SU1190353A1 - Device for checking electronic units of electronic-mechanical clocks - Google Patents

Abstract

A DEVICE FOR CONTROL OF ELECTRONIC ELECTRON-MECHANICAL HOURS CONTROL, containing a power source, a pulse generator, an amplifier, an indicator, control contacts, the first pole of the power source is connected to one of the control connection terminals, which is different in that , an additional power supply, switching unit and matching unit have been introduced into it. differentiating element and bridge circuit, in one of the arms of which a magnetic field sensor is connected, and an indicator and inputs of a differentiating element connected to the amplifier inputs are connected to the measuring diagonal, the second pole of the power supply is connected to the first input of the switching unit and matching the input of which is connected to the negative output of the diagonal of the power supply of the bridge circuit, the third and fourth inputs to the outputs of the amplifier, the fifth input to the first output i of the pulse generator, the positive output of the diagonal of the power supply neither the bridge circuit and the first pole of the power source, the sixth input — with the second output of the pulse generator, the seventh and eighth inputs — with the outputs of the auxiliary power supply; the first, second and third outputs of the switching and matching unit are connected to the second, third and fourth contacts respectively connection of the control object. : l e

Description

The invention relates to instrumentation and can be used in a time industry and consumer services sector for organizing the control of an electronic-mechanical watch.

The purpose of the invention is to increase the reliability of the control.

FIG. 1 shows a block diagram of the device; FIG. 2 is a circuit diagram of a switching and matching unit.

The device contains a power source 1, a pulse generator 2, an additional power source 3, a switching and matching unit 4, a bridge circuit 5, an indicator 6, a differentiating element 7, an amplifier 8 a magnetic field sensor 9, contacts 10-13 for connecting a controlled electronic unit (EB) 14, containing an oscillator 15 of the balance-spin type, in the gap of the magnets of which is located the coil 16 of the electronic unit with windings L1 and L2. Unit 4 for n4ytacation and matching (Fig. 2) contains a switch 17 to three directions, a key 18, subscripts 19-22.

The device works as follows.

Monitored EB is connected to the device through pins 10-13. At the same time, the minus power supply of the EB is connected to pin 10, to the contacts 15 and 12, respectively, the collector and the base of the VT EB transistor, to the pin 13 - positive power supply bus EV. In the initial state, the signals at the outputs of the switching and matching unit 4 and, consequently, the contacts 11-13 are absent (the switch 17 in this case is in position 1). To monitor the EB 14 into the gap between one of the poles of the magnets of the oscillator 5 of the balance-spiral type and the coil 16 of the EV, a magnetic field sensor 9, made on the basis of a magnetic diode, is installed. A magnetic field sensor 9 is included in one of the arms of a bridge circuit 5 formed of resistors and a magnetic diode, one type installed in sensor 9, and fed from a constant voltage source.

Control of EV 14 begins with a test of its functioning. For this, the switching and matching unit is set to this state.

