CS270687B1 - Connection of delay circuit - Google Patents

Abstract

The solution concerns the automatic charging of storage devices and solves the connection of a delay circuit with a double delay to mitigate the current surge in the distribution network when the tariff switch is switched on. The connection is made up of two emitter followers. A blocking transistor is connected to the emitter resistor of each follower. A discharge resistor, a discharge capacitor and a diode cathode are connected to its base. The discharge resistor with the discharge capacitor forms the time base for the required delay. The diode and the edge resistor, which are connected to the base of the blocking transistor, are used to quickly discharge the charging capacitor during a short-term power outage.

Description

The invention relates to the charging of storage heat consumers and solves the connection of a delay circuit with a double delay for the mitigation of a current shock in the distribution network, when the rate switch is closed.

Mechanical time relays are known which, after closing the rate switch, gradually connect the individual groups of storage heat consumers to the distribution network, thus mitigating the current shock. The disadvantage of brightness relays is that they are faulty and sensitive to shocks. They often switch due to accidental shocks, for example when passing heavy trucks near a heated building.

Bimetallic time relays are also known, which are cheaper and less faulty. These relays are also activated when the rate switch is closed. The relay includes a resistor which heats the bimetallic switch when the rate switch is closed. The disadvantage of bimetallic relays is that they do not fulfill their function in the event of a short-term power failure. Due to the thermal inertia of the bimetal, the contacts will not open when the distribution network is switched off for a short time. After switching on the mains again, the bimetal remains closed without ensuring the necessary delay when connecting the individual groups of storage appliances. This leads to an unwanted current surge.

These shortcomings are eliminated by the connection of a double delay delay circuit for the storage appliances according to the invention. The circuit is made up of two known emitter monitors. The positive input terminal of the circuit is connected to the first terminal of each biasing resistor connected in series and the collector of each tracking transistor. The base of each tracking transistor is connected to the center terminal of a pair of series-connected bias resistors and to one pole associated with a coupling capacitor. The emitter of each tracking transistor is connected via its associated eaistor resistor to the circuit breaker. The negative input terminal of the circuit is connected to the second terminal of the corresponding pair of series-connected bias resistors. The input signal terminal of the connection is connected to the second pole of the coupling capacitor. The essence of the invention lies in the fact that the first input signal terminal of the circuit is connected to the emitter of the second tracking transistor and to the emitter of the second blocking transistor. The collector of the second blocking transistor is connected to the collector of the first blocking transistor and to the positive pole of each discharge capacitor. The negative pole of each discharge capacitor is connected to the base of the associated blocking transistor, to the first terminal of the associated discharge resistor and to the cathode of the associated diode. The anode of each diode is connected to the first terminal of the assigned protection resistor. The second terminal of each protection resistor is connected to the second terminal of the associated discharge resistor and to the circuit breaker. The second output signal terminal of the circuit is connected to the emitter of the first tracking transistor and to the emitter of the first blocking transistor.

The arrangement according to the invention reliably ensures the connection of a selected group of storage heat consumers to the electrical distribution network with a selected delay. Its operation is not affected by shocks or short-term shutdown of the distribution network. X after a short-term power failure, the connection works in the same way as when the rate switch is closed. The delay time can be selected according to the size of the discharge capacitor and the discharge resistance. By connecting additional delay circuits, more than two delays can be used. The connection is simple and inexpensive. It is made of commonly available components.

An example of an arrangement according to the invention is shown schematically in the attached drawing ee by two delay circuits.

CS 270 687 Bl

The connection is made up of two identical delay circuits, which differ only in the values of the discharge resistors 5.1 and 5.? and the values of the discharge capacitors 7.1 and 7.2. The first circuit, the components of which are indicated by a dot in the reference numeral χ, has a shorter delay, the second circuit, the components of which are indicated by the number 2 after the dot in the reference numeral, has a longer delay. The delay of the first circuit is 330 seconds. The delay of the second circuit is 660 seconds. An emitter tracker is known in front of each delay circuit. The positive input terminal 041 of the circuit is connected to the positive pole of the first discharge capacitor 7.1. with the collector of the first blocking transistor 10.1. with the collector of the first tracking transistor 9.1. with the first terminal of the first pair of series-connected bias resistors 2.1. 3.1. with the positive pole of the second discharge capacitor 7.2. with the collector of the second tracking transistor 9.2. with the collector of the second blocking transistor 10.2 and with the first terminal of the second pair of series-connected bias resistors 2.2. 3.2. The negative input terminal 042 of the circuit is connected to the second terminal of the first pair of series-connected bias resistors 2.1, 3.1 and to the second terminal of the second pair of series-connected bias resistors 3.2. 2.2.

The first signal output terminal 045 of the circuit is connected to the emitter of the first monitor transistor 9.1 to the emitter of the first blocking transistor 10.1 and to the first terminal of the first emitter resistor 4.1. The second signal output terminal 046 of the circuit is connected to the emitter of the second monitor transistor 9.2. with the emitter of the second blocking transistor 10.2 and with the first terminal of the second emitter resistor 4.2.

