RU129263U1 - DEVICE FOR TESTING SECONDARY POWER SOURCES - Google Patents

Abstract

1. A device for testing secondary power supplies, containing a primary power source, a tested secondary power source and a recovery type load device unit, which includes a pulse voltage converter, an adder-amplifier, a reference voltage source, a current sensor in which the output is positive and negative secondary power sources are connected respectively to the input positive and negative terminals of the load device, the power input of the current sensor is is the positive input terminal of the load device, the negative input terminal of the pulse voltage converter is the negative input terminal of the load device, the output of the reference voltage source is connected to the addition input of the amplifier-adder, the output of the adder amplifier is connected to the control input of the pulse voltage converter, characterized in that the primary source of electricity made in the form of uninterruptible power supply, providing a double energy conversion mode, and into a block n of a recovery-type load device, the first and second decoupling diodes are additionally introduced, and the uninterruptible power supply includes a rectifier, a charger, a battery, terminals for connecting an external battery, a converter, while the rectifier input terminals are an uninterruptible power supply input and are connected to an ac mains supply current, the positive and negative terminals of the rectifier are connected respectively to the positive and negative input terminals of the charger

Description

A device for testing secondary power supplies relates to a converting technique and can be used in ground-based testing of spacecraft power systems.

A device is known (RF patent for utility model No. 75755, IPC G01R 31/02, G01R 31/40) for testing DC power supplies with the return of consumed electricity to an industrial electrical network containing several load modules connected in parallel to the power supply system under test, and external control controller. The design of such a device is based on the inverter driven by the network, and there is a need to coordinate the output voltage of the device and the voltage of the alternating current network, which leads to more complicated control circuits, a decrease in the energy utilization coefficient, and a deterioration in overall dimensions.

Closest to the utility model is a device (RF patent No. 2187192. IPC Н02М 3/07, Н02М 3/10) for testing DC power supplies with energy recovery in a direct current network containing a primary power source, a tested secondary power source, a load unit devices, which include a current regulator, a DC-DC converter, a storage capacitor, a current sensor, and series-connected transistors are connected to the output of the secondary power source polar current regulator, allowing impingement simulate and reset the load current, current sensor and the inverter input DC current limiting transistor allocated to current controller output and returning the energy consumed in the DC link, test feed secondary power source.

In this device, the mains voltage and the output voltage of the DC / DC converter are added up, there is a need to use an additional voltage regulator that maintains the supply voltage of the tested secondary source at a constant level, which in turn leads to a decrease in energy efficiency, more complicated control circuits, and worsening of overall dimensions . In addition, due to the possible disappearance of the AC mains, it is impossible to conduct long-term life tests of secondary power sources.

The objective of the utility model is to increase the energy efficiency, as well as expanding the functionality and simplifying the device.

The problem is solved in that a device for testing secondary power supplies, containing a primary power source, a tested secondary power source and a recovery unit load unit, which includes a pulse voltage converter, an adder-amplifier, a reference voltage source, a current sensor in which the output the positive and negative terminals of the secondary power source are connected respectively to the input positive and negative terminals of the load unit devices, the power input of the current sensor is the positive input terminal of the load device block, the negative input terminal of the pulse voltage converter is the negative input terminal of the load device block, the output of the reference voltage source is connected to the addition input of the amplifier-adder, the output of the adder amplifier is connected to the control input of the pulse voltage converter , according to the technical solution, the primary source of electricity is made in the form of an uninterruptible power supply, about providing a double energy conversion mode, and the first and second decoupling diodes are additionally introduced into the recovery unit of the recovery device, the uninterruptible power supply comprising a rectifier, a charger, a battery, terminals for connecting an external battery, a converter, while the input terminals of the rectifier are an input uninterruptible power supply and connected to the AC mains, the output plus and minus terminals of the rectifier are connected to responsibly with the positive and negative input terminals of the charger, the output positive terminal of the charger is connected to the positive terminal of the battery, to the input positive terminal of the converter, and to the positive terminal designed to connect the external battery, the output negative terminal of the charger is connected to the negative terminal of the battery batteries, to the input negative terminal of the converter, and to the negative terminal, designed to connect an external battery, e converter terminals are an output of an uninterruptible power supply and are connected to the input terminals of the tested secondary power supply, the power output of the current sensor of the unit of the load device is connected to the input positive terminal of the pulse voltage converter, the information output of the current sensor is connected to the subtraction input of the amplifier-adder, the output positive terminal of the pulse the voltage converter is connected to the anode of the first decoupling diode, the output negative terminal of the pulse converter The voltage separator is connected to the anode of the second decoupling diode and is the output negative terminal of the unit of the load device, the output positive and negative terminals of the unit of the load device are connected respectively to the positive and negative terminals of the uninterruptible power supply, designed to connect an external battery.