when its third 11 output (switch 17 is in position 2) and, therefore, potential1D1al is supplied to contact 13 from the second output of power supply 1, as a result of which controlled EB 4 is under voltage, if EB EB 14 is normal, oscillations occur .15, which are observed visually. Simultaneously with the passage of the oscillator magnets over the magnetic field sensor, the unbalance of the bridge circuit 15 occurs, causing the indicator arrow to deflect. 6. If the oscillator 15 does not oscillate, elements of the DF 14 are checked. First, the winding L of the coil 16 is checked, for which the balance is deflected 90 ° and secured in this position. Then, the switching and matching unit 4 is brought into such a state when the signal from its second input goes to its first output (switch 17 in position 3) and, therefore, to pin 11 and collector of transistor VT controlled by EB 14. At second and the third outputs of the switching unit 4 and matching with the signals are absent. In this case, the winding L1 of the coil 16 of the controlled EV 14 turns on in parallel with the supply diagonal of the bridge circuit 5. If there is no break in the winding L1 of the coil 16, the current flowing through it creates a magnetic field that is sensed by the magnetic field sensor 9, resulting in a bridge imbalance 5, causing the arrow indicator deviation 6, the magnitude of which can be judged on the health of the winding L1 of the coil 16. Then, the health of the transistor VT EB 14 is checked, for which the switching unit 4 and agree The vanes are put into such a state when the signal from its first input goes to the third output, and the pulse output voltage is formed at the second output (switch 17 in position 4, the pulse voltage is generated for the closure time of switch 18). In this case, the monitored B 14 is under the voltage of the power supplied from the power source 1. With the closure of cam 18, an increase in the base current of the transistor VT occurs, which causes the transistor to be in good condition, an increase in the collector current, which, in turn, causes a change in the magnetic flux in the coil 16. This change is detected by the sensor 9 of the magnetic plate and causes the indicator arrow 6 to deflect, according to which the transistor is in good condition. Resistor 19 (Fig. 2) is designed to adjust the base current of the transistor VT. If the VT transistor is faulty, the indicator 6 arrow does not deviate. After checking the transistor, go to testing the bias resistor. For this, unit 4, the switching and matching is transferred to the state in which the output voltage of the additional source 3 voltage is transmitted to its first and second outputs (switch 17 in position 5), the negative output arrives at the second output is positive potentials, which are received respectively at the collector and the base of the transistor VT. In this case, the transition collector-base transistor. VT turns out to be locked and current is in. in a controlled EB, a bias resistor R flows through the circuit — winding LI of coil 16. The current flowing through the circuit creates a magnetic flux in coil I6, which is sensed by sensor 9 of the magnetic field. When this occurs, the unbalance of the bridge circuit 5 causes a deviation of the arrow of the indicator 6, judging from the value of which the bias resistor R is healthy. Resistor 20 (Fig. 2) ensures that the required current is set in the controlled circuit. After that, the capacitor C I is checked, for which the switching and matching unit 4 is put into a state in which the output signal of the generator 2 pulses goes to its second output (switch 17 in position 6) and, therefore, through pin 12 - to the base of the transistor VT. In the first and third outputs of the switching and matching unit 4, signals in this case are absent. Since the second output of the pulse generator 2 is connected to the first power supply source I and, therefore, through contact 10 to the negative power supply bus of the controlled EB 14, a pulse current that generates magnetic current flows through the CI circuit and the winding L1 of the coil 16 is sensed by magnetic field sensor 9. As a result, the indicator arrow 6 is deflected, indicating that the capacitor C1 is working. Resistor 21 provides the installation of the required current in a controlled circuit. Then, the test of the feedback circuit of the electronic unit consisting of the capacitor C2 and the winding L2 of the coil 16 is transferred. For this, the switching and matching unit 4 is put into a state where the signal from the outputs of the generator 2 of pulses goes to its second and third expenses (switch 17 in position 7) and, therefore, through contacts 12 and 13 to the base of the transistor VT and the positive power supply bus of the controlled EB 14, and in such a polarity that during the pulse the transition of the transistor emitter VT is locked . Under the influence of a pulsed current, the value of which is established using a resistor 22 in a controlled circuit, a current flows, which flows through the winding 2 of the coil 16 and creates a magnetic flux that is sensed by the magnetic field sensor 9. When the feedback circuit is intact, the indicator arrow 6 deflects. If the indicator does not deflect, the switching and matching unit 4 is put into a state where the signal from the output of the amplifier 8 goes to its second and third outputs (position 8 of the switch 17), consequently, through contacts 12 and 13 to the base of the transistor VT and the positive power supply bus of the controlled EB 14. This releases the balance, which was previously rotated at an angle of 90 relative to the starting position. Using a feedback circuit, consisting of a circuit capacitor C2 - winding 2 - sensor 9 of the magnetic bridge circuit 5 - differentiation element 7 - amplifier 8 $, the switching and matching unit 4 creates the conditions for oscillation of the balance of hours. If the oscillation is not possible 1 1903536, then this confirms the conclusion about the circuit failure capacitor C2 winding L2 of aux 16.

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Claims (1)

DEVICE FOR CONTROL OF ELECTRONIC-MECHANICAL CLOCK ELECTRONIC BLOCKS, containing a power source, a pulse generator, an amplifier, an indicator, connection contacts of a monitoring object, the first pole of a power source being connected to one of the connecting contacts of a monitoring object, characterized in that, in order to increase the reliability of control , it introduced an additional power source, a switching and matching unit, a differentiating element and a bridge circuit, in one of the arms of which a magnetic field sensor is included, and to the meter an indicator and inputs of the differentiating element, the outputs of which are connected to the inputs of the amplifier, the second pole of the power source is connected to the first input of the switching and matching unit, the second input of which is connected to the negative output of the power diagonal of the bridge circuit, the third and fourth inputs are connected to the outputs of the amplifier, the fifth input - with the first output of the pulse generator, the positive output of the diagonal of the power supply of the bridge circuit and the first pole of the power source, the sixth input - with the second output of the pulse generator, the seventh and the eighth inputs - with the outputs of the additional power source, the first, second and third outputs of the switching and matching unit are connected respectively to the second, third and fourth contacts of the control object. I 1190353 2