DE3010371A1 - Control output circuit for solar cells - has sensing circuit which switches cells through to converter when power output exceeds threshold - Google Patents

Abstract

The control circuit is for a solar generator so that the solar cells are only switched through to a converter if sufficient sunlight exists to lift the output power of the cells above a predetermined threshold level. The solar cells (1) are connected to the control and converter (4) circuitry by a manual switch (2,a,b). When the power output exceeds a threshold level the cells (1) are connected to the converter (4) by the automatic control switch (3) which is in series with the manual one (2). The converter (4) and the automatic switch are switched on by a control circuit (6) which is in turn controlled by the power measuring circuit (9) on the front end of the automatic switch (3) and across the output of the solar cells (1) when the manual switch (2) is closed. The power measuring circuit (9) is brought into circuit by a contact(S) of the automatic switch (3)/control circuit (6) combination. The power measuring circuit (9) is a Zener diode, GTO thyristor combination.

Description

description

The invention relates to a method for switching on a Converter to the output terminals of a solar generator and an arrangement for implementation of the procedure.

In order to be operational, static converters require a minimum of input power. This minimum power is used to supply the control equipment and the no-load losses of the converter and the load connected to it, the mostly consists of motors.

When supplying the converter from the network, you can set vcr.auC- that the required supply is always available.

The situation is different if the converter comes from a solar generator is supplied as it is in photovoltaic energy supply (rvn) systems of the Case is. Beer is the range of services available from the solar generator directly dependent on the intensity of the current solar radiation.

If the converter is switched on in times of insufficient power,> - supply of the solar generator on, the solar generator voltage can drop to a value when the protective devices of the converter respond and the converter is switched off - If the switch-on command for the converter persists, is Continuous switching on and off of the converter is the result. This takes so long at, until the solar generator can deliver sufficient power.

In addition, the solar generator must be resilient so that the am Inverter operated load can do its job.

For example, if the load is a drive for water pumps, So the water pumping does not start until a system and pump-specific minimum consumption the pump on. In addition, the efficiency of the system is extremely high in the low-load range small amount.

The object of the present invention is to provide a method for switching on of a converter to the output terminals of a SolaL generator with which it can be determined whether the solar generator has an adequate output power Who adds before the converter is put into operation. The arrangement for implementation of the process enables a performance-oriented automatic activation of the Solar generator load.

Therefore it should be referred to as a performance-oriented automatic switch-on kL ^) will.

This task is characterized by that in claim 1 Features solved.

With the method according to the invention, both the automatic commissioning of the PVE system after sunrise as well as the automatic Switching on the system again after the solar generator has been temporarily shaded, with the prerequisite that the solar generator by the circuit design can provide a determinable minimum performance, enables.

Advantageous further developments of the invention are set out in C13 subclaims marked. So you get by adding a small additional circuit a charge controller for accumulators for minimum power detection. Herewith it is possible during the times when the solar generator has the required minimum output can not deliver to charge accumulators. These can be used, among other things, for short-term Shading of the generator the Umrichterb # tr ##. B ensure or an electrical Enable lighting in naked times.

The method according to the invention is described below with reference to the in The arrangement shown in the drawing for carrying out the method is explained.

Fig. 1 shows the performance-oriented automatic switch-on (LEA) in Input circuit of a converter that is fed from a solar generator.

Fig. 2 shows the basic circuit of the performance-oriented automatic switch-on, Fig. 3 shows a circuit diagram of the performance-oriented automatic switch-on with a signaling or switching device.

4 shows a circuit diagram of the power-oriented automatic switch-on with signaling or switching device and a charge controller for an accumulator.

Fig. 5 shows the U-I characteristics of the solar generator and the performance-oriented automatic switch-on the position of the switching points at different 3 illuminance levels for the solar generator.