A device for testing secondary power supplies additionally contains (n-1) blocks of the recovery device load device, all n blocks being interconnected.

The blocks of the recovery-type load device are connected in parallel, while the input plus and minus terminals of all the blocks of the recovery-type load devices are connected in parallel and connected to the output plus and minus terminals of the secondary power supply, and the output plus and minus terminals of all the blocks of the recovery type load devices connected in parallel with the plus and minus terminals of the uninterruptible power supply, designed for I connect an external battery.

The blocks of the recovery-type load device are connected in series, while the input plus and minus terminals of all the blocks of the recovery-type load devices are connected in parallel and connected to the output plus and minus terminals of the secondary power supply, and the output negative terminal of the first block of the recovery type load device is connected to output positive terminal of the n-th block of the recovery type load device, output positive terminal of the first th unit load device regenerative type, and the output terminal minus n-th unit load device regenerative type are connected respectively to the positive and negative terminals of an uninterruptible power supply intended for connection of external battery

The blocks of the recovery type load device are interconnected in series-parallel, while the input plus and minus terminals of all the recovery type load devices are connected in parallel and connected to the output plus and minus terminals of the secondary power supply, and the output, plus and minus terminals to the load blocks recuperation-type devices are connected in series and form a sequential assembly of blocks of the regenerative loading device second type, ie the negative output terminal of the first block of the recovery type load device of the first sequential assembly is connected to the positive output terminal of the k-th block of the recovery type load device of the first sequential assembly, and n / k consecutive assemblies of blocks of the recovery type load device are connected in parallel, i.e. the positive output terminals of the first blocks of all serial assemblies of the recovery type load device are connected to the positive terminal of the uninterruptible power supply intended for connecting an external battery, the negative output terminals kx of the blocks of all serial assemblies of the recovery type load device are connected to the negative terminal of the uninterruptible power supply unit external battery.

The technical result of the utility model is to increase the energy efficiency, as well as expanding the functionality and simplifying the device.

The utility model is illustrated in diagrams and graphs.

Figure 1 presents the structural diagram of a device for testing secondary power supplies.

Figure 2 - parallel connection of the blocks of the load device.

Figure 3 - serial connection of the blocks of the load device.

Figure 4 - series-parallel connection of the blocks of the load device.

Figure 5 shows the current-voltage characteristic of the battery and the external characteristic of the unit load recovery device type.

