JP3469678B2 - DC power supply system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a DC power supply system in which a DC power supply such as a solar cell is connected to a commercial power system via an inverter.

[0002]

2. Description of the Related Art In recent years, a DC power supply system has been put into practical use in which solar cells are installed in homes, factories or regions and are connected to a commercial power grid of an electric power company, and surplus power of the solar cells flows backward to the commercial power grid. Has been converted.

In this type of DC power supply system, solar cells are connected to a commercial power system via an inverter,
A home load is connected to the output terminal of the inverter. As a result, the output of the solar cell is converted from direct current to alternating current,
The AC power is supplied to the commercial power system and home loads.

By the way, in the conventional DC power supply system, the operation of the inverter is stopped when a power failure occurs in the commercial power system due to a disaster or a lightning strike. In order to effectively use the power generated by the solar cells, it is considered to operate the inverter independently with the grid connection to the commercial power system disconnected and supply the power from the solar cells to the household load. .

Further, as shown in FIG. 3 , a charge / discharge control circuit (62) is interposed between the DC power source (1) and the inverter (2) to cover the required power at night when a power failure occurs. The storage battery (71) is charged by the control circuit (62), and during the daytime, the electric power obtained by the independent operation of the inverter (2) is supplied to the domestic load (5), and the surplus power is stored in the storage battery ( A method of supplying the electric power to the domestic load (5) by charging the battery 71) and discharging the storage battery (71) at night is under study.

In this case, as the storage battery (71), a relatively small electric power (for example, 100 to 5) required for operating the minimum necessary equipment such as a lighting and a television receiver.
00W) should have a capacity that can cover the short period of about 10 hours including nighttime.

[0007]

However, in the conventional DC power supply system shown in FIG. 3 , the output of the storage battery (71) is charged and discharged with the breaker (4) opened due to the occurrence of a disaster or the like. When inputting to the inverter (2) via the control circuit (62) and thereby supplying the AC power obtained from the inverter (2) to the domestic load (5), the output of the storage battery (71) is 100 as described above. ~ 500W,
Rated output of the inverter (2) itself (for example, 3 to 5 kW)
Therefore, the operating efficiency of the inverter (2) is significantly reduced.

FIG. 4 exemplifies the efficiency characteristics of an inverter. At rated output, high efficiency exceeding 90% can be obtained, but when the output falls below 20%, the proportion of fixed loss increases. , The efficiency drops sharply.

Therefore, in the DC power supply system of FIG. 3 , the storage battery (71) needs to have a capacity which is obtained by adding the loss due to the decrease in efficiency to the required power. For example, if the efficiency drops to 30 percent, 3
In order to cover the power of 00 WH, the storage battery (71) needs a capacity of 1000 WH.

However, when the capacity of the storage battery (71) becomes large as described above, there is a possibility that the storage battery (71) cannot be charged in one day.

An object of the present invention is to provide a DC power supply system capable of converting the output of the storage battery into AC power with high efficiency and supplying it to the load even when the storage battery of small capacity is equipped. .

[0012]

A direct current power supply system according to the present invention has a basic configuration shown in FIG. 1 and has a small capacity at an output end of a direct current power supply (1) via a charge / discharge control circuit (61). The storage battery (7) is connected to the storage battery (7), and the output terminal of the storage battery (7) has a lower rated output than the main inverter (2) and a small capacity inverter (8) having a rated output corresponding to the capacity of the storage battery (7). ) Is connected to the small capacity inverter (8)
The emergency outlet (9) is connected to the output end of the power outlet, and when the commercial power system (3) fails, the DC power from the storage battery (7) passes through the small capacity inverter (8) to the emergency outlet (9). Is being supplied.

Further , the charge / discharge control circuit (61) has a DC input terminal and an AC input terminal, and the DC input terminal is a relay (10).
While being connected to the output end of the DC power supply (1) via the, the AC input end is connected to the power line between the main inverter (2) and the commercial power system (3).

[0014] shown in to other configurations in Figure 2, together with the output end of the small-capacity inverter (8) is connected to the emergency outlet (9) via a first relay (11), the first relay (11 ) To the emergency outlet (9),
The main inverter (2) and the power line between the commercial power system (3) are connected to each other via the second relay (12).

[0015]

In the basic structure shown in FIG. 1, the storage battery (7) is charged by the electric power obtained from the DC power supply (1). Then, when the output of the DC power supply (1) decreases, the DC power obtained by discharging the storage battery (7) is
It is supplied to the small capacity inverter (8). At this time, if the small-capacity inverter (8) is started and the minimum necessary load is connected to the emergency outlet (9), the AC power obtained from the small-capacity inverter (8) becomes
It will be supplied from the emergency outlet (9) to the minimum required load.

