SU1718335A2 - Redundant dc power supply system - Google Patents

Abstract

Usage: uninterrupted power supply of radio equipment, where backup sources are batteries for the time of the failure of the primary network. Summary of the invention: the remote inputs of the system and network adjustable converter, as well as additional inputs for controlling the keys connected respectively to two- and three-diode non-linear circuits, and delay elements using RC circuits, automatically implement an algorithm for switching power sources. The system eliminated the undesirable subcharging of the battery in case of a good condition of the power supply network. 1 il.

Description

with

with

The invention relates to electrical engineering, can be used in systems of uninterrupted power supply of radio equipment, in which batteries are used as emergency sources for the time of power failure in the network, and is an improvement of the system according to author. N 1624601.

A known DC backup power system, comprising a mains adjustable voltage converter, the first output terminal of which is connected in parallel through a thyristor key and the first contact of the relay is connected to the first output terminal of the charger and the first terminal of the battery, the second terminal of which is connected to the second output a terminal of a network adjustable voltage converter, a second contact and a winding

relay, between the second terminal of the battery and the first output winding of the relay are connected in series the first key and the first nonlinear circuit consisting of three series-connected diodes, in series between the second terminal of the battery and the first terminal of the second closing contact of the relay are connected in series the second a key and a second non-linear circuit consisting of two series-connected diodes, as well as an OR element, a voltage-to-current converter and a third key, and the display output is STI PE network .guliruemogo voltage converter coupled to the second switch control input, and via an OR gate - a control input of the first switch, the common terminal of the first key and the first non-linear circuit coupled to the control input tiristornoVI

sh &

with

s yel

the key, the voltage-to-current converter input is connected in parallel to the second nonlinear circuit, and its output is connected to the control input of the third key connected between the first terminal of the battery and the second input of the OR element, the first and second terminals of the relay winding are connected respectively to the second terminal the second closing contact of the relay and the first terminal of the battery; the second output terminal of the charger is connected to the second terminal of the battery. This DC backup power system also contains a third non-linear circuit, formed from the parallel connection of a current limiting resistor and a diode, and a storage capacitor, and the charging device is made with a remote switching input, and a third non-linear circuit and a storage capacitor are connected in series and connected between the common terminal of the second key and the second nonlinear circuit and the second terminal of the relay coil, and the common terminal of the third key and the second input of the OR element with the remote switch on input of the charging device.

In addition, this DC backup power system contains a resistive divider, a reference voltage source, a fourth switch and an operational amplifier, and the network adjustable voltage converter is made with. measurement leads brought to the outside, the first vj of the resistive divider is connected to the second output terminal of the network regulated voltage converter and through the voltage source connected in series and the fourth key to the second output of the resistive divider, the middle output of which is connected to the non-inverting input of the operational amplifier, the output of which is connected to the inverting input and the second measuring output of the network controlled voltage converter, the first measuring the output of which is connected to its first output terminal, and the control input of the fourth key is connected to the common output of the third key and the second input of the OR element.

A disadvantage is the lack of operational reliability.

To turn off the output voltage of a known system, it is necessary to disconnect the battery at the same time as turning off the power supply or a little longer. To re-enable you,

the supply voltage of the system, you must first apply the network, and then connect the battery. Otherwise, if the specified sequence of actions is not followed (due to operator errors), a false battery connection to the output terminals takes place in the system, which reduces the battery capacity and, consequently, reduces the time of guaranteed power failure in the event of a power failure.

The purpose of the invention is to increase the operational reliability of the backup DC power system.

The drawing shows a schematic diagram of a DC backup power system.