The test device consists of an uninterruptible power supply 1, which contains a rectifier 2, a charger 3, a rechargeable battery 4, a converter 5. An uninterruptible power supply 1 has terminals 17, 18 for connecting an external rechargeable battery in parallel with the built-in rechargeable battery 4. The output is positive and negative the rectifier 2 terminals are connected respectively to the input positive and negative terminals of the charger 3. The positive output terminal of the charger 3 is connected to the positive battery terminal hydrochloric battery 4, positive input terminal of the converter 5 and the positive terminal 17 for an external battery. The output negative terminal of the charger 3 is connected to the negative terminal of the battery 4. with the input negative terminal of the converter 5 and with the negative terminal 18, for connecting an external battery. The input terminals of the rectifier 2 are the input terminals 14, 15, 16 of the uninterruptible power supply 1 and are connected to an AC network. The output terminals of the converter 5 are the output terminals 19, 20 of the uninterruptible power supply 1 and are connected to the input terminals of the tested secondary power source 6. The recovery type load device unit 7 contains a current sensor 8, a reference voltage source 9, an amplifier-adder 10, a pulse voltage converter 11 , first 12 and second 13 decoupling diodes. The input positive terminal 21 of the block of the load device 7 is connected to the power input of the current sensor 8, the power output of which is connected to the input positive terminal of the pulse voltage converter 11. The negative input terminal of the pulse voltage converter 11 is the negative input terminal 22 of the block of the load device 7. Information output of the current sensor 8 is connected to the subtraction input of the amplifier-adder 10, the output of the reference voltage source 9 is connected to the input of the addition of the amplifier-adder 10. The output of the amplifier-adder 10 connected to the control input of the pulse voltage converter 11. The positive output terminal of the pulse voltage converter 11 is connected to the anode of the first decoupling diode 12, the cathode of which is connected to the cathode of the second decoupling diode 13 and is the positive output terminal 23 of the block of the load device 7. The negative output terminal of the pulse voltage converter 11 is connected to the anode of the second decoupling diode 13 and is the output negative terminal 24 of the block of the load device 7. Input positive 21 minus terminal 22 of the load device unit 7 are connected respectively to the positive and negative output terminals of the secondary power source 6. The output 23 above zero and minus terminal 24 of the load device type regenerative unit 7 are respectively connected to the positive 17 and negative 18 terminals for connection of external battery.

With insufficient loading power of the secondary power source, (n-1) blocks are additionally connected to the block of the load device, while the input terminals of all blocks of the recovery type load device are connected in parallel, i.e. input positive terminals 21 of all blocks 7 of the load device are connected to the output positive terminal of the secondary power supply 6, input negative terminals 22 of all blocks 7 of the load device are connected to the output negative terminal of the secondary power source 6.

When this load current of the secondary power source 6 is equal to the sum of the input currents n blocks 7 of the load device.

To ensure the output voltage level of the open circuit of the recovery type 7 load device above the battery voltage 4 of the uninterruptible power supply, the output terminals of the recovery type load device blocks 7 are connected either in parallel, or in series, or in series-parallel.

A parallel connection of the output terminals of the blocks 7.1-7.n of the recovery type load device is shown in FIG. In this case, the output open circuit voltage of the recovery device is equal to the output voltage of the open circuit of one unit of the recovery device. The output positive terminals 23 of the blocks 7.1-7.n are interconnected and connected to the positive terminal 17, for connecting an external battery, the negative output terminals 24 of the blocks 7.1-7.n are interconnected and connected to the negative terminal 18 for connecting an external battery .

The serial connection of the output terminals of the blocks 7.1-7.n of the recovery type load device is shown in Fig.3. In this case, the output open circuit voltage of the recovery device is equal to the sum of the output open circuit voltage n of the blocks of the recovery device. The output negative terminal 24 of the 7.1 unit of the load device is connected to the output positive terminal 23 of the unit 7.n of the load device, that is, the output negative terminal 24 of the previous unit is connected to the output positive terminal 23 of the next unit. The positive output terminal 23 of block 7.1 is connected to the positive terminal 17 for connecting an external battery, the negative output terminal 24 of block 7.n is connected to the negative terminal 18 for connecting an external battery.

Series-parallel connection of the output terminals of the blocks 7.1-7.n of the load-recovery unit of the recovery type is shown in Fig.4. In this case, the output voltage of the open circuit of the load device is equal to the sum of the output voltage of the open circuit to the blocks of the load device (k <n), connected in series (7.1-7.k). The output terminals to the blocks of the recovery device load device are connected in series and form a sequential assembly of the load device blocks. The negative output terminal 24 of the block 7.1 of each sequential assembly of the load device is connected respectively to the output positive terminal 23 of the block 7.k of this assembly, i.e., the negative output terminal 24 of the previous block of each serial assembly is connected respectively to the output positive terminal 23 of the next block of the given assembly. The positive output terminals 23 of the 7.1 blocks of each serial assembly are combined and connected to the positive terminal 17 for connecting an external battery, the negative output terminals 24 of the 7.k blocks of each serial assembly are combined and connected to the negative terminal 18 for connecting an external battery.