In addition , during normal interconnection operation, the relay (1
0) is opened and AC power from the commercial power system (3) is supplied to the AC input end of the charge / discharge control circuit (61) to charge the storage battery (7). When a power failure occurs, the relay (10) is closed and the electric power obtained from the DC power supply (1) is supplied to the DC input end of the charge / discharge control circuit (61) to charge the storage battery (7). When the output of the DC power supply (1) decreases, the DC power from the storage battery (7) is supplied to the small capacity inverter (8), and the AC power obtained from the small capacity inverter (8) passes through the emergency outlet (9). It will be supplied to the minimum required load.

[0017] In FIG. 2 shown to other configurations, in the normal interconnection operation, the first opening the relay (11) closes the second relay (12), the AC power from the commercial power system (3) Emergency outlet (9) via the second relay (12)
Supply to. This makes it possible to use the emergency outlet (9) not only in an emergency. At this time, the storage battery (7) is charged by the electric power obtained from the DC power supply (1).

Then, when the output of the DC power supply (1) decreases, the DC power obtained by discharging the storage battery (7) is supplied to the small capacity inverter (8). At this time, if the first relay (11) is closed and the second relay (12) is opened, the AC power obtained from the small-capacity inverter (8) will be the AC power obtained from the first relay (11) and the emergency outlet (9). ) Will be supplied to the minimum load required.

In any of the above constructions, the DC power obtained from the small capacity storage battery (7) is converted into AC by the small capacity inverter (8), so that the conversion efficiency is high. Here, if the rated output of the small capacity inverter (8) is made to correspond to the capacity of the storage battery (7), the maximum conversion efficiency can be obtained.

[0020]

According to the DC power supply system of the present invention, when a power failure occurs, the output of a small-capacity storage battery can be converted into AC power with high efficiency and supplied to the minimum load required.

[0021]

EXAMPLES Two examples in which the present invention is applied to a solar cell power generation system will be described in detail below with reference to the drawings. First Embodiment In the solar cell power generation system shown in FIG. 1, a DC power source (1) composed of solar cells is connected to a commercial power system (3) via a main inverter (2), and a main inverter (2 ) And the commercial power system (3), a breaker (4) is interposed, and a domestic load (5) is connected between the output end of the main inverter (2) and the breaker (4).

A small-capacity storage battery (7) is connected to the output end of the DC power supply (1) through a charge / discharge control circuit (61), and the charge / discharge control circuit (61) and the storage battery (7) are connected. A small capacity inverter (8) is connected to the point, and an emergency outlet (9) is connected to the output terminal of the small capacity inverter (8) .

The solar cell power generation system shown in FIG . 1 has a charge / discharge control circuit (61) having a DC input terminal and an AC input terminal.
The charging / discharging control circuit (61) is connected to the DC input terminal of the charging / discharging control circuit (61) via the relay (10), and the output terminal of the DC power supply (1) is connected to the charging / discharging control circuit (61). The AC input terminal of is connected to the power line between the main inverter (2) and the commercial power system (3).

During normal interconnection operation, the main inverter (2) is activated, while the relay (10) is opened so that the AC power obtained from the main inverter (2) is supplied to the domestic load (5). , Charge / discharge control circuit (6
1) and the storage battery (7) is charged.

When the output of the DC power supply (1) is reduced, the AC power obtained from the commercial power system (3) is supplied to the domestic load (5) via the breaker (4) and the charge / discharge control circuit is also supplied. It is supplied to the AC input terminal of (61) and the storage battery (7) is charged.

When a power failure occurs in the commercial power system (3) due to a disaster or the like, the breaker (4) is opened and the main inverter (2) shifts to the self-sustained operation mode. or,
The relay (10) is closed.

During the daytime, the output of the DC power supply (1) is supplied to the charge / discharge control circuit (6) via the relay (10), and the storage battery (7) is charged thereby.

On the other hand, when the output decreases at night or the like, the self-sustained operation of the main inverter (2) is stopped and the small capacity inverter (8) is started. As a result, the DC power from the storage battery (7) is supplied to the small capacity inverter (8),
The AC power output from the small capacity inverter (8) is supplied to the minimum required load through the emergency outlet (9).

Also in the solar cell power generation system of FIG.
By equipping the small-capacity inverter (8) having a rated output corresponding to the small-capacity storage battery (7), it is possible to sufficiently charge the storage battery (7) and operate the small-capacity inverter (8) with high efficiency.

Further, particularly in the solar cell power generation system of FIG. 1, the relay (10) is opened during the normal interconnection operation, so that the output voltage of the solar cell as the DC power source (1) depends on the voltage of the storage battery (7). Maximum power point tracking operation is possible without being affected. Second Embodiment In the solar cell power generation system shown in FIG. 2, the emergency outlet (9) is connected to the output end of the small capacity inverter (8) via the first relay (11) and the first relay (11) is connected.
And a power line between the emergency outlet (9) and the power between the main inverter (2) and the breaker (4) are connected to each other via the second relay (12).

