DE3206590A1 - Step-function current generator - Google Patents

Abstract

The invention relates to a step-function current generator by means of which a superelevated pull-in power can be supplied to a load, especially to a solenoid valve. The lower continuous power is, in contrast, emitted directly to the load from a voltage supply source. For this purpose, the step-function current generator contains a blocking oscillator circuit whose reverse pulses occurring at the output charge a downstream-connected capacitor to an increased voltage. On reaching a defined voltage on the capacitor, a switch in the load circuit is switched on. A disconnection device is furthermore connected to the load circuit, by means of which the blocking oscillator circuit is disconnected when the pull-in power is emitted to the load. <IMAGE>

Description

Surge generator

The invention relates to a surge generator for generating a increased instantaneous power for a controllable load.

In control engineering, switching operations are often required, to trigger an increased instantaneous power must be applied while to maintain a switching state, compared to the instantaneous power mentioned significantly reduced continuous output is sufficient. This is for example at the switching of solenoid valves is the case for their switching in an exemplary embodiment an instantaneous power of 8-12 watts must be applied during the holding power such a> 1 solenoid valve is only 1.5-2 watts ~. In many cases is what is required to control the solenoid valves or other loads DC voltage supply network prescribed or by other framework conditions given. It can happen that the specified DC voltage supply network although is able to maintain a switching state required To apply holding power, but that for triggering the switching process itself required increased current power not from the existing equal voltage Supply network can be obtained.

The invention is therefore based on the object of a current, surge generator that is to be connected to the existing DC voltage supply network and is able to deliver increased instantaneous power to the controllable load. At the same time, account should be taken of the fact that a required Continuous power from the existing one DC voltage source applied can be.

In the case of a surge generator, the task at hand is the one at the beginning mentioned type according to the invention solved in that to a voltage supply source a blocking oscillator circuit is connected, the output pulses of which are connected to a downstream Charge the current tone generator to a voltage that is higher than the input voltage, that when a defined voltage is reached on the capacitor, there is a load circuit arranged switch switched through and the instantaneous power from the surge capacitor is delivered to the load that the load circuit also has a disconnection device is connected in such a way that when the instantaneous power is delivered to the load, the blocking oscillation circuit switched off and a reduced continuous output to the load directly from the voltage supply source is delivered.

The load is often a solenoid valve whose Holding power can be applied by the existing DC voltage source, while the response power via the self-shutdown surge generator is related.

The load is in a preferred embodiment via a Thyristor controlled. The load circuit containing the thyristor and the load is preferably via a first diode to the Stromstonkondensator and via a second diode connected directly to the voltage supply source. Both diodes are polarized so that a current flow from the charged Stromstonkondensator or is made possible by the power supply source.

The blocking oscillator is preferably transistorized, then there is also the disconnection device preferably made of a transistor whose collector Emitter path parallel to the base-emitter path contained in the blocking oscillator Transistor is switched. The base electrode of the turn-off transistor is preferred controlled via a voltage divider, which is parallel to the load, so that the Switch-off transistor is always switched through when a current is transmitted through the load given size flows.

Between the surge capacitor and the control electrode of the thyristor is preferably a breakdown circuit that gerdioden one or more Tri each with a defined breakdown voltage these trigger diodes essentially determine the voltage on the capacitor, when they are reached, the thyristor is ignited and the required instantaneous power is generated is delivered to the load from the surge capacitor. With these trigger diodes In an advantageous embodiment, it can be four-layer diodes.

The invention and its further advantageous embodiment are intended in will be explained in more detail below on the basis of an exemplary embodiment.

With the circuit according to; the figure is at the circuit input a Glezhspannungsquelle UNETZ available, which is connected to the solenoid valve M in the load circuit a holding power of, for example, 2 watts can emit, but not the RnsorPnhkraft able to deliver from approx. 8-12 watts The to the poles of the DC voltage network connected diode bridge from the diodes D5, D6, D7, Dß ensures a reverse polarity protected Connection of the impulse generator to the network. The diodes D5-D8 are connected so that that regardless of the polarity of the network at the input terminal A of the surge generator positive potential is always applied, while the other input terminal B has reference potential is occupied.

The input terminal A is connected to the thyristor Thy via the diode D2 and the load circuit containing the solenoid valve M connected.- In this way the solenoid valve is consequently supplied with the required holding power, with the diode D2 disturbing reactions from the current generator to the circuit input safely prevented.

The resistor R2, which connects the input terminal A to the blocking oscillator circuit connects, is used to limit the current for this circuit.

The blocking oscillator or blocking converter circuit is known per se Way built. (Daranowski / Jankowski "Transistor circuits in pulse technology", -VEB-Verlag Technik Berlin, 1964, pages 179 ff) In the Xollektorzweig of a transistor T2, the winding L1 of an economy transformer is arranged across the resistor R2 is connected to input terminal A. The feedback winding L2 is in Base branch of the transistor T2, which in the illustrated circuit also has the serving as protection against overloads of the base-emitter path of the transistor T2 Includes diode D3 and resistor R8. Parallel to the series connection of the collector-emitter path of the transistor T2 and the winding L1 is on the one hand the capacitor C2 and on the one hand others the series connection Capacitor C1 and resistor RX, wherein the base current circuit of the transistor T2 to the connection between the capacitor C1 and the resistor R1 is connected.

The capacitor C2 ensures that the blocking oscillator despite the series resistor R2 can absorb the required peak current. The collector of the transistor T2 is via a diode that rectifies the return pulse of the blocking oscillator D4 connected to the surge capacitor C3, the one with these output pulses in the turn-off phases of the transistor T2 on one compared to the input voltage UE is charging excessively high voltage.

