RU144248U1 - SOLAR BATTERY ELECTRIC SIMULATOR - Google Patents

Abstract

1. An electric simulator of a solar battery containing a constant voltage source in the form of a rectifier with a filter and a converter with a stable output voltage, a direct current source in the form of a short circuit current stabilizer simulator, a voltage boost module in the form of a converter with a stable additional voltage, connected between a constant voltage source and a direct current source, a block of resistors connected to the output of a direct current source and containing a series controlled resistor Rп and shunts controlled resistor Rш, as well as a nonlinear element formed by parallel-series-connected diodes, and connected to the resistor block, through a cut-off diode, characterized in that the current regulator is made with two control loops formed by two keys, the first key is an input, and the second - output, connected to the cathode of the diode, the anode of which is connected to the output of the constant voltage source and the common output bus of the boost module, as well as a choke and return diode, the cathode of which is connected to the output of the first key, and through the inductor - with the connection point of the input of the block of resistors and the anode of the cut-off diode, while the anode of the return diode is connected to the common bus of the load and the constant voltage source, the non-linear element is connected by its input to the cathode of the cut-off diode, and also, through the decoupling diode and the reverse the converter is parallel to the output of the boost module, connected by a positive pole to the input of the second key of the current stabilizer, in addition, an isolation diode and an output switch are introduced to connect to the load. 2.

Description

Solar battery simulators are secondary power sources for simulating the main technical characteristics of solar cells, which are used in carrying out autonomous and complex tests of energy converting equipment based on primary sources in the form of solar panels.

Solar cell simulators are known that contain a voltage source and a current source, which are controlled in such a way as to be interconnected and simulate the current-voltage characteristic (CVC) of a solar battery (see, for example, the description of US Pat. No. 4,999,524). The specified device contains a constant voltage source connected in series with a programmable voltage source voltage boost, and a programmable pulsed current source. The limiting diode is connected in parallel with the current source and the constant voltage source. The complete control circuit contains two circuits. The relatively slow main control loop with a bandwidth of several kHz regulates the average amplitude of the current flowing into the inductor and contains a Hall sensor, an error amplifier, a summing amplifier, a comparator for generating the PWM output signal, a key driver, a key, and a choke. A relatively fast loop with a bandwidth of at least 100 kHz compensates for voltage changes across the inductor and links dynamic changes to the main loop. The disadvantage of this device is the presence of a Hall sensor, as well as a summing amplifier and a comparator, realizing the transition from the current section of the I – V characteristic to the voltage section.

Also known is a device for simulating the current-voltage characteristics of a solar battery (RU 52522), which also contains a DC voltage source, a DC source, a block of variable resistors that simulate the internal resistance of a solar battery, a nonlinear block formed by parallel-series connected diodes, and a block of capacitors for simulating the output resistance of a solar battery, a voltage boost module connected between a voltage source and a current source, decoupling diodes, and also a discharge core and charging modules. In this device, the resistor block consists of resistors Rп and Rш. The value of the resistor Ksh sets the slope in the current – voltage – voltage section of the current, and the resistor Rp sets the slope in the voltage – voltage – voltage section. The configuration of the nonlinear transition between the voltage and current sections is determined by the corresponding set of diodes of the nonlinear element. Charging and discharge modules provide regulation and stabilization of the voltage of the filter unit. The disadvantage of this device is the complexity of the circuit due to the presence of charging and discharge blocks.

The closest in essential features and achieved effect to the proposed solution is a device for simulating the current-voltage characteristics of a solar battery according to utility model RU 77695, which consists of a DC voltage source, DC source, a block of resistors that simulate the internal resistance of the solar battery, a nonlinear block formed in series - parallel-connected resistors, capacitor unit and voltage boost module, voltage stabilization module, comparator, control forward transistor switch and a current sensor. The principle of operation of this simulator of the current-voltage characteristics of the solar battery is based on the parametric formation of the current-voltage characteristic with improved static and dynamic characteristics.

The disadvantages of this device are associated with the presence of a comparator that implements the formation of the I – V characteristic at the transition section from the current section to the voltage section, with a diode current threshold. In this case, there are errors associated with a fuzzy transition criterion, caused in the case of a current threshold, the establishment of not a zero but a final current value, as well as with the hysteresis of the comparators. The disadvantage is the presence of a current sensor.

The objective of the utility model is to increase the accuracy of the formation of the I – V characteristic of the solar battery by ensuring its monotonicity at the transition points.