The input signal terminal 047 of the circuit is connected to the first pole of the first coupling capacitor 1.1 and to the first pole of the second coupling capacitor 1.2. The second pole of the first coupling capacitor 1.1 is connected to the center terminal of the first pair of series-connected bias resistors 2.1. 3.1 and with the base of the first tracking transistor 9.1. The second pole of the second coupling capacitor 1.2 is connected to the middle terminal of the second pair of series-connected bias resistors 2.2. 3.2 and with the base of the second tracking transistor 9.2. Switch terminal 048 connection - is connected to the second terminal of the first emitter resistor 4.1. with the second terminal of the first discharge resistor 5.1 «with the second terminal of the first protective resistor 6.1« with the second terminal of the second emitter resistor 4.2. with the second terminal of the second discharge resistor 5.2 and with the second terminal of the second protective resistor 6.2. The first terminal of the first protection resistor 6.1 is connected to the anode of the first diode 8.1. The cathode of the first diode 8.1 is connected to the first terminal of the first discharge resistor 5.1, to the base of the first blocking transistor 10.1, and to the negative pole of the first discharge capacitor 7.1. The first terminal of the second protection resistor 6.2 is connected to the anode of the second diode 8.2. The cathode of the second diode 8.2 is connected to the first terminal of the second discharge resistor 5.2, to the base of the second blocking transistor 10.2 and to the negative pole of the first discharge capacitor 7.2.

The individual input and output connection terminals are connected to the external device as follows. The positive input terminal 041 of the connection is connected to the make contact · of the auxiliary relay of the rate switch. The negative input terminal 042 of the circuit is connected to the NC contact of the rate switch auxiliary relay. The first signal output terminal 045 of the connection is connected via control circuits to the first group of storage appliances with a shorter delayed switching on after closing the rate switch. The second signal output terminal 045 of the connection is connected via control circuits to a second group of storage appliances, which are connected to the distribution network with a longer delay after the rate switch is closed. The input signal terminal 047 of the connection is connected to a controller which controls the start of switching and the switching time of the battery appliances according to the outdoor temperature. The lower the outdoor temperature, the longer the charging time for the storage appliances.

CS 270 687 Bl

The connection works like this. Before the low rate is switched on, the center contact of the auxiliary relay of the rate switch is connected to its NC contact. This connects the switch terminal 048 of the circuit to its positive input terminal 041. The voltage based on the two blocking transistors 10.1 and 10.2 is higher than the voltage based on the associated monitoring transistors 9.1 and 9.2. Both monitor transistors 9.1 and 9.2 are disabled and do not pass the signal from the input signal terminal 047 of the connection to the signal output terminals 045 and 046 of the connection. By switching on the rate switch, the central contact of the auxiliary relay closes with its switching contact, thus connecting the switch terminal 048 to its negative input terminal 042. The first discharge capacitor 7.1 is charged via the first discharge resistor 5.1 and charging via the second discharge resistor 5.2. second discharge capacitor 7.2. The voltage on the basis of the first blocking transistor 10.1 and on the basis of the second blocking transistor 10.2 gradually decreases. When the voltage based on the first blocking transistor 10.1 is less than the voltage based on the first tracking transistor 9.1, the first tracking transistor 9.1 is unlocked. The input signal passes from the input signal terminal 047 of the connection via the first coupling capacitor 1.1 based on the first monitor transistor 9.1 and from its emitter to the first signal output terminal 045 of the connection and from there via the control circuits not shown in the drawing with a shorter delay. The delayed release time of the input signal is determined by the values of the first discharging resistor 5.1 and the first discharging capacitors 7.1. the second tracker transistor is unlocked 9.2. The signal from the input signal terminal 047 of the circuit passes through the second coupling capacitor 1.2 based on the second monitor transistor 9.2 and from its emitter to the second output signal terminal 046 of the circuit. This signal switches the second group of storage appliances with a longer delay. In the event of a short-term mains failure, the first discharge capacitor 7.1 is rapidly discharged via the first diode 8.1 and via the first protective resistor 6.1 «, so that the circuit is ready to connect the first group of appliances β with the required delay after reconnecting the mains. Likewise, the second discharge capacitor 72 is discharged via the second diode 8.2 and via the second protective resistor 6.2. Similarly, the connection works and prepares for its operation when the rate switch is switched off.

The invention is used in the automatic charging of storage heat appliances, for delayed connection of individual groups of appliances to the distribution network.

Claims (1)

OBJECT OF THE INVENTION A double delay delay circuit circuit formed of two emitter monitors, wherein the first positive input terminal of the circuit is connected to the first terminal of each pair of series-connected bias resistors and to the collector of its associated monitor transistor, the base of which is connected to the center terminal of the associated pair of series-connected bias resistors. , with one pole of the associated coupling capacitor, the emitter of each tracking transistor is connected via an associated emitter resistor to a circuit breaker terminal, the negative input terminal of which is connected to the second terminal of each pair of series connected bias resistors and the input signal terminal of the circuit is connected to the second pole of each coupling. capacitor, characterized in that the first input signal terminal / 045 / connection is connected to the emitter of the first tracking transistor /9.1/ and to the emitter of the first blocking transistor /10.1/, the collector of which is connected to the collector of the second blocking transistor and the positive pole of each discharge capacitor /7.1, 7.2 /, the negative pole of which is connected to the base of the assigned blocking transistor /10.1, 10.2 /, to the first terminal of the assigned discharge resistor /5.1, 5.2 / and to the cathode of the assigned diode /8.1, 8.2 /, the anode of which is connected to the first terminal of the associated protective resistor /6.1, 6.2 /, the second terminal of which is connected to the second terminal of the associated discharge resistor /5.1, 5.2 / and to the switch terminal / 048 / connection, the second output signal terminal / 046 / is connected to the emitter of the second tracking transistor /9.2/ and to the emitter of the second blocking transistor /10.2/.