A device for testing secondary power supplies operates as follows.

The uninterruptible power supply 1 receives electric power from an alternating current network and ensures uninterrupted supply of electric power to a secondary power source 6 when the AC mains is disconnected. Uninterruptible power supply 1 operates in double energy conversion mode (on-line), that is, rectifier 2 converts AC voltage to DC voltage and feeds charger 3. Charger 3 charges battery 4, from which the selection power converter 5 to power the test secondary power source 6.

To test secondary power supplies with an input on alternating current, uninterruptible power supply 1 must have an output on alternating current, that is, converter 5 must be a DC / AC converter. For testing secondary power supplies with a DC input, uninterruptible power supply 1 must have a DC output, that is, converter 5 must be a DC / DC converter.

Unit 7 of the recovery type load device sets the power loading mode of the tested secondary power supply 6 and carries out energy recovery through the first decoupling diode 12 to the DC network of uninterruptible power supply 1. Current sensor 8, reference voltage source 9, amplifier-adder 10. pulse voltage converter 11 form a pulse stabilizer of the input current. The voltage from the information output of the current sensor 8, proportional to the load current of the tested secondary power supply 6, is compared with the output voltage of the reference voltage source 9 in the adder-amplifier 10. Thus, a control signal proportional to the deviation of the input current of the load unit 7 is generated at the output of the adder-amplifier 10 recovery type devices from the required value specified by the reference voltage source 9, and fed to the control input of the pulse converter yazheniya 11.

The first decoupling diode 12 prevents the current from flowing back through the output of the recovery unit 7 of the load device. The second decoupling diode 13 passes current when the unit 7 of the recovery type load device fails when the output terminals n of the load device are connected in series.

To test powerful secondary power supplies, several (n) blocks of the load device are used, connected in parallel at the input, i.e. combined terminals 21 of all blocks and terminals 22 of all blocks. In this case, the load current of the secondary power source 6 is equal to the sum of the input currents of the blocks 7 of the recovery type load device.

нагрузочного устройства, который возвращается в источник бесперебойного питания 1.With a constant output voltage and load current of the secondary power source 6, the recovery unit type 7 load unit 7 is a constant power source with a steeply falling external characteristic (Fig. 5), which allows it to be connected in parallel with the battery 4. The intersection point of the current-voltage characteristic of the battery and the external characteristic recovery device type 7 determines the output current

load device that returns to uninterruptible power supply 1.

нагрузочного устройства рекуперационного типа 7 выше напряжения аккумуляторной батареи 4.Battery voltage in different uninterruptible power supplies has different levels. To expand the scope of application of the device, the output terminals of the units 7 of the recovery type load device can be connected in parallel, in series, or in series-in parallel to provide an open circuit voltage level

recovery device type 7 above the voltage of the battery 4.

As an uninterruptible power supply 1, an uninterruptible power supply operating in a double conversion mode (on-line mode) with the ability to connect an external battery can be used.

As a pulse voltage converter 11, a known circuit of a bridge pulse DC-DC converter with transformer galvanic isolation and with an output open circuit voltage not lower than the voltage of the battery 4 of the uninterruptible power supply 1 can be used.

As a source of reference voltage 9 can be used with any precision controlled voltage regulator.

As an adder amplifier 10, an operational amplifier may be used.

As the current sensor 8, a non-contact current sensor based on the Hall effect can be used.

The use of energy recovery in the DC network of uninterruptible power supply 1 reduces the consumption of electricity from the AC network, and when the AC network is disconnected, from the battery 4. At the same time, power is consumed from the AC network (and when it is disconnected from the battery 4) , necessary only to compensate for losses in uninterruptible power supply 1, secondary power supply 6 and in the recovery device type 7 load device, which when the network is switched off This current increases the operating time of the device from the battery 4.

The proposed device has additional functionality, which allows long-term testing of secondary power sources for reliability without the risk of disruption of test schedules due to the loss of the AC mains, reduces energy costs.