The system contains a network adjustable voltage converter 1, the first output terminal of which through parallel connected thyristor switch 2 and the first closing contact of relay 3 are connected to the first output terminal of the charger 4 and the first terminal of the battery 5, the second terminal of which is connected to the second output charging device terminal 4 and with the second output terminal of the network regulated voltage converter 1, the second closing contact b and the winding 7 of the relay. Between the second terminal of the battery 5 and the first terminal of the winding 7 of the relay, the first switch 8 connected in series and the first nonlinear circuit 9 formed by three diodes connected in series. Between the second terminal of the battery 5 and the first output of the second closing contact 6 of the relay are connected in series the second switch 10 and the second non-linear circuit 11 formed by two series-connected diodes. The output indication of the health of the network adjustable voltage converter 1 is connected to the control input of the second key 10, as well as through the OR element 12 to the control input of the first key 8. The common output of the first key 8 and the first nonlinear circuit 9 is connected to the control input of the thyristor key 2. The input of the converter 13, the voltage to the current is connected to the second nonlinear circuit 11, and its output is connected to the control input of the third key 14 connected between the first terminal of the battery 5 and the second input of the OR 12 element. The first and

The second terminals of the relay coil 7 are connected respectively to the second terminal of the second closing contact 6 of the relay and the first terminal of the battery 5.

A third non-linear circuit 1 5 formed from a parallel connection of a current-limiting resistor and a diode, and a storage capacitor 16 are connected in series and connected between the common terminal of the second switch 10 and the second non-linear circuit 11 and the second terminal of the winding 7 of the relay, and the common terminal of the third switch 14 and the second input element OR 12 is connected to the remote input of the charging device 4.

The first output of the resistive divider 17 is connected to the second output terminal of the network regulated voltage converter 1 and through the series-connected source 18 of the reference voltage and the fourth switch 19c with the second output of the resistive divider 17, the middle output of which is connected to the non-inverting input of the operational amplifier 20, the output of which is connected to an inverting input and a second measuring output of a network regulated voltage converter 1, the first measuring output of which is connected to its first output the lemma, and the control input of the fourth key 19 is connected to the common output of the third key 14 and the second input element OR 12. Consecutively connected fifth key 21 and locking resistor 22 are connected between the second and first terminals of the battery 5, serially connected first threshold element, for example, zener diode 23, and the first current-producing resistor 24 are connected between the auxiliary control input of the first switch 8 and the first terminal of the battery 5. The second threshold element connected in series, for example Ortron 25, and the second current-setting resistor 26 are connected between the auxiliary control input of the second switch 10 and the first terminal of the battery 5i Series-connected second storage capacitor 27 and the current limiting resistor 28 are connected between the second terminal of the battery 5 and the Common pin terminal 21 and a locking resistor 22. The first diode 29 is connected between the common pin of the fifth key 21 and the locking resistor 22 and the common pin of the first threshold element 23 and the first current-supply resistor 24. The second di d 30 is connected between the common output of the second threshold element 25 and the second current supply resistor 26. The third diode 31 is connected between the common output of the second storage capacitor 27 and the current limiting resistor 28 and the common output of the first 5 threshold element 23 and the first current supply resistor 24. At the same time, the control input An additional key 21 and a remote input of the network adjustable voltage converter 1 are connected to the remote control input of the system.

The DC backup power supply system operates as follows.

In the absence of a signal (low level 5 n) at the remote control input, the redundant power supply system is in the on state. In this case, the network adjustable voltage converter 1 is located in a working state. The fifth key 21 is locked, the second storage capacitor 27 is charged through the locking resistor 22 on the voltage of the battery 5, the diodes 29-31 are locked. In normal operation mode (in the presence of AC mains voltage), the voltage at the output of the system is equal to the nominal output voltage of the network regulated voltage converter 1. Network adjustable

0 transformer 1 voltage generates a health indication signal (low level), which is fed to the control input of the second key 10 and through the element OR 12 to the control input of the first key 8. At the same time, the input transistors T1 and TZ are kept saturated, and the output transistors T2 and T4 of the second and first keys 10 and 8 are locked. The thyristor key 2 is locked, the winding 7 of the relay is de-energized, and the first and second make contacts 3 and 6 are open. The voltage drop across the second nonlinear circuit 11 is absent, the current at the output of the voltage converter 13 is zero, and the third key 14 is locked.

5 In this case, the fourth key 19 is locked. There is no voltage drop across resistor P2 resistor P2. The input and output voltages of the opamp 20 are equal to

0 second output terminal of the network regulated converter 1.

The current of the second measuring output of the network adjustable converter 1 is closed through the output of the operating

5 amplifier 20. Battery Torn battery 5 is disconnected from the output. Charger 4 provides charging of battery 5 and content mode.