The electric simulator of the solar battery in the proposed technical solution, as well as the prototype, contains a constant voltage source in the form of a rectifier with a filter and a converter with a stable output voltage, a direct current source in the form of a short-circuit current stabilizer simulator, a voltage boost module in the form of a converter with a stable additional voltage connected between a constant voltage source and a constant current source, a resistor block included in the output of the constant current source and containing s serial controllable resistor Rp and controllable shunt resistor Rsh and a nonlinear element formed by parallel-series-connected diodes and resistors connected to the block via clipping diode. Unlike the prototype, in the electric simulator, the current stabilizer is made with two control loops formed by two keys, the first key is an input, and the second is an output connected to the cathode of the diode, the anode of which is connected to the output of the DC voltage source and the common output bus of the boost module, as well as a choke and a return diode, the cathode of which is connected to the output of the first key, and through the choke to the connection point of the input of the resistor block and the anode of the cut-off diode, while the anode of the return diode is connected to a common of a load and a constant voltage source, the nonlinear element is connected by its input to the cathode of the cut-off diode, and also, through the decoupling diode and a reversing converter, in parallel with the output of the boost module connected by a positive pole to the input of the second key of the current stabilizer, in addition, a disconnector is introduced to connect to the load diode and output switch.

To increase the reliability and continuity of the power supply to the load, the electric simulator can be made in the form of two identical modules of the electric simulator operating in the hot standby mode, for which a shunt key is installed at the output of each channel, controlled by the simulator parameters monitoring device.

Further, the principle of operation of the electrical simulator is explained using the figures in which: FIG. 1 is a structural diagram of a simulator, FIG. 2 - simulated current-voltage characteristic of a solar battery.

The solar battery simulator in accordance with the utility model comprises a constant voltage source consisting of a rectifier 1 connected to the supply network through a switch 2, a filter 3 and a converter 4 with a stable output voltage, and a voltage boost module 5 connected by an input in parallel with the constant voltage source. Between the positive terminal of the DC voltage source 4 connected to the negative terminal of the boost module 5, a constant current source is connected through diode 6 in the form of a current stabilizer consisting of a key 7, a choke 8 and a return diode 11. A second switch 9 is introduced to form a second current control loop To form the current-voltage characteristic of the solar battery at the output of the current stabilizer, a sequential controlled resistor 12 is included, which sets the slope of the characteristic in the voltage section, and the shunt are controlled resistor 13, defining the slope of the current at the portion. A non-linear element 14 connected in parallel with the output of the voltage boost source through an isolation diode 15 and a reversing converter 16 provides a non-linear configuration of the transition section of the I – V characteristic of the solar battery. A reversing converter 16 connected in parallel with the voltage boost source 5 and the non-linear element 14 is introduced to stabilize the voltage level of the non-linear element within the specified parameters. At the output of the simulator there is a shunt key 17, controlled by the device for monitoring the parameters of the simulator 18, and the simulator is connected to the load through the isolation diode 19 and the switch 20.

To ensure hot redundancy, the simulator is made in the form of two identical modules, the main and backup, having the same output settings. The second redundant module is indicated in the figure as 21.

The device operates as follows: after the key 2 is closed, the mains power is supplied to the rectifier 1, the output voltage of which through the filter 3 is supplied to the buck converter 4, which generates the voltage U ₀ = Uхх (1 + Rп / Rш) -Uне, where Uхх - the idle voltage of the simulator, Rп and Rш are the resistance values of the resistors 12 and 13, Une is the voltage at the nonlinear element 14. The voltage is installed at the output of the DC voltage source of voltage boost 5: Uд> Uэ. The current stabilizer provides regulation and stabilization of the short-circuit current Ikz through the inductor 8. The resistor 13 sets the slope in the current-voltage characteristic section (section AB in Fig. 2), the resistor 12 sets the slope of the current-voltage characteristic in the voltage section (CO section in Fig. 2). The configuration of the nonlinear I – V transition (section BC in FIG. 2) is determined by the corresponding set of semiconductor diodes of the nonlinear element 14.

The current stabilizer has two control circuits and current stabilization Ikz. For clarification, consider the process of changing the load resistance from short circuit to idle.

When the load is short-circuited, the simulator operates in the current – voltage – voltage – current section, while the current of the nonlinear element 14 is zero, because the clipping diode 10 is locked. The transistor switch 9 is closed. The transistor switch 7 operates in a PWM mode with a low duty cycle γ ₇ . During the pulse (key 7 is open), the current flows into the load along the "large" circuit: plus source 4 - diode 6 - key 7 - inductor 8 - resistor 12 - decoupling diode 19 - switch 20 - load - minus source 4. V moments of pause (key 7 is locked), the current flows into the load along the circuit: inductor 8 - resistor 12 - decoupling diode 19 - switch 20 - load - return diode 11. With increasing load resistance, γ ₇ increases, increasing the power in the load.

