JPS62181633A - Solar battery circuit - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a charging circuit used to effectively transfer electric power generated from a solar cell to a storage battery.

Conventionally, in order to effectively utilize the electric energy obtained by a solar cell, it is generally known that the electric energy is temporarily stored in a storage battery and then taken out and used when necessary.

The problem when trying to charge a storage battery using the voltage generated by a solar cell is that when the amount of light irradiated to the solar cell is small, the generated voltage is so small that charging becomes impossible.
The problem is that the energy generated during this time cannot be used.

For example, the voltage generated by a solar cell changes within a day as shown in FIG. 4, and the generated voltage becomes smaller during the hours after sunrise and before sunset. Therefore, if a charging circuit is designed to match the voltage generated during the hours around noon when the amount of power generation is large, it will not be possible to flow charging current from the solar cell to the storage battery during the hours after sunrise and before sunset when the generated voltage is low. Therefore, the energy generated during this time period cannot be used. Also, since the amount of irradiation light decreases even during cloudy days, the energy generated by the solar cells cannot be used at this time either.

In order to enable charging of storage batteries even when the irradiation light 9 was small, there was a charging method like the conventional method (Special Publications Showa GO28).
Publication No. 56].

In a circuit that charges a storage battery using a solar cell, multiple capacitors are installed separately from the storage battery, and when the amount of light irradiation is small and the voltage generated by the solar cell is low, a temporary charging state is established in which multiple capacitors are connected in parallel to the solar cell. , a method in which these capacitors are connected in series to the storage battery and the main charging state is alternately switched, and the voltage charged in the capacitor in the parallel state is boosted by switching to the series connection of the capacitor to charge the storage battery. It is.

The method using multiple capacitors described above requires multiple capacitors in addition to the storage battery.

(2) The voltage boosted by these capacitors is n times the voltage generated by the solar cell, and is not necessarily of a size suitable for charging the storage battery. ■Since each capacitor used basically requires two selector switches, the circuit configuration becomes complicated.

There were some drawbacks.

These drawbacks are particularly problematic when solar cells are used to charge storage batteries which require a relatively large capacity, such as l'tl sources for lighting lamps or unmanned lighthouses.

In other words, the disadvantage of requiring multiple capacitors as described above is that it is necessary to use a capacitor with a certain capacity depending on the capacity of the storage battery to be charged, which directly increases the size of the entire device and increases the manufacturing cost. Connect. In addition, the disadvantage of the step-up voltage mentioned above in (①) is that it does not reach the desired value because it is stepped and does not reach the desired value.
Considering the situation where the voltage continuously decreases compared to the voltage generated for several hours before and after noon, which can be charged without a booster circuit, it is not suitable for practical use. Furthermore, the disadvantage of requiring a large number of changeover switches (2) above directly leads to an increase in the size of the device and a decrease in reliability when power transistors or relays are used depending on the magnitude of the charging current.

Plate Song ``° Runo, : Meno-1 The present invention addresses the above-mentioned conventional problems and improves them.Means for solving the problems include solar cells and a DC booster. - a DC converter, a monitoring unit that determines and outputs the output voltage of the solar cell after determining whether the pressure has reached a predetermined level at which the storage battery can be directly charged; and a switching circuit that switches the circuit connection so that when the level has reached the predetermined level, the voltage is directly supplied to the storage battery, and when the voltage has not reached the predetermined level, the voltage is boosted by a DC-DC converter and supplied to the storage battery. This is a distinctive solar cell circuit.

■ In the configuration means described above, the monitoring section monitors the voltage generated by the solar cell and controls the switching circuit, so that when the voltage generated by the solar cell is large, this directly causes the voltage to change. 3 batteries, and when the voltage generated by the solar cell drops and the storage battery cannot be directly charged, the voltage is boosted to a predetermined voltage using a DC-DC converter and then the storage battery is charged, so most of the energy generated by the solar cell is used by the storage battery. It is used to charge the battery.

Husband plate The present invention will be described according to one embodiment.