When the AC mains voltage fails, the indication signal disappears.

serviceability of a network adjustable voltage converter 1. In this case, the input transistors T3 and T1 are locked, and the output transistors T4 and T2 of the first and second keys 8 and 10 are unlocked by currents specified by the additional inputs of the keys, respectively, of the first current supply resistor 24 through the first threshold element (Zener diode 23) and the second current load resistor 26 through the second threshold element (Zener diode 25). Through the unlocked first key 8, the voltage of the battery 5 is fed to the control input of the thyristor key 2 and unlocks it. The thyristor key 2 performs fast speeds without the output voltage of the battery 5 to the output terminals of the system.At the same time, the voltage of the battery 5 is supplied through the unlocked switch 8 to the first nonlinear circuit 9 and the relay coil 7 in series and through the unlocked second switch 10 to the third connected nonlinear circuit 15 and a storage capacitor 16. The storage capacitor 16 is charged almost to the voltage of the battery 5 through the current limiting resistor of the third non-linear circuit 15. Under the action of current, flowing through a coil 7, the contacts 3 and 6 of the relay are closed. In this case, the thyristor key is shunted by the closed contact 3 of the relay, as a result, the voltage drop between the battery 5 and the output terminals of the system is prevented and the thyristor switch 2 is locked. When the contact 6 is closed, the relay begins to flow through the serially connected second second key 10, the second non-linear circuit 11 and winding 7 of the relay, and the first non-linear circuit 9 is de-energized, because the voltage drop on the second non-linear chain 11 is less than the voltage drop on the first non-linear chain 9. Unit 13 converts the voltage drop on the second nonlinear circuit 11 into the current, which unlocks the third key 14. At the same time, the control input of the first key 8 through the element OR 12 and the input of the remote switch on the charging device 4 and the control input The fourth key 19 directly from the output of the third key 14 is supplied with a voltage locking the first key 8, keeping the charging device 4 in the off state and unlocking the fourth key 19.

Lree,. & Rdrgv network voltage generation appears signaling the health indication

(low) network regulated voltage converter 1, under the influence of which the second key 10 is locked and the first key 8 continues

kept locked through the element OR 12. However, the current continues to flow for some time through the series-connected second nonlinear circuit 11, the closed contact 6 and

0 the winding 7 of the relay from the charged storage capacitor 16 through the diode of the third non-linear circuit 15. As a result, the battery 5 remains connected to the output contacts of the system after

5 for the restoration of the network voltage for some time, during which the transients associated with the establishment of the output voltage of the network controlled converter 1 terminate.

The voltage of the unlocked third key 14 keeps the fourth key 19 closed. At the same time through the resistive divider 17 flows the current specified by the source

5 18 reference voltage.

The voltage across the resistor P2 of the resistive divider 17 is applied between the second output terminal of the network converter 1 and the noninverting input of the operational amplifier 20.

This voltage determines the magnitude of the excess voltage of the output voltage of the network converter 1 over the nominal value. Voltage drop

5, resistor P2 is selected such that when the mains voltage is restored, the output voltage of the network converter 1 exceeds the voltage of the battery 5.

0 "As a result, when the battery 5 is disconnected at the output of the mains voltage converter 1, there is a necessary amount of current to provide uninterrupted power supply to the load.

5 Disconnection of the battery 5 from the output terminals occurs when contacts 3 and 6 are opened due to the discharge of the accumulation capacitor 16. When the current through the second nonlinear circuit 11 stops, the current at the output of the voltage converter 13 also becomes zero, and the third key 14 is locked. In this case, the first key 8 remains locked due to the presence of a signal indicating the operability of the network adjustable transducer 1, the fourth key 19 is locked, and the charging device 4 is turned on. The flow of current through the resistive divider 17 is stopped, the voltage drop across the P-switch P2 becomes equal to zero, and the output voltage of the network controlled transducer 1 is again set to the nominal value. The battery of the torn battery 5 remains connected only to the charging device 4, which provides the charging of the battery 5 and the compensation of its leakage current.

Consider the process of shutting down the backup power system when the signal is applied (low level) to the remote control input.

The system operates on AC power.

