illumination zone, which will cause switching

5 Schmitt trigger 5 from state “1” and “O. The states of the T-flip-flop 6 and the one-shot 7 do not change. At point 24, the cycle is repeated.

Capacitor 4 prevents the Schmitt trigger 5 from being triggered in the event of vibrations at the light boundary. In this way, automation is performed to bypass the contour of the part of the product being processed.

The use of the invention eliminates the need to manually switch the direction of movement of the hardening electrode at the end of each turn and transfer it to the next line. The application of the proposed device will significantly expand the range of processed products and automate the circuit bypass while simplifying the device.

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Claims (1)

DEVICE FOR PHOTOCOPIER ELECTRIC SPARK ON WORKS containing a power source connected to the electrode-tool 'and parts, transverse and longitudinal feed engines with control units connected to the outputs of the photo-optical system, including a radiation source, photo mask, photosensor and signal processing unit of the photosensor, characterized in that, for the purpose of simplification of the device during spark doping, the photosensor signal processing unit is made in the form of a Schmitt trigger, the output of which is connected to the inputs of the T-trigger and one-shot, the outputs of which are outputs otoopticheskoy system. Figure 1