RU175772U1 - DC UNINTERRUPTED POWER SUPPLY - Google Patents

Abstract

The utility model relates to the field of electronic instrumentation and can be used to create backup power sources for electronic devices. An uninterruptible power supply unit with a direct current is proposed, which contains a controller, a galvanic cell or a galvanic battery, an automatic connection unit for an uninterruptible power supply, a discharge current sensor of a galvanic cell or a galvanic battery . What is new is that the uninterruptible DC power supply unit further comprises a unit for comparing the voltage of the network, a unit for comparing the voltage of a galvanic cell or a galvanic battery, a temperature control unit for a galvanic cell or a galvanic battery, a voltage stabilizer-limiter of an electric network, a transceiver electrically connected to the controller, a stabilizer supply voltage of the controller and transceiver, while the output of the voltage stabilizer-limiter The mains supply is electrically connected to the input of the mains voltage comparison unit, the output of which is electrically connected to the first input of the unit for automatically connecting an uninterruptible power supply with direct current, the second input of which is electrically connected to the output of a galvanic cell or a galvanic battery, and the third input of the unit for automatically connecting an uninterruptible power supply is electrically connected to the first controller output, the first controller input is electrically connected to the output of the control unit the temperature of the galvanic cell or battery, the second input of the controller is electrically connected to the output of the voltage comparison unit of the galvanic cell or galvanic battery, the third input of the controller is electrically connected to the output of the discharge current sensor of the galvanic cell or galvanic battery, the input of which is electrically connected to the first output of the source automatic block uninterrupted DC power supply, the second output of which is electrically connected to the input of the unit is compared I voltage of the electrochemical cell or a galvanic battery and to an input of the controller supply voltage regulator and the transceiver, and the third output automatic connection uninterruptible power source unit DC is used as an output power to an uninterruptible DC power source. As a galvanic cell or battery, it is possible to use a galvanic primary cell or a galvanic primary battery. The technical result is to increase the reliability of an uninterruptible DC power supply. 1 ill.

Description

The utility model relates to the field of electronic instrumentation, namely to direct current power sources, and can be used to create backup power sources for electronic devices.

Known [1] is an uninterruptible power supply with direct current (the last five words are designated hereinafter - IBEC), containing a rectifier, galvanic secondary cell or galvanic secondary battery (the last seven words are indicated below - GVEB), which is used as a rechargeable battery, a current sensor in the charging circuit, controller, power supply, two comparators and two voltage dividers, while the inputs of the comparators are connected to the output of the current sensor and voltage dividers, and the outputs of the comparators are connected to the control inputs of the controller, the three outputs of which are connected to the control inputs of the rectifier.

The disadvantage of this IBEC is the low reliability due to the lack of control of the load current.

This disadvantage was eliminated in IBEP [2], which has expanded operational capabilities and ensures uninterrupted operation while maintaining optimal parameters of the operation of the GVEB when supplying consumers with direct current. IBEP [2] is the closest in technical essence and the achieved result and is selected as a prototype.

IBEP [2] contains n rectifiers, the control inputs of which are connected via an interface to the corresponding controller output, a load current sensor, a load voltage meter connected to the controller input, GVEB, which uses a rechargeable battery, a main and remote display panel, and a temperature control unit air connected to the fans. There is an IBEP automatic connection unit, the inputs of which are connected to the inputs of alternating voltage sources, and the power inputs of rectifiers and an air temperature control unit are connected to the output, and the rectifiers are divided into two units with a modular design, one of which performs the function of supplying the load, and the other function monitoring and maintaining the state parameters of the GVEB. The outputs of the load rectifiers are connected through the switch of the load rectifiers to the cathode of the diode connected to the input of the load voltage meter, and the anode of the diode through the switch of the rectifiers of the GVEB is connected to the outputs of the GVEB rectifiers. The diode cathode through the load current sensor is connected to the first input of the primary consumer protection unit, to the power input of the secondary consumer disconnect unit and to the input of the insulation control unit. The system has a charge current sensor and a GVEB discharge current sensor, turned on in the opposite direction, and the anode of the diode through both sensors is connected to the GVEB switch, to the inputs of the automation power supplies and to the input of the current sensors power supply. Another output of the GVEB switch is connected to the GVEB and to the input of the GVEB voltage meter. The current sensor power supply inputs are connected to the output of the current sensor power supply, and the automation power supply outputs are connected to the corresponding input of the controller, to the contact group and to the input of the GVEB charge mode block, the outputs of which are connected to the controller inputs, and the outputs of the contact group are connected to the second group of the block indicators and to the corresponding inputs of the controller, and the first group of indicators is connected to the corresponding outputs of the controller. The inputs of the control panels are connected to the controller output via the RS-485 interface.