Claims (5)

1. A device for testing secondary power supplies, containing a primary power source, a tested secondary power source and a recovery type load device unit, which includes a pulse voltage converter, an adder-amplifier, a reference voltage source, a current sensor in which the output is positive and negative secondary power sources are connected respectively to the input positive and negative terminals of the load device, the power input of the current sensor is is the positive input terminal of the load device, the negative input terminal of the pulse voltage converter is the negative input terminal of the load device, the output of the reference voltage source is connected to the addition input of the amplifier-adder, the output of the adder amplifier is connected to the control input of the pulse voltage converter, characterized in that the primary source of electricity made in the form of uninterruptible power supply, providing a double energy conversion mode, and into a block n of the recovery type load device, the first and second decoupling diodes are additionally introduced, the uninterruptible power supply comprising a rectifier, a charger, a rechargeable battery, terminals for connecting an external rechargeable battery, a converter, while the rectifier input terminals are an uninterruptible power supply input and are connected to an alternating power supply current, the positive and negative terminals of the rectifier are connected respectively to the positive and negative input terminals of the charger devices, the output positive terminal of the charger is connected to the positive terminal of the battery, to the input positive terminal of the converter and to the positive terminal used to connect the external battery, the output negative terminal of the charger is connected to the negative terminal of the battery, to the input negative terminal of the converter, and to the negative terminal, designed to connect an external battery, the output terminals of the converter are the output of the uninterruptible power supply voltage and are connected to the input terminals of the tested secondary power supply, the power output of the current sensor of the load device is connected to the input positive terminal of the pulse voltage converter, the information output of the current sensor is connected to the subtraction input of the amplifier-adder, the output positive terminal of the pulse voltage converter is connected to the anode of the first decoupling diode , the negative output terminal of the pulse voltage converter is connected to the anode of the second decoupling diode and is tsya negative output terminal of the load device, plus and minus output terminal block of the load device are connected respectively to the positive and negative terminals of an uninterruptible power supply intended for connection of external battery. 2. The device according to claim 1, characterized in that it further comprises (n-1) blocks of a regenerative-type load device, all n blocks being interconnected. 3. The device according to claim 2, characterized in that the blocks of the regenerative-type load device are connected in parallel, while the input plus and minus terminals of all the units of the regenerative-type load devices are connected in parallel and connected to the output plus and minus terminals of the secondary power source, the output plus and minus terminals of all blocks of the recovery type load devices are connected in parallel with the plus and minus terminals of the source reboynogo food intended for an external battery. 4. The device according to claim 2, characterized in that the blocks of the regenerative type load device are interconnected in series, while the input plus and minus terminals of all blocks of the regenerative type load devices are connected in parallel and connected respectively to the output plus and minus terminals of the secondary power source, and the negative output terminal of the first unit of the recovery type load device is connected to the positive output terminal of the n-th unit of the recovery load device type, the output positive terminal of the first unit of the recovery unit load device and the output negative terminal of the nth unit of the recovery unit load device are connected respectively to the plus and minus terminals of the uninterruptible power supply, designed to connect an external battery. 5. The device according to claim 2, characterized in that the blocks of the regenerative-type load device are connected in series-parallel, while the input plus and minus terminals of all the units of the regenerative-type load devices are connected in parallel and connected respectively to the output plus and minus terminals of the secondary source power supply, and the output plus and minus terminals k of the blocks of the recovery type load device are connected in series and form a sequential block assembly load device regenerative type, ie the negative output terminal of the first block of the recovery type loading device of the first sequential assembly is connected to the positive output terminal of the k-th block of the recovery type loading device of the first sequential assembly, with n / k consecutive assemblies of the recovery type loading device blocks connected in parallel, i.e. the positive output terminals of the first blocks of all serial assemblies of the recovery type load device are connected to the positive terminal of the uninterruptible power supply intended for connecting an external battery, the negative output terminals kx of the blocks of all serial assemblies of the recovery type load device are connected to the negative terminal of the uninterruptible power supply unit external battery.

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