In Figure 1, (1) is a solar cell made of silicon, etc.
It is constructed by connecting a predetermined number of solar cells in series according to the voltage of the storage battery to be charged. (2) is DC-D
A C converter is used that has a characteristic that the output voltage remains approximately constant even if the input voltage fluctuates. (3) is a storage battery, in which secondary batteries such as nickel-cadmium batteries or lead-acid batteries are connected in series or in parallel to have the voltage and capacity corresponding to the load.F,! 7 will be completed. (4) is a backflow prevention diode, which is inserted and connected in series to the input line of one electrode of the storage battery (3). (5) is a monitoring unit that compares the output voltage of the solar cell with the voltage that can charge the storage battery (3), for example 24V, and determines whether it has exceeded that, and generates an ON output when it is 24V or higher, for example. do.

(6) is based on the output of the monitoring unit (5), and the solar cell (3)
, a switching circuit that switches the connection between the DC-DC converter (2) and the storage battery (1).
The normally open contact (6a) connects to the DC-DC converter (6a) and one electrode of the solar cell (1) when there is no ON output.
2) A relay with a normally closed contact (6b) connected to (3) is used. The configuration of this switching circuit (6) may be such that when the output voltage of the solar cell is above a predetermined level, it is input directly to the storage battery, and when it does not reach this level, it is input to the storage battery through the DC-DC converter. , can be configured arbitrarily. Further, this switching circuit (6) can also be constructed using a semiconductor element instead of a relay.

An example of the circuit of the DC-DC converter (2) is shown in FIG. In the same figure, (8) is an unstable multi-by break, (9) is a constant voltage circuit for driving the un-stable multi-by break, (10) is a boost I/lance, and (11) (1
1) is a power transistor, (12) is a resistor, (13)
is a charge/discharge capacitor, (14) is a full-wave rectifier, (15)
is a diode.

Note that the characteristics of the power conversion efficiency with respect to the input voltage of this DC-DC converter (2) are as shown in FIG.

In the above configuration, the operation under sunlight conditions as shown in FIG. 4 will be described.

After sunrise, when the amount of irradiation light is small and the output voltage of the solar cell (1) does not reach the reference voltage of 24V, the monitoring unit (5)
No N output is generated and the switching circuit (6) is normally closed contact (6b)
is kept closed. As a result, the DC-DC converter (2) boosts this voltage to 24V or more and transfers it to the storage battery (3).
supply to. In addition, the amount of irradiation light increases and the solar cell (1
) around noon when the output voltage of the monitor ( ) exceeds 24V.
5) generates an ON output, the switching circuit (6) switches the normally open contact (6a) to the closed state, and the output voltage of the solar cell (1) is directly supplied to the storage battery (3). . As dusk approaches and the amount of irradiation light decreases, the monitoring unit (5) switches the switching circuit (6) again to the state where the normally closed contact (6b) is closed, and the voltage boosted by the RLC-DC converter (2) Charge the storage battery (3).

Due to the above operation, the electrical energy generated in the solar cell (1) is effectively transferred to the storage battery (3) during almost all daylight hours.
) will be charged.

According to the present invention, when the output voltage of the solar cell is low,
By boosting the voltage using a DC-DC converter and supplying it to the storage battery, it becomes possible to effectively charge the storage battery with the energy of the solar cell during almost the entire daylight hours, increasing the efficiency of power supplies using solar cells. Especially when manufacturing a power supply with the same capacity as a conventional one, the solar cells, which are the most expensive part, can be made smaller in capacity than in the past, which is a great advantage as it reduces costs and reduces the installation area at the same time. .

[Brief explanation of drawings]