In this case, the network adjustable voltage converter 1 turns off with the remote control input. In this case, the signal indicating the health of the network regulated voltage converter disappears, and the input transistors TK and T1 of the first 8 and second 10 keys are locked. However, the battery 5 is not connected to the output terminals of the system, because when a signal is applied (low level) to the remote control input, the fifth key 21 opens and, accordingly, acts through serially connected diode 2.9 and the port element 25 to the additional inputs of keys 8 and 10 holds the output transistors T4 and T2 of these keys locked. The second storage capacitor .27 is discharged through the current limiting resistor 28 and the open fifth key 21. At the same time, the current supply resistors 24 and 26 and the clamping resistor 22 flow through the open fifth key 21.

The system operates on a battery 5.

In this case, the battery pack

5 disconnected from the output terminals. When a signal is applied to the remote control input, the fifth key 21 is unlocked. In this case, the second key 10 is locked, as a result of which the winding 7 and the open contacts are de-energized

6 and 3 relays. .

Consider the process of turning on the backup power system when un-low-level from the remote control input.

The system has AC line voltage at the input.

In this case, the signal indicating the health of the converter 1 holding the key 8 locked and the output voltage of the converter 1 appears after a certain time determined by the soft start mode of the converter 1 after removing the signal from the remote input and the fifth key 21 is locked without delay simultaneously with the removal from the remote control input.

However, the battery 5 is not once again connected to the output terminals of the system for the time delay of the converter’s indication signal relative to the moment of removal of the remote signal, because the discharged second storage capacitor 27 through the diode 31 and the threshold element 23 continues to hold the key 8 locked. The constant charge time of the storage capacitor 27, determined by the resistances of the resistors 22, 24 and 26, is chosen such that before the occurrence of the health signal of the converter 1, the storage capacitor 27 does not have time to charge before unlocking the voltage of the threshold element 23, the voltages on the capacitor 27, the magnitudes of the unlocking of the threshold elements 23 and 25 last open, and the currents set by the resistors 24 and 26, respectively, flow through the saturated TZ and T1 transistors. 27 continues to be charged until the voltage of the battery 5 through the ficking resistor 22. As a result, the diodes 20, 30 and 31 are locked, and the storage capacitor 27 does not introduce inertia to the system when the mains voltage is lost.

There is no AC power at the system input.

In this case, a battery 5 is connected to the output terminals of the system. When the signal from the remote control input is removed, the fifth key 21 is locked. The storage capacitor 27 begins to charge with the current set by resistors 22, 24 and 27. When the voltage across the capacitor 27 reaches the value of unlocking the threshold elements 23 and 25, the latter are unlocked, and the additional inputs of the switches 8 and 10 start to flow to the additional control inputs and 26. Keys 8 and 10 open, voltage is applied to the winding 7 of the relay, and contacts 3 and 6 are closed.

Thus, in the proposed DC backup power supply system, it is possible to quickly turn off and turn on the output voltage with a single low-current control signal regardless of the mode (normal or emergency) of the system operation.

The technical and economic efficiency of the proposed system is to increase its operational reliability, since now the operator does not need to follow the sequence of his actions to switch on and off the output voltage, and it suffices to affect the remote control input of the system.

Claims (1)

Claims of the invention The system of backup power supply by direct current according to auth.St. No. 1624601, differing from the fact that, in order to increase operational reliability, the remote control inputs of the system and the network regulated voltage converter and additional control inputs of the first and second keys are introduced, as well as sequentially connected fifth key and the locking resistor between the second and first terminals of the battery, the first threshold element connected in series, for example, the zener diode, and the nerves and then the casing resistor between the auxiliary control input of the first cell Cha and the first terminal of the battery serially connected second threshold element, e.g. sta- a bilitron, and a second current resistor between the auxiliary control input of the second key and the first battery terminal, a second storage capacitor connected in series, and a current limiting resistor between the second battery terminal and the common pin of the fifth key and fixing resistor, the first diode between the common terminal n that key and fixing resistor and the common output of the first threshold element and the first current supply resistor, the second anode between the common output of the fifth key and the fixing the second diode between the common output of the second storage capacitor and the current limiting resistor and the common output of the first threshold element and the first to the current resistor, while the control input of the network adjustable voltage converter The terminal is connected to the remote control system input.