The system includes meters of load currents, GVEB charge and GVEB discharge, the outputs of which are connected to the controller inputs, and the inputs to the corresponding outputs of sensors of load current, GVEB charge current and GVEB discharge current.

During operation and storage in GVEB, its level decreases due to the evaporation of the electrolyte, and due to the presence of impurities in the electrolyte and electrodes, the electrolyte concentration decreases, and therefore, the voltage and capacity of the GVEB decreases, which reduces the reliability of the IBEC. In this regard, a regular check of the level and concentration of electrolyte GVEB and replenishment of electrolyte losses is required.

The objective of this utility model is to increase the reliability of IBEC.

An IBEC is proposed that contains a controller, a galvanic cell or a galvanic battery (the last five words are designated below - BBB), an IBEP automatic connection unit, a BBB discharge current sensor.

IBEP further comprises a unit for comparing the voltage of the BBB, a unit for monitoring the voltage of the BBB, a stabilizer - a voltage limiter for the electric network, a transceiver electrically connected to the controller, a voltage stabilizer for the controller and transceiver, while the output of the stabilizer-limiter for voltage of the electric network is electrically connected with the input of the mains voltage comparison unit, the output of which is electrically connected to the first input of the IBEP automatic connection unit, from the second the input of which the BBB output is electrically connected, and the third input of the automatic uninterruptible power supply unit is electrically connected to the first output of the controller, the first input of the controller is electrically connected to the output of the BBB temperature control unit, the second input of the controller is electrically connected to the output of the BBB voltage comparison unit, the third input the controller is electrically connected to the output of the BBB discharge current sensor, the input of which is electrically connected to the first output of the IBEC automatic connection unit, second the first output of which is electrically connected both to the input of the voltage-voltage comparison block and to the input of the power supply voltage regulator of the controller and transceiver, and the third output of the IBEC automatic connection block is intended as the power output for the IBEC.

As a BBB, it is possible to use a galvanic primary cell or a galvanic primary battery.

Introduction to the IBEC of the unit for comparing the mains voltage, the output of which is electrically connected to the first input of the unit for automatically connecting the uninterruptible power supply, allows you to determine the moment the IBEC is turned on and give a signal to turn on the IBEC, and thus ensure uninterrupted power supply to the load and the reliability of the UPS.

The presence of the BBB voltage comparison unit, whose output is electrically connected to the second input of the controller, and the BBB temperature control unit, whose output is electrically connected to the first input of the controller, allows you to determine the voltage and temperature of the BBB and give a signal to turn on the UPS, which increases the reliability of the UPS.

The presence of a stabilizer - a voltage limiter of the electric network, the output of which is electrically connected to the input of the mains voltage comparison unit, eliminates the voltage surges of the electric network, and accordingly, eliminates damage to the IBEC elements and improves the reliability of the IBEC.

The presence of a transceiver electrically connected to the controller allows you to transfer IBEP status signals from the controller to an external device, which allows you to monitor the status of the IBEC, and thus increases the reliability of the IBEC.

