RU2279705C2 - Method of energizing load from solar battery - Google Patents

Abstract

FIELD: automatic control systems.

SUBSTANCE: method intends for controlling voltage of power limited constant current sources and for controlling secondary sources operating from current sources, for example, solar batteries. Commutation of key elements of increasing converter is carried out by synchronizing and controlling signals. Control signal is formed on the base of sum of error signal and sweep signal. Current of throttle (power source) and output current of converter are measured. Sweep signal is formed to be proportional to difference of saw-shaped signal with amplitude being equal to current signal of power source and of signal being equal to output current of converter.

EFFECT: widened functional abilities due to its propagation to increasing converters.

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Description

The claimed technical solution relates to automatic control and is intended to control the voltage of limited power sources of direct current, it can be widely used in controlled secondary power sources operating from current sources, such as solar panels.

Known step-up converters containing a inductor, a key element, a diode and a filter capacitor, in which, when the key element is closed, the current from the power source flows through the inductor, storing energy in it, while the diode blocks the load and the filter capacitor from the key element, the current to the load during this period of time it comes only from the filter capacitor, then, when the key element is closed, the inductor’s EMF is summed up with the input voltage of the power supply and the energy of the inductor’s current is given into the load and filter capacitor.

Known methods for controlling the output voltage of such converters are based on switching a key element with a duty cycle γ proportional to the error signal equal to the difference between the output voltage of the converter and the reference voltage, while the output voltage depends on the supply voltage U _n , the resistance r of the discharge and charging circuit of the inductor, load resistance R _n and duty cycle γ [1].

The disadvantage of this control method is the limited control range k _U = 1-5 and its non-linearity, as well as the relationship between the error signal and the pulse duty cycle.

The closest technical solution selected as a prototype is a step-down converter control method in which the switching of key elements is carried out by synchronizing and control signals, the control signal is formed from the sum of the error signal, the differentiated output signal and the sweep signal, the differentiated output signal is formed proportional to the current difference the inductor and the output current of the converter, and the scan signal is generated as predicted for the interval after comm tation key elements differential output [2].

The known method provides switching of the key element in the absence of a static error and the stability of control in a wide range of parameter settings.

The disadvantage of this method lies in the impossibility of obtaining an output voltage higher than the supply voltage, as well as in the pulsed nature of the current consumption, unacceptable when powered by current sources.

The purpose of the invention is to expand the functionality of the control method due to its distribution to boost converters.

This goal is achieved in that the switching of the key elements of the boost converter is carried out by synchronizing and control signals, the control signal is formed from the sum of the error signal and the sweep signal, the inductor current (power source) and the output current of the converter are measured, while the sweep signal is formed proportional to the difference of the sawtooth signal with amplitude equal to the current signal of the power source, and a signal equal to the output current of the Converter.

The essence of the invention lies in the fact that the proposed control method is based on the use of a sweep signal for switching the key elements, which is formed by the criterion of equality to zero in the steady state mode for the average period of the repetition of current pulses through the filter capacitor. Moreover, in the vicinity of the steady state by the time of switching the key element, the scan signal value becomes equal to zero, which ensures switching of the key element in the absence of a static error.

By the criterion of equality to zero in the steady state, the average value of the filter capacitor current for the pulse repetition period for a boost converter with one-sided pulse-width modulation is

where I1 _C , I2 _C is the filter capacitor current in the interval before and after switching the key element; t _to - the moment of switching of the key element.

If we take the current value of I _C.sr as the sweep signal, then after simple transformations (2) we get

where t _p = T {t / T} is the time coordinate for generating the sweep signal ({a} is the fractional part of the number a).

The filter capacitor current when modulating the leading edge of the pulse is: I1 _C = -I _o , I2 _C = I _n - I _o , and when modulating the trailing edge - I1 _C = I _n -I _o , I2 _C = -I _o , where I _n is the current of the power source; I _o - the output current of the Converter.

Substituting the corresponding expressions for the capacitor current into equation (3) and accepting the currents I _n , I _output at the switching intervals of the key element as constant and based on the average theorem for a certain integral [3], we obtain a sweep signal for control with modulation of the leading edge of the current pulse

which is the difference between a falling ramp signal with an amplitude equal to the current signal of the power source and a signal equal to the output current of the converter.

For control with modulation of the trailing edge of the current pulse - sweep signal

which is the difference between an increasing sawtooth signal with an amplitude equal to the current signal of the power source and a signal equal to the signal of the output current of the converter.

In this case, we obtain the control law of the form

where x = U _o - U _on - error signal, U _o - output signal; U _on - reference signal; k _m is the transmission coefficient of the sweep signal, which determines the dynamic characteristics of the converter [4]; t _k is the switching moment of the key element, which is determined by the least modulo negative root of the equation F = 0 when controlling the modulation of the leading edge of the current pulse of the power source and the smallest positive root of the equation F = 0 when modulating the trailing edge of the current pulse of the power source.

According to (2), the corresponding switching of the key element in the steady state should occur at I _C.cp = 0, which corresponds to the transition through zero of the scan signal according to (3, 4, 5), this, in turn, ensures switching of the key element under control according to the law ( 6) with an error signal x (t _k ) = 0.

The drawing shows a diagram of a Converter with pulse-width regulation that implements the proposed control method.