At the moment when the key 7 is fully open, and the load resistance does not provide Ikz current in the inductor 8, the simulator control unit (not shown) automatically starts to deploy γ ₉ . At the same time, the second “small” control and stabilization circuit Ikz comes into operation, simultaneously adding voltage up to the idle voltage of the simulator. During the pulse (switch 9 is open), during the PWM period, the current Ikz of inductor 8 is distributed in the following circuits: (plus voltage source 5 - switch 9 - open switch 7 - inductor 8 - diode 10 - non-linear element 14 - minus voltage supplement 5) and (plus source 5 - key 9 - key 7 - inductor 8 - resistor 12 - parallel circuit of resistor 13 and load - constant voltage source 4 - minus voltage boost source 5). At the time of a pause (key 9 is locked), the current of the inductor 8 is distributed along the following circuits: {inductor 8 - diode 10 - non-linear element 14 - diode 6 - key 7 - inductor 8} and {inductor 8 - resistor 12 - parallel circuit of resistor 13 and load - Converter 4 - minus the voltage boost source 5}. Thus, the inertia-free parametric I – V characteristic of the solar cell simulator shown in FIG. 2.

Non-linear element 14 is built on semiconductor diodes, the direct voltage drop on which depends on temperature. To keep the I – V characteristic of the simulator within the specified parameters, the voltage level of the restriction Une is stabilized by the reversing transducer 16. The reversing transducer 16 can be implemented in an anti-parallel connection of step-up and step-down converters. If the channel operates on the current portion of the I – V characteristic, there is no current discharge to the nonlinear element, and the voltage at the cathode of the diode 15 is supported by a buck converter. In the voltage – voltage characteristic section, the excess energy of the nonlinear element 14 is discharged by a boost converter to the input of the voltage boost source 5, from where it is spent on the operation of the “small” control and stabilization circuit Ikz.

In the proposed scheme, an automatic transition is applied from the PWM key 7 to the PWM key 9 and vice versa, which made it possible to ensure the monotonicity of the current-voltage characteristic at the transition points.

Hot backup is carried out as follows: The simulator is made in the form of two modules, the main one, which is described above, and the backup module 21. In operation, both channels having the same settings of the output parameters are turned on. In this case, the key 17 (hereinafter referred to as the “short circuit”) is open at the output of the main module, and is closed at the output of the backup module 21. In the event of a failure of the main module, the key of the main module 17, controlled by monitoring devices 18 of the parameters of the main and backup modules, instantly closes the output of the main module, and the "shortener" of the backup module 21 simultaneously opens its output. Thus, while providing inertialess current-voltage characteristics, the continuity of the load power supply is achieved and, thereby, increasing the reliability of the solar battery simulator.

Claims (2)

1. An electric simulator of a solar battery containing a constant voltage source in the form of a rectifier with a filter and a converter with a stable output voltage, a direct current source in the form of a short circuit current stabilizer simulator, a voltage boost module in the form of a converter with a stable additional voltage, connected between a constant voltage source and a direct current source, a block of resistors connected to the output of a direct current source and containing a series controlled resistor Rп and shunts controlled resistor Rш, as well as a nonlinear element formed by parallel-series-connected diodes, and connected to the resistor block, through a cut-off diode, characterized in that the current regulator is made with two control loops formed by two keys, the first key is an input, and the second - output, connected to the cathode of the diode, the anode of which is connected to the output of the constant voltage source and the common output bus of the boost module, as well as a choke and return diode, the cathode of which is connected to the output of the first key, and through the inductor - with the connection point of the input of the block of resistors and the anode of the cut-off diode, while the anode of the return diode is connected to the common bus of the load and the constant voltage source, the non-linear element is connected by its input to the cathode of the cut-off diode, and also, through the decoupling diode and the reverse the converter is parallel to the output of the boost module, connected by a positive pole to the input of the second key of the current stabilizer, in addition, an isolation diode and an output switch are introduced to connect to the load. 2. An electric simulator of a solar battery according to claim 1, characterized in that it is made in the form of two identical modules: a primary and a backup, having the same output parameter settings, and turned on according to the hot standby circuit with the help of keys shunting the outputs of these modules according to the device signals monitoring parameters of the simulator.