Fig. 1 is a circuit diagram of a solar cell circuit showing an embodiment of the present invention, Fig. 2 is a circuit diagram showing an example of a DC-DC converter used in the circuit of Fig. 1, and Fig. 3 is shown in Fig. 2. DC-DC
FIG. 4, which is a characteristic diagram of efficiency with respect to the input voltage of the converter, is a diagram showing an example of fluctuations in the output voltage of the solar cell in one day. (1) - Solar cell, (2) - DC-DC converter, (3) - Storage battery, (5) - Monitoring section, (6) - Switching circuit. Patent applicant: Fukaie Gyo Co., Ltd. Takubo Kogyo Co., Ltd.; Agent: Gangwon Province; June 21, 1988 Commissioner of the Japan Patent Office Kuro 1) Mr. Yu Aki 1, Indication of the case 1988 Patent Application No. 23622 2, Title of the invention Relationship with the case of the person who corrected the solar cell circuit 3.1ili Patent application Name: Fukaie Gyo Co., Ltd. (and 1 other person) 4, Agent: 8550 Address: 8th Floor, Osaka Shoko Building, 1-15-26 Edobori, Nishi-ku, Osaka, Osaka Name: (6458) Patent Attorney Sho Ehara 5, Amendment Target Specification and Drawing 6, ?iCorrect Contents 1> Page 2, Lines 6 to 10 ``The generated voltage will be within one day as shown in Figure 4''. , the energy conversion efficiency of the solar cell changes depending on the input impedance of the load, and the RA value of the input impedance of this load also changes depending on the change in the amount of irradiation light. If a load with input impedance is left as is even when the irradiation light Q of the solar cell is low, the energy conversion efficiency will be extremely poor, and the utilization rate of irradiation energy during this time period will be extremely poor. We will explain the voltage generated by a solar cell when a load is connected.In terms of solar cell output characteristics, the open-circuit voltage rises suddenly with a small amount of irradiation, and then rises in a gentle curve as the amount of irradiation increases. On the other hand, the G/Q current is approximately directly proportional to the amount of irradiation light, so when a certain storage battery load is connected, the voltage generated by the solar cell will decrease within a day, for example, as shown in Figure 4. ” he corrected. 2) Correct "generated energy" in lines 17 and 19 of page 2 to "irradiation energy". 3) Page 3, line 6, “Voltage generated by solar cells due to small amount of irradiation light” is changed to “Irradiation light 9
The voltage generated by the solar cell is so small that it cannot directly charge the storage battery. 4) Page 5, line 19 [From F', when the generated voltage of the solar cell is large, amend it to ``When the generated voltage of the solar cell connected to a predetermined load is larger than the rated charging voltage of the swamp battery.'' . 5) On page 6, lines 4 to 5, "The energy generated by solar cells is used." was corrected to "The energy irradiated to solar cells can be used effectively to charge storage batteries." do. 6) In the first line of page 7, "Compared with 24■" is corrected to "Compared with the rated charging voltage of the storage battery, 24V." 7) Page 7, lines 9 to 10 r I) C-D C converter (2) (3) j to rD
Correct as "C-DC comparator (2)". 8) Page 7, line 12, “output voltage is above a predetermined level” is corrected to “output voltage is the predetermined charging rated value p no upper 2 of the storage battery that is the load.” 9) Page 7, lines 13 to 14 Correct the line "to this level" to "to this value". 10) On page 8, line 13, "The output voltage is 24V ---" is corrected to "The output voltage is set according to the storage battery that is the load, for example, 24V --." 11) Page 8, line 17, ``The voltage is 24 V or higher'' is changed to ``The voltage is corrected to J, for example, 24 V or higher.'' 12) Page 8, line 19, ``The output voltage is 24 V J.'' For example, 24■'' is corrected. 13) Page 9, line 8, "The above operation reduces the sunshine hours" is changed to "The action of the DC-DC converter (2) in the above operation is to increase the input impedance on the load side as seen from the solar cell when the amount of irradiation light is small. This can be said to improve the energy conversion efficiency of solar cells.This effect corrects the amount of sunlight. 14) Page 9, line 9, “Electrical energy J generated in the solar cell (1) is corrected as irradiation energy j to solar type/l!x(1). 15) Page 9, line 12, “Output "The voltage is low" is corrected to "the output voltage is low compared to the rated charging voltage of the storage battery that is the load." 16) On page 9, line 15, "energy of solar cells" is corrected to "energy irradiated to solar cells." 17) Among the drawings, Figure 1 will be corrected as shown in the attached sheet.

Claims (1)

[Claims] (1) A solar cell, a DC-DC converter for boosting voltage,
a monitoring unit that determines and outputs whether the output voltage of the solar cell has reached a predetermined level at which the storage battery can be directly charged; and when the output voltage of the solar cell has reached the predetermined level based on the output of the monitoring unit. A solar cell circuit characterized by comprising: a switching circuit that switches the circuit connection so that the voltage is directly supplied to the storage battery, and when the voltage has not reached the predetermined level, the voltage is boosted by a DC-DC converter and supplied to the storage battery. .