SU1487148A2 - Current boosting device - Google Patents

Description

The invention relates to electrical engineering and can be used to force a current in electromagnetic actuators. The purpose of the invention is to improve the reliability of the device forcing current by dispersing the dissipated power due to the discharge current of an inductive load. The device contains an inductive load 1 connected to the power source 2 through the first diagonal of the electric bridge, containing the first and second diodes 3 and 4 in the cross-arms, the capacitor 5 in the diagonal, the control key 6 and the discharge key 7 in the other cross-arms of the bridge. The goal is achieved by introducing into the proposed device the current limiting resistor 9 in series with diode 4 and introducing the third 10 and fourth 11 diodes, with diode 4 being connected counter-parallel to the input circuit of key 7, and diode 11 between the output of the capacitor 5 connected to the key 7 and the source 2 power supply. 1 il.

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The invention relates to electrical engineering, is intended for boosting the current in the control devices of electromagnetic actuators, such as relays, electromagnets, electromagnetic couplings, printers and others, and is an improvement of the invention auth.St., No. 839023.

The purpose of the invention is to increase reliability by dispersing the dissipated power due to the discharge current of an inductive load.

The drawing shows a circuit diagram of the device.

The device contains an inductive load 1 connected to the power source 2 through the first diagonal of the electric bridge containing the first diode 3 and the second diode 4 in the cross-arms, closing the charge circuit of the boost capacitor 5 included in the second diagonal of the bridge, and in the other cross-arms the control key 6 and the bit key 7, closing the circuit of the forced inductive load. In this case, the control input of the bit key 7 through the current-limiting resistor 8 is connected to the pole of the power source 2 connected to the common bus, the second diode 4 is connected to the junction point of the control key 6 with the power source 2 through an additional current-limiting resistor 9 the key 7 is connected to the third diode 10, and the output of the capacitor 5 connected to the discharge key 7 is connected through the fourth diode 1 1 which is connected back to the pole of the power supply 2 connected to the inductive load 1.

The device works as follows.

At. switching on the power supply 2, the charging current of the capacitor 5 flows through the circuit 2-1-3-9, branching further along two parallel circuits 4-7 and 10-8, the magnitude of the charging current and

_; therefore, the degree of excitation of the inductive load 1 is limited by the resistances of the resistors 8 and 9.

In this case, the resistance of the resistor 8 is chosen somewhat larger than in the known device so that the equivalent resistance

with. considering the shunting effect of the resistor 9 remains the same as in the known device, the voltage on the input circuit of the discharge Clic 7 (i.e. at the base-emitter junction of the transistor) is limited by the voltage on the open diode 10. At the end of the transition process, the voltage on the capacitor 5 is set equal to the voltage of the power source 2.

When the key 6 is closed, the key 7 also closes due to the discharge of the discharge current of the capacitor 5 through the circuit 6-5-8 through the input circuit (basic emitter junction) of the key 7 limited by the resistance of the resistor 8. Diode

4 prevents condenser discharge

5 through a resistor 9. The inductive load 1 is applied to the total voltage of the capacitor 5 and the power source 2, providing a forced increase of the excitation current.

At the end of the process of discharge of the capacitor 5 bit key 7 is closed, and the load 1 is connected to ^- power supply 2 via diode 3 and key 6.

When the key 6 is opened, the excitation current of the inductive load 1 fades out gradually. When this, m, under the action of the voltage of the EMF of self-induction and the voltage of the power supply 2, the capacitor 5 is charged. At the first moment after the switch 6 is opened, when the EMF of the induction load 1 exceeds the voltage value of the power supply 2, the discharge current of the inductive load 1 branches off to low the circuit closed by the fourth diode 11. The remaining part of the discharge current is additionally branched in two parallel circuits 4-9 and 10-8, while the voltage applied to them is limited at the voltage level of the source 2 of the pit tions.

The diode 11 performs at the initial stage of the discharge of inductive load 1 the role of the fixing diode. In addition, the diode 11 contributes to the dispersion of the dissipated power due to the discharge of the inductive load 1, the diode 11 closes the self-induced EMF to the capacitor 5, ensuring its charge without energy consumption from the power source. This increases the efficiency of the device.

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Diode 10 limits switching emissions (and thus protects the input circuit of key 7 from hazardous reverse voltages) and at the same time contributes to the dispersal of the dissipated power due to the discharge of an inductive load, connecting in parallel circuit 4–9 another 10–8 circuit whose elements carry ₁₀ double functional load.

Thus, increasing the current to force the device reliability caused by a decrease in the probability of local heating elements ₁₅ roystva Device for dispersal due to power dissipation due to the discharge current of the inductive load.

Claims (1)

Claim The device forcing the current auth.St. No. 839023, about t of l and h and about 48 6 By the fact that, in order to increase reliability by dispersing the dissipated power due to the discharge current of an inductive load, an additional current limiting resistor and the third and fourth diodes are introduced, and an additional current limiting resistor is connected between the second diode and the junction point of the control key with the power source, the third diode is connected counter parallel to the input circuit of the bit key, and the fourth diode is connected between the capacitor lead connected to the bit key and the ind pin active load associated with the power supply, in reverse connection with respect to the latter.