In Fig. 1, 1 denotes a solar generator, the outputs A manually operated switch 2, a controllable switch, via lines a, b 3 and are connected to the input of a converter 4. In the branch a a throttle 5 is arranged. The output voltage U and the frequency f of the converter 4 are controlled by a converter control 6, which also sends the signals for the controllable switch 3 emits. A capacitor is parallel to the input of the converter 4 7 arranged, the voltage of which is applied to the input terminals of the circuit 6. A converter 8 supplies the circuit 6 with a quantity proportional to the current 1d. In parallel with that Output of the solar generator 1 is after the switch 2 via a contact S. performance-oriented automatic switch-on 9 arranged, their structure and how they work is described below. S is a contact of the controllable Switch v which is controlled by circuit 6.

The output signals of the performance-oriented automatic switch-on 9 act on the circuit 6 for the control of the converter 4. If the performance-oriented Automatic switch-on 9 in the presence of the no-load voltage or

the required power of the solar generator 1 a corresponding Outputs a signal to the circuit 6, the controllable switches 3 are closed and contact S is open. The voltage emitted by the solar generator 1 is thus generated fed to the converter 4 and the power-oriented automatic switch-on 9 switched off.

Fig. 2 shows the basic circuit of the power-oriented automatic switch-on 9. This is via the contact S between the lines a and b, which are the output terminals of the solar generator 1 (Fig. 1) with the converter 4 (Fig. 1) connected, switched. It consists of two parallel series connections, which are connected to one pole of the contact S and are connected to line b. The series connections are formed from a resistor R 1, an absolute switchable, switched in the forward direction Thyristor (GTO) T 1 and a resistor R 2 on the one hand and a resistor P 4 and a forward-connected thyristor 2 on the other hand. Parallel to Resistor R 2 is a capacitor C 1. To the control electrode of the turn-off thyristor T 1, the anode of a Zener diode D 1 is connected its cathode at the junction of the resistor R with the anode of the thyristor fP 2 lies. The anode of a Zener diode is connected to the control electrode of the thyristor T 2 D 2 connected its cathode at the connection point of the resistor R 2 with the The cathode of the turn-off thyristor i is located.

The mode of operation of the circuit arrangement according to FIG. 2 is as follows: If the voltage of the solar generator 1 (FIG. 1) increases, the circuit arrangement becomes higher over the lines a, b to the full open circuit voltage of the generator 1, so the switch-off thyristor (GTO) g IC 1 is ignited via the resistor R 3. As a result, the generator voltage is short-circuited to a value that is determined by the resistors P.-i and R 2 of the circuit and the instantaneous value of the solar generator short-circuit current is determined.

The resistor R 1 limits when T 1 is switched on from a high voltage the inrush current. This task can help reduce power dissipation as well take over a choke L, this is then with a diode D or a resistor to wire. If the short-circuit current reaches a certain level, which is a measure for is the generator power, the thyristor T 2 is controlled by the voltage drop across the resistor R. 2 ignited. This causes the shutdown of the turn-off thyristor T 1 by the capacitor C 1 connected in parallel to R 2 with reverse polarity to the Ga # e cathode path from T 1 lays. The voltage of the generator can now increase to its idle value. In that the thyristor T 2 receives its holding current via the resistor R 3 and becomes conductive remains, reignition of T 1 is reliably prevented.

The jump of the solar generator voltage to its beer running value or the ignition or being conductive of T 2 after reaching the minimum power can be used as the switch-on criterion for switching on the converter 4 (Fig. 1).

For this purpose, the circuit arrangement 9 according to FIG. 2 is provided with a message or Switching device expanded and shown in FIG.

The signaling or switching device is used to initiate the switch-on process for the load after recognizing the residual power of the generator. In addition is between the resistor R 3 and the thyristor T 2 still one in the forward direction polarized diode D 3 switched. In parallel with the resistor R 3 and the diode D 3 lies a one circuit consisting of a resistor R 4 and a relay coil d 1. Instead The relay coil can have an optical receiver or the like. After turning on the burden the contact S opens and switches the performance-oriented Automatic switch-on 9.

Fig. 5 shows the U-I characteristics of the solar generator 1 and the performance-oriented automatic switch-on 9 the position of the switching points at different Illuminance # for the solar generator.

When the illuminance reaches the value # On, due to the then prevailing solar generator voltage USG> UAll the switch-off thyristor T 1 ignited via R 3. About the series connection of the resistors R 1 and R 2, which thereby are connected to the terminals of the solar generator, the short-circuit current of the flows Solar generator IK'An. The solar The 1K'An generator voltage drops to the value UU = 1K'An R1,2 from.