The presence of a voltage stabilizer for the controller and transceiver, the input of which is electrically connected to the second output of the IBEC automatic connection unit, allows you to provide power to the controller and the transceiver and ensure reliable operation of the IBEC.

The electrical connection of the first output of the controller with the third input of the IBEC automatic connection unit, the BBB output is electrically connected to the second input, the connection of the third input of the controller with the output of the BBB discharge current sensor, the input of which is electrically connected to the first output of the IBEC automatic connection block, the second output of which electrically connected to the input of the BBB voltage comparison unit, the purpose of the third output of the IBEC automatic connection unit as the power output for the IBEC allows To automate the functioning of IBEC and increase the reliability of IBEC.

The possible use of a galvanic primary cell or battery as a BBB eliminates the need for regular check of the BBB electrolyte level and concentration and replenishment of electrolyte losses, which increases the reliability of the IBEC.

The figure shows a functional block diagram of IBEP.

The IBEP contains a block 1 for comparing the mains voltage (hereinafter referred to as block 1), a block 2 for comparing the voltage of a galvanic cell or battery (hereinafter referred to as block 2), a galvanic cell or battery 3, a block 4 for automatically connecting an uninterruptible power supply unit (hereinafter referred to as block 4), a block 5 temperature control of a galvanic cell or battery (hereinafter referred to as block 5), a sensor 6 of a discharge current of a galvanic cell or battery (hereinafter referred to as sensor 6), a stabilizer is a voltage limiter 7 of the electric network (hereinafter referred to as stabilizer 7), a voltage stabilizer 8 I controller and transceiver (hereinafter - Stabilizer 8), the transceiver 9, the controller 10.

The output of the stabilizer 7 is electrically connected to the input of block 1, the output of which is electrically connected to the first input of block 4, with the second input of which the output of the BBB 3 is electrically connected, and the third input of block 4 is electrically connected to the first output of the controller 10.

The first input of controller 10 is electrically connected to the output of block 5, the second input of controller 10 is electrically connected to the output of block 2, the third input of controller 10 is electrically connected to the output of sensor 6, the input of which is electrically connected to the first output of block 4, the second output of block 4 is electrically connected as with the input of block 2, and with the input of the stabilizer 8, and the third output of block 4 is intended as the output power for the uninterruptible power supply.

The controller 10 is electrically connected by a bus to the transceiver 9. On the power circuit, the stabilizer 8 is electrically connected to the transceiver 9 and the controller 10.

The unit 1 for comparing the voltage of the network is designed to compare the voltage of the electric network with a voltage equal to 21 V, and is made on a comparator 521CA3, a reference voltage source on a Zener diode D818E, electrolytic capacitors, relay coil REK 84V.

The BBB voltage comparison unit 2 is designed to compare the voltage of the BBB with a voltage of 18 V and is made on a 521CA3 comparator, a voltage reference source on a D818E zener diode.

As the BBB 3, the galvanic primary element 10S1PL026SHX is used.

The IBEP automatic connection unit 4 is intended for switching the electric network and the BBB 3 on the instrument of use and is made on the REC 84V relay.

The block of temperature control BBB is designed to generate a temperature signal BBB 3 and is made on a chip LM135AH.

The BBB discharge current sensor 6 is designed to generate a BBB 3 discharge current signal and is based on the MAX4080FASA + chip.

The voltage stabilizer-limiter 7 is designed to protect the uninterruptible power supply from voltage surges and is made on a BDX33CG transistor, a BZX85B30 zener diode and a DM-3-10-V inductor.

The voltage regulator 8 of the power supply of the controller 10 and the transceiver 9 is designed to supply a stabilized voltage to the controller 10 and the transceiver 9 and is made on a TEN5-2411WI microassembly.

The transceiver 9 is designed to transmit signals from the controller 10 to the application device. Performed on the chip SP3087EEN-L.