During normal interconnection operation, the main inverter (2) is started and the first relay (11) is opened,
The second relay (12) is closed. As a result, the AC power from the main inverter (2) or the commercial power system (3) is supplied to the domestic load (5) via the breaker (4) and the emergency outlet via the second relay (12). (9) is supplied. As a result, it becomes possible to use the emergency outlet (9) not only in an emergency.

At this time, the electric power obtained from the DC power source (1) is supplied to the storage battery (7) by the charge / discharge control circuit (6), and the storage battery (7) is charged.

When a power failure occurs in the commercial power system (3) due to a disaster or the like, the breaker (4) is opened and the main inverter (2) shifts to the self-sustained operation mode. or,
The first relay (11) is closed and the second relay (12) is opened.

During the daytime, the output of the DC power supply (1) is supplied to the storage battery (7) by the charge / discharge control circuit (6), and the storage battery (7) is charged.

When the output of the DC power supply (1) decreases, the self-sustained operation of the main inverter (2) is stopped and the small capacity inverter (8) is started. As a result, the storage battery (7)
Is supplied to the small capacity inverter (8), and the AC power output from the small capacity inverter (8) is supplied to the emergency outlet (9) via the first relay (11). The electric power of the load is covered.

Similarly, in the solar battery power generation system shown in FIG. 2, a small capacity inverter (8) having a rated output corresponding to the small capacity storage battery (7) is provided to sufficiently charge the storage battery (7). It is possible to operate the small capacity inverter (8) with high efficiency.

In any of the solar cell power generation systems shown in FIGS. 1 and 2, the small capacity inverter (8) is operated independently from the main inverter (2), so the specifications of the small capacity inverter (8) are as follows: It can be selected regardless of the specifications of the main inverter (2) and can be freely designed.

Further, since an emergency power system different from the main power system from the DC power source (1) to the commercial power system (3) is constructed, the emergency power system is legal with respect to the main power system. It is not subject to the regulation, and it is possible to simplify incidental equipment.

The above description of the embodiments is for explaining the present invention, and should not be construed as limiting the invention described in the claims or limiting the scope. The configuration of each part of the present invention is not limited to the above-mentioned embodiment, and it goes without saying that various modifications can be made within the technical scope described in the claims.

For example, instead of the emergency outlet (9) of the above embodiment, a switching device or the like capable of automatically supplying the output of the small capacity inverter (8) to a part of the domestic load (5) is used. It is also possible to equip it.

In the above embodiment, the main inverter has the self-sustained operation mode, but the main inverter can be applied to a solar cell power generation system having no self-sustained operation mode.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a first embodiment of a DC power supply system using a solar cell.

FIG. 2 is a block diagram showing a configuration of a second embodiment of the same.

FIG. 3 is a block diagram showing a configuration of a conventional DC power supply system.

FIG. 4 is a graph showing a characteristic of conversion efficiency of an inverter.

[Explanation of symbols]

(1) DC power supply (2) Main inverter (3) Commercial power system (4) Breaker (5) Domestic load (6), (61) Charge / discharge control circuit (7) Storage battery (8) Small capacity inverter (9) Emergency outlet

Continuation of front page (56) Reference JP-A-6-189477 (JP, A) JP-A-4-29534 (JP, A) JP-A-2-111237 (JP, A) (58) Fields investigated (Int .Cl. ⁷ , DB name) H02J 9/06 504

Claims (2)

(57) [Claims] 1. In a DC power supply system in which a DC power supply is connected to a commercial power system via a main inverter and a domestic load is connected between the main inverter and the commercial power system, an output terminal of the DC power supply is provided. A storage battery is connected via the charge / discharge control circuit, and at the output end of the storage battery,
A small-capacity inverter having a rated output lower than that of the main inverter and having a rated output corresponding to the capacity of the storage battery is connected, an emergency outlet means is connected to the output end of the small-capacity inverter, and at the time of a power failure of the commercial power system, the DC power from the storage battery is supplied to the emergency outlet through the small capacity inverter , the charge and discharge control circuit has a DC input end and an AC input end,
The DC input terminal is connected to the output terminal of the DC power supply via relay means.
While the AC input terminal is connected to the main inverter and commercial power
DC power system connected to the power line between the power system
Mu. 2. A DC power supply is supplied via a main inverter.
Connected to the mains power system,
DC power system with household load connected between the power system
System, via a charge / discharge control circuit at the output end of the DC power supply
Then the storage battery is connected and at the output end of the storage battery,
Storage battery capacity with a lower rated output than the main inverter
Connected to a small capacity inverter with a rated output according to
Emergency outlet means connected to the output end of the capacity inverter
When the commercial power system fails, the storage battery
DC power from the emergency
Is supplied to a power outlet and the output end of the small capacity inverter is connected to the first relay means.
The first relay is connected to the emergency outlet means.
And the power line between the emergency outlet and the main inverter
And a power line between the commercial power system and the second relay means.
DC power supply system that is then connected to each other.