The pulse-width-controlled converter, made according to the proposed control method, contains a power source (solar battery) 1, inductor 2, diode 3, filter capacitor 4, key element 5, comparison unit 6, two current sensors 7, 8, a control forming unit signal 9, RS-flip-flop 10, with the ramp signal generator 11 and the subtraction unit 12. The output power supply bus 1 is connected to input 2 via a throttle sensor 7, the current, the output inductor 2 is connected to the transducer output U _O bus through the diode 3, except tog , Throttle 2 output is shunted by a key element 5, in the load circuit converter included current sensor 8, input node comparison 6 are connected to the output bus inverter U _O and bus U _on the reference target voltage, the current sensor output 7 connected to a control input of the generator of the ramp signal 11, the inputs of the subtraction unit 12 are connected to the output of the sawtooth signal generator 11 and the output of the current sensor 8, the inputs of the control signal generation unit 9 are connected to the output of the comparison unit 6 and the subtraction unit 12, the output of the control formation unit actuating signal 9 is connected to the S-input of RS-trigger 10, R-input of RS-trigger 10 and a synchronizing signal input 11 of the ramp generator coupled to bus U synchronization _sync, the output RS-flip-flop 10 is connected to the control input of the key element is 5.

A pulse-width-controlled converter operates as follows: a sawtooth signal with an amplitude proportional to the current value I _{n of the} power source 1 is generated at the output of the sawtooth signal generator 11 by the sync pulses U _synch , a sweep signal Y _p is generated at the output of the subtraction node 12, at the output of the comparison node 6, an error signal x is generated, at the output of the control signal generation unit 9, in accordance with (6), a control signal F is generated, the RS-trigger 10 is set to VT = 1 when the clock ca U _sync and status VT = 0 when a control signal F, for the closure of a key element 5, the current I _n the power source 1 flows through the throttle 2 by storing therein the energy of the diode 3 wherein the cuts (blocks) the load does not allow the filter capacitor 4 to be discharged through a closed key element 5, the current in the load during this period of time comes only from the filter capacitor 4, then, when the key element 5 opens, the current I _{n of the} power supply 1 through the diode 3 enters the load and charges the filter capacitor 4, if this mode is not if the energy of power source 1 is enough (the voltage of power source 1 is less than the output voltage of the converter), then the self-induction EMF of inductor 2 is summed with the output voltage and the current energy of inductor 2 is transferred to the load.

In the converter with control of the leading edge of the current pulse, a ramp-down signal is generated at the output of the sawtooth signal generator 11, a sweep signal Y _pn is generated at the output of the subtraction node 12 according to equation (4), the sync signal U _sync RS-trigger 10 is set to VT = 1, in which the key element 5 closes and cuts off (blocks) the load from the power source 1, with the least negative root of equation (6) F = 0 - the RS-trigger 10 is set to VT = 0, in which the key element nt 5 is opened and the current power source 1 is supplied to the load and charges the filter capacitor 4.

In the converter with control of the modulation of the trailing edge of the current pulse at the output of the sawtooth signal generator 11, an increasing sawtooth signal is generated, at the output of the subtraction node 12, a sweep signal Y _r.s. according to equation (5), according to the clock signal U _{sync, the} RS-trigger 10 is set to VT = 1, in which the key element 5 opens and the current of the power source 1 enters the load and charges the filter capacitor 4, with the smallest positive root of equation (6) F = 0 - RS-trigger 10 is set to VT = 0, in which the key element 5 opens and cuts off (blocks) the load from power source 1.

The converters are controlled according to the criterion of the steady-state mode — the zero value of the average value of the filter capacitor current over the pulse repetition period according to (2), and is implemented by generating a sweep signal according to (3), which, in turn, is converted to (4) or (depending on the type of modulation) 5).

Thus, the proposed control method allows for the operation of the converter in the absence of a static error, ensuring the stability of the steady state in a wide range of parameter settings.

LITERATURE

1. Semenov B.Yu. Power electronics for amateurs and professionals. M .: Solon-R. 2001.

2. Kazantsev Yu.M., Lekarev A.F. The method of direct control synthesis in converting technology // Electronic and Electromechanical Systems and Devices: Sat. scientific Proceedings of the Scientific and Production Center "Polyus". Tomsk: MGP "RASCO" at the publishing house "Radio and Communications", 2001. S.131-140.

3. Smirnov V.I. Course of higher mathematics. M .: Nauka, 1974.T.1.

4. Kazantsev Yu.M., Chernyshev A.I., Lekarev A.F. The formation of quasi-sliding processes in pulse converters with PWM // Electricity. 1993. No. 12. S.45-49.

Claims (1)

The method of supplying the load from the solar battery, which consists in the use of a step-up converter, in which the switching of the key elements is carried out by synchronizing and control signals, the output current of the converter and the current of the power source are measured, an error signal x equal to the difference between the output signal and the reference signal is generated, characterized in that they generate a sweep signal Y _p proportional to the difference of the sawtooth signal with an amplitude equal to the current signal of the power source and the signal equal to the output at the current of the converter, while switching the key elements is carried out in accordance with the law of control of the form

where x = U _o - U _op - error signal, U _o - output signal; U _op - reference signal; k _m is the transmission coefficient of the sweep signal; t _p = T {t / T} is the time coordinate for generating a sweep signal; t _k is the moment of switching of the key element, which is determined by the smallest modulo negative root of the equation F = 0 when controlling the modulation of the leading edge of the current pulse of the power source and the smallest positive root of the equation F = 0 when controlling the modulation of the trailing edge of the current pulse of the power source.