The controller 10 is designed to generate control signals IBEC and is executed on the ATMEGA8-16AU chip.

IBEP works as follows.

When the appliance is turned on, the supply voltage of the electric network is supplied to the stabilizer 7 and through it to block 1. If the voltage of the electric network is greater than 21 V, then block 1 does not provide an output signal to the first input of block 4. Block 4 does not connect power to the UPS.

If the voltage of the mains is greater than 29 V, the stabilizer 7 limits the voltage to 29 V.

If the voltage of the electric network is less than 21 V, then block 1 supplies an output signal to the first input of block 4. Block 4 connects the electric power to the UPS. In this case, from the second input of block 4 through the second output of block 4, the voltage from the BBB 3 is supplied to block 2.

Block 2 compares the voltage with the BBB 3 with a level of 18 V and gives a signal to the second input of the controller 10. The controller 10 provides a signal to the third input of the block 4. If the voltage of the BBB 3 is less than 18 V, then the signal from the controller 10 arriving at the third input of the block 4 , turns off block 4, which turns off the UPS.

If the voltage of the BBB 3 is greater than 18 V, then the signal from the controller 10 arriving at the third input of block 4 supports the on state of block 4, which supports the on state of the IBEC. In this case, the voltage of the BBB 3 is supplied from the second output of the block 4 to the stabilizer 8, which provides electric power to the transceiver 9 and controller 10.

In addition, from the third output of block 4, the output voltage of the BBB 3 is supplied to the application device within 18-29 V.

In the process of operation of the IBEC from the first output of block 4, a signal is sent to the sensor 6, which gives a signal to the third input of the controller 10. The controller 10 measures the discharge voltage of the BBB and the time of its flow and stores these parameters. The controller 10 transmits signals to the transceiver 9, which transmits information about the status of the UPS on the RS-422 interface to the application device.

In the process of operation of the IBEC from block 5, the temperature of the BBB goes to the controller 10, which gives a blocking signal to block 4 at a temperature of the BBB more than 85 ° C.

Thus, the created design of IBEC allows to increase the reliability of power supply to the load.

Sources of information used:

1. Patent RU 10295 U1, 1998-11-30, the entire document.

2. Patent RU 2533204 C1, 2014-02-14, the entire document (prototype).

Claims (2)

1. The uninterruptible DC power supply comprising a controller, a galvanic battery, an automatic connection unit for an uninterruptible power supply, a discharge current sensor of a galvanic battery, characterized in that the uninterruptible DC power supply further comprises a unit for comparing the mains voltage with the reference voltage of the network, a voltage comparing unit galvanic battery with its reference voltage, temperature control unit of a galvanic battery, stabilizer-limit voltage of the electric network, a transceiver electrically connected to the controller, a voltage stabilizer for the controller and transceiver, while the output of the voltage stabilizer-limiter of the electric network is electrically connected to the input of the voltage comparison unit with the mains voltage, the output of which is electrically connected to the first input of the automatic connecting an uninterruptible power supply, with the second input of which the output of the galvanic battery is electrically connected, and the third input the unit for automatically connecting an uninterruptible power supply unit is electrically connected to the first output of the controller, the first input of the controller is electrically connected to the output of the temperature control unit of the galvanic battery, the second input of the controller is electrically connected to the output of the voltage comparison unit of the galvanic battery with its reference voltage, the third input of the controller is electrically connected to the output a discharge current sensor of a galvanic battery, the input of which is electrically connected to the first output of the automatic switching on the uninterruptible power supply, the second output of which is electrically connected both to the input of the voltage comparison unit of the galvanic battery with its reference voltage, and to the input of the voltage regulator of the controller and transceiver, and the third output of the automatic connection of the uninterruptible power supply is intended as the power output for the source uninterruptible power supply. 2. An uninterruptible power supply according to claim 1, characterized in that a galvanic primary battery is used as a galvanic battery.

Images