CS243105B1 - Central source's regulator connection for supply of remote consumers - Google Patents

Abstract

The procedure concerns the controller connection for the central power supply is supplying remote ones Appliance that controls the current control circuit two circuits of selection of maximum and central a power source connected to the power supply to which appliances are connected. The connection is particularly suitable for sources uninterrupted DC voltage in direct parallel operation with battery batteries and central sources in telecommunications objects. The essence of the solution lies in that. that a first input (3) of the first selection circuit (2) maximum, whose output is connected to the other the main controller input (7) is connected to the first sensor (18) the output of the central source (16), and a second input (4) of the first selection circuit (2) maximum is connected to the protective output of the controller (8), to the first input (6) the main controller (5) whose output it is connected to the current control circuit (1) Ija is connected to the control circuit (14) to drive the values go to the second input uuj the safety controller (8) is connected to the power supply (15) the reference voltage and the first the input (9) of the protective regulator (8) is second circuit output (12) connected (11) selecting the maximum whose inputs are linked with the other sensors (20) on the power supply Appliance Inputs (19)

Description

The invention relates to a controller for a central power supply supplying a remote appliance having a current control circuit, two maximum pick-up circuits, and a central power supply connected to a voltage distribution to which the appliances are connected.

The hitherto known connections for controlling the voltage of the central power supply for supplying remote appliances regulate the voltage at the output of the central power supply according to the data of one voltage sensor sensing the magnitude of the voltage in the voltage distribution, most often at the output of the central power supply.

The main drawbacks of the solutions known so far are that the voltage on the appliances differs from the voltage at the output of the central power supply by decreases in the voltage distribution and is therefore dependent on the current consumption of the appliances connected in the distribution between the central power supply and the individual consumers. these devices, the controller on the individual appliances monitored the central source monitored. When the current consumption of appliances decreases, the same voltage appears on them as at the output of the central source and if this voltage is higher than their maximum permissible voltage, there is a danger of their damage.

On the other hand, if the power supply of the central power supply is lowered so that dangerous overvoltage cannot occur when the demand is dropped, it may drop below the lower allowable limit at the most distant appliance at full current. · The voltage at the output of the central power supply is regulated according to the charging requirements or the conservation of the battery and the voltage on the appliances deviates uncontrollably from this voltage, depending on on the momentary subscription.

These drawbacks are eliminated by the circuit according to the invention, which consists in that the first input of the first peak pickup circuit, the output of which is connected to the second input of the main controller, is connected to a first voltage sensor at the output of the central power supply, the maximum is connected to the output of the protective controller, the first input of the main controller is connected, its output is connected to the current control circuit, the reference voltage control circuit is connected, the reference voltage source is connected to the second input of the the second circuit of maximum selection, its inputs are connected to the second voltage sensors on the power inputs of appliances.

The main advantages of the circuitry according to the invention are that the voltage at the selected consumers or the voltage distribution points is monitored by this connection and the voltage at the output of the central source is controlled so that the voltage at each appliance or the distribution point monitored does not exceed a given maximum value. This makes it possible, for example, in the case of a central DC power supply with the accumulator battery connected, to increase the voltages at the output of the central power supply above the maximum permissible voltage of the consumers at full current consumption and to charge the battery rapidly. In the event of a drop in the current consumption and thus a drop in the voltage distribution, the circuit according to the invention automatically reduces the voltage at the output of the central source so as not to exceed the maximum permissible voltage at the consumers.

In the following, the invention is explained in more detail by way of example with reference to the drawing.

An example of a circuit according to the invention is schematically shown in the attached drawing.