With increasing illuminance, the short-circuit current of the solar generator increases to and thus also the voltage across the resistor R 2.

The solar generator has its own lighting level #Minimum Required minimum performance achieved.

The solar generator voltage has risen to the value UEin, the to trigger the thyristor g 2 over the voltage at R 2 is sufficient to extinguish of the turn-off thyristor T 1 to cause.

Since the solar generator only ccvh with the Holding current is loaded by T 2, its voltage can approach the idle value UO increase.

To the solar generator 1 (Fig. 1) also during the phases in which he not being able to use its required minimum output is according to the invention the performance-oriented automatic switch-on 9 to a charging device I for a Accumulator B, as shown in Fig. 4, expanded. It consists of a thyristor 3, with its anode to the cathode of the thyristor g 2 and with its cathode is connected to line b. A series circuit is parallel to the thyristor T 3 consisting of a blocking diode D 4 and the accumulator B. In the ignition circuit of the Thyristor T 3 is a Zener diode D 5 argeordr-t, whose cathode is connected to the connection the cathode of the blocking diode 4 is connected to the negative pole of the accumulator B.

The mode of operation of the charging device is as follows: That of the performance-oriented Automatic switch-on 9 required test current for minimum power detection avs solar generator 1 - this is the short-circuit current of the conductive cut-off thyristor T 1 through this flows - is used to charge the accumulator B. To do this, he will use the Blocking diode D 4, the accumulator B and via line b back to the solar generator 1 headed.

The charging of the accumulator B is finished when he either his Has reached the end-of-charge voltage, or the. Solar generator has reached its minimum output Has. In the first case, the end-of-charge voltage of the accumulator 3 is released via the Zener diode D 5 the ignition of the thyristor T 3 off.

So that the blocking diode D 4 is from the voltage of the accumulator B. held in reverse polarity and thus the charging current of the accumulator B is interrupted. It continues to flow as a test current through the thyristor T 3.

In the second case, in which the solar generator 1 longs for minimum power reached the voltage at R 2, as already described, the ignition of the Thyristor 11: e-n so that the turn-off thyristor T 1 is blocked and the wire current is interrupted will.

Blank page

Claims (6)

Procedure for connecting a converter to the output terminals of a solar generator Patent claims 9 method for switching on a converter to the output terminals of a solar generator by means of a converter control controllable switch, characterized in that when the contacts are open controllable switch (3) the short-circuit current of the solar generator (1) is detected and as a function of this, the controllable switch (3) and a contact (S) complementary being controlled. 2. Arrangement for performing the method according to claim 1, characterized characterized in that in front of the contacts of the controllable switch (3) between the Output terminals (a, b) of the solar generator (1) the contact (S) the series connection of a resistor (R1), a switchable thyristor (#i) and a resistor (R2) to which a capacitor (C1) is connected paraffi'-lel, and the series connection of a resistor (R3), a diode (D3), to which a signaling respectively. Switching device (R4, dl) is connected in parallel, and a thyristor (T2) is arranged. 3. Arrangement according to claim 2, characterized in that the Gatz of the thyristor (T2) via a forward polarized Zener diode (D2) with the Cathode of the turn-off thyristor (21) is connected. 4. Arrangement according to claims 2 and 3, characterized in that that the gate of the turn-off thyristor (1) is polarized in the forward direction Zener diode (D1) is connected to the anode of the diode (D3). 5. Arrangement according to claims 2 to 4, characterized in that that the resistor (R1) is bridged by an inductance by means of a diode (D) (L) is replaced. 6. Arrangement according to claims 2 and 3 or 2 to 4, characterized in that between the series circuits connected in parallel (R1, TI, R2, R3, D3, T2) and the output terminal (b) of the solar generator (1) a blocking diode (D4) and an Ak umulator (B) are arranged, which are bridged by a thyristor (23), at its gate the Anorde of a Zener diode (D5) is connected, the cathode of which is connected to the cathode the diode (D4) and the positive pole of the accumulator (B) is connected.