The capacitor C1 is activated when a DC voltage UNETz or UE is charged through the resistor R until the transistor T2 over the resistor Rd, the inductance L2 and the diode D3 become conductive and finally through the feedback winding L2 is driven up to saturation. By the kickback or output pulse when the transistor T2 is switched off, the capacitor cl charges negatively and discharges through the resistor R1 during the blocking phase of the transistor. Direct after the blocking of the transistor T2 must be in the magnetic field during the By controlling this transistor, stored energy can be dissipated. At the exit C of the blocking oscillator thus creates a voltage pulse with an excessive maximum voltage and there is a current FlnX from the inductance of the transformer through the opened Diode D4, which charges capacitor C3.

The process described is repeated periodically, so that the capacitor C3 via the rectifying diode D4 with the pulse pulses of the blocking oscillator is charged until a specified maximum voltage is reached.

If the blocking oscillator is dimensioned accordingly, a pulse repetition frequency is used of 20-25 kz at output C of the blocking oscillator. The capacitor C is with 3 these pulses are charged to a voltage of approx. 80 V, for example.

The discharge current path of the capacitor C3 leads via the current limiting resistor R and the Die D1 to the cathode-3 anode route of the thyristor Thy, which is in series to the solenoid valve to be switched N is arranged in the load circuit. The diode D1 prevents the capacitor C3 through 3 the direct connection of the thyristor is charged with the input terminal A.

However, the capacitor C can only discharge 3 when the Control electrode of the thyristor via the voltage breakdown path connected to the capacitor receives a trigger signal. This is the case when the voltage across the capacitor C3 exceeds the total breakdown voltage of the trigger diodes V1, V2. Then got there Via the trigger diodes V1, V2, which are, for example, four-layer diodes, and via the current limiting resistor R6 a trigger signal to the control electrode of the thyristor Thy, so that it becomes conductive and the capacitor C3 has an increased instantaneous power can deliver more than 8 watts to the solenoid valve> 1. The one between the control electrode and the cathode of the thyristor Thy connected resistor R7 serves as a bleeder resistor for the reverse current through the control electrode of the thyristor.

If the solenoid valve N responds when the increased instantaneous power is delivered, almost the entire capacitor voltage is applied to the solenoid valve N. That tension lies also at the voltage divider connected in parallel to the solenoid valve M from the resistors R4 and R5, then the one with the base electrode to the tap of the voltage divider connected transistor T1 is turned on. The collector-emitter path of transistor T1 is parallel to the base-emitter path of transistor T2, so that when the transistor T1 is switched on, the base potential of the transistor T2 essentially corresponds to the reference potential. The blocking oscillator consequently oscillates no more, and the. Capacitor C is no longer 3 recharged.

The further required holding power dz the solenoid valve M - at a holding voltage of z. BS. 6-9 volts and a holding current of approx. 120 mA is obtained directly from the network via diode D2. The holding voltage on the solenoid valve M is also sufficient to keep transistor T1 in the on state.

The diode D9 connected in parallel to the solenoid valve N serves as a quenching diode for energy never stored in the solenoid valve when it is switched off.

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Claims (8)

P a t e n t a n s p r ü c h e 1. Impulse generator for generation an increased instantaneous power for a controllable load, characterized in that that a blocking oscillator circuit is connected to a voltage supply source is whose output pulses a downstream surge capacitor (C3) charge a voltage that is higher than the input voltage, then when it is reached a defined voltage on the capacitor a switch (Thy) arranged in the load circuit switched through and the instantaneous power from the surge capacitor (C3) to the Load (M) is delivered that the load circuit also has a disconnection device (T1) is connected in such a way that when the instantaneous power is delivered to the load, the Blocking oscillator circuit switched off and a reduced continuous output to the load (M) is output directly from the power supply source. 2) surge generator according to claim 1, characterized in that the load (M) is an e-solenoid valve whose holding power - in contrast to the response power - can be applied directly from the existing power supply source. 3) surge generator according to claim 1 or 2, characterized in that that the load is controlled by a thyristor (Thy), and that the thyristor and the load circuit containing the load via a first diode (D to the surge capacitor (C) and via a second 3 diode (D2) directly to the voltage supply source (UE) an'ossen ast, both diodes are polarized so that a current flow from the charged capacitor (C3) or from xer voltage supply source in the pleasure circuit is made possible. 4) Stromstongenerator according to one of the preceding claims, characterized characterized in that a voltage divider (R4, R5) is connected in parallel with the load () whose voltage is connected to the base electrode of a switch-off transistor (T ) is connected, the collector-emitter path of the switch-off transistor (T) parallel to the base-emitter path of the one contained in the blocking oscillator circuit Transistor (T2). 5) Stromstongenerator according to one of the preceding claims, characterized characterized in that the collector of the blocking oscillator transistor (T2) has a Diode (D4) is connected to the surge capacitor (C3). 6j surge generator according to one of the preceding claims, characterized characterized in that between the surge capacitor (C3) and the control electrode of the thyristor (Thy is a breakdown circuit connected to one or more Contains trigger diodes with a defined breakdown voltage, so that this breakdown voltage of the diode (s) essentially determines the defined voltage across the capacitor which ignited the thyristor and the instantaneous power from the surge capacitor is delivered to the load. 7) surge generator according to claim 6, characterized in that the breakdown circuit has two trigger diodes (V1, V2) and a current limiting resistor (R6) contains. 8) surge generator according to claim 7, characterized in that; that the trigger diodes (V1, V2) are four-layer diodes.