The output of the main controller 6 is connected to the current control circuit 7. The voltage setpoint control circuit 14 is connected to the first input 6 of the main controller 6 and the output of the first maximum selection circuit 2 is connected to the second input 2 of the main controller 6 243105

The first input 6 of the first peak selection circuit 2 is connected by a β first voltage sensor 18 at the output of the central voltage source 6. The output of the protection regulator g is connected to the second input 8 of the first maximum selection circuit 8. The reference voltage source 8 is connected to the second input 10 of the protection regulator 8 and the output 2 of the second maximum selection circuit signaling output 48 of the second maximum selection circuit 6, wherein the inputs of the second maximum selection circuit 11 are coupled to the second voltage sensors 24, at the power inputs of the consumers. The appliances 48 are connected in parallel to a voltage distribution 17 which is connected to a central voltage source 16.

The described circuit works in such a way that the main controller 6 regulates the voltage at the output of the central voltage source 6 according to the setpoint applied to the first input 6 of the main controller 6 from the voltage setpoint control circuit 6 and the actual voltage value supplied to the second input. From the first maximum selection circuit. This control is also provided by the current control circuit 6, to which the output from the main controller 6 is supplied and functions as a reference value of the output current of the central voltage source 6. Under normal conditions, when the voltage at any of the consumers 19 has not exceeded the maximum allowable value given by the reference voltage source 15, at the output of the first peak selection circuit 6 is an indication of the first voltage sensor 18 detecting voltage at the outputs of the central voltage source 16.

When the voltage at one ee of the appliances 19 exceeds the value given by the reference voltage source 15, the protective controller 8 increases the magnitude of its output which is applied to the second input 4 of the first maximum selection circuit 6 and The main regulator 8 regulates the voltage at the output of the central voltage source 6 by the action of the safety regulator g so that the voltage at any of the consumers 60 does not exceed the maximum permissible value.

The return to normal mode occurs after the auxiliary regulator g has reduced the magnitude of its output signal below the value of the actual value measured by the first voltage sensor 6 and the value measured by that first sensor 8 is supplied to the second input 6 by the voltage. This occurs after a voltage drop across the 19 cell consumers. as a result of an increase in power consumption and thus an increase in voltage drop at the voltage distribution 17, or after a decrease in the voltage at the output of the central power supply 16 as a result of the reduced output of the control voltage source 14. 13 of the second maximum selection circuit. At the output 12 of the expensive peak selection circuit 11 there is a signal corresponding to the selected largest of the voltages that are present on the consumers 19. The individual inputs of the second peak selection circuit 11 may have different amplification from each other. The order of maximum selection and comparison with the reference value can be reversed, that is, each input can be individually compared to the reference value. ^J '

The function of the signal output 13 of the second maximum selection circuit 11 is to signal a fault in the supervision of the voltage at one of the consumers 19, for example, an interruption or short-circuit of the leads. The signal output 13 of the second peak selection circuit 11 may be coupled to the voltage setpoint control circuit 14, which in the event of a supervision failure, will reduce the voltage setpoint at the output of the central voltage source 16.

The wiring of the controller according to the invention can be used for all sources from which the voltage is distributed by other lines to one appliance or to a plurality of appliances where it is necessary that the supply voltage does not exceed a certain predetermined value.

In particular, the circuitry according to the invention is suitable for use in uninterrupted direct current power sources in direct parallel operation with a accumulator battery and in central sources in telecommunication objects.

Claims (1)

SUBJECT OF THE INVENTION Controller connection for a central power supply supplying a remote appliance having a current control circuit, two peak selection circuits and a central voltage supply connected to the voltage distribution to which the appliances are connected, characterized in that the first input (3) of the first circuit (2) the maximum voltage selection, the output of which is connected to the second input (7) of the main controller (5), is connected to the first voltage sensor (18) at the output of the central voltage supply (16), and the second input (4) is connected to the output of the protective regulator (8), and to the first input (6) of the main regulator (5), the output of which is connected to the current control circuit (1), a voltage control circuit (14) is connected to the second input ( 10) a reference voltage source (15) is connected to the protective controller (8) and the output (12) of the second circuit (11) of the selection is connected to the first input (9) of the protective controller (8) the maximum of which inputs are connected to the second voltage sensors (20) on the power inputs of the appliances (19).