JP2014042425A - Surplus power charge device and charge control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to appropriately and efficiently perform charge in charging a storage battery connected to the same power distribution network with PV surplus power.SOLUTION: A device for performing charge with surplus power reversely flowing from a power generation device in a power distribution network connected to a pole transformer comprises: a storage battery which is connected to the power distribution network and stores the surplus power reversely flowing in the power distribution network; and a rectifier for supplying power received from the power distribution network to the storage battery. The rectifier determines impedance from reception voltage and reception current of AC power, and determines charge voltage to the storage battery on the basis of the reception current which causes a change of the impedance.

Description

  The disclosed invention relates to a surplus power charging apparatus, a charging control method, and the like.

  In recent years, there are an increasing number of cases in which a photovoltaic power generation (PV) is grounded to a consumer (for example, a house or a factory) that receives supply of AC power from a power plant. Of the power generated by PV, the surplus power (surplus power or PV surplus power) that is not consumed by the power consuming device in the consumer is output to the distribution network or power system. The flow of power from the consumer toward the power system is called “reverse power flow”. When PV spreads and each PV reversely flows surplus power, there is a concern that the system voltage rises to a predetermined value or more, the output of PV is suppressed, and the power generation efficiency of PV decreases. As one of the solutions to this problem, it is conceivable to install a PV surplus power charging device having a storage battery in a consumer where PV is installed and charge the PV surplus power (for this point, Patent Document 1). reference).

JP 2012-95465 JP

  However, the conventional PV surplus power charging apparatus has the following problems. In other words, the conventional PV surplus power charging device can be used only within the customer where it is installed, and it cannot be used when there is no storage battery in the customer, as well as when the storage battery is 100% charged, No more charging is possible. In order to solve this problem, it is conceivable to use not only a storage battery in a specific consumer but also another storage battery connected to the same distribution network. However, when using other storage batteries connected to the same distribution network, the surplus power necessary for reverse power flow from the customer to the power plant is charged to other storage batteries, or conversely from the customer to the power plant. There is a problem that surplus power more than the amount necessary for the reverse power flow to the battery is not properly charged in other storage batteries and is wasted. Thus, since the conventional PV surplus power charging apparatus does not have an index for charging other storage batteries, it has been difficult to efficiently perform charge control for other storage batteries without excess or deficiency.

  An object of the disclosed invention is to enable efficient charging without excess or deficiency when charging surplus PV power to a storage battery connected to the same distribution network.

The surplus power charging device according to the disclosed invention is:
In a distribution network connected to a pole transformer, a surplus power charging device that charges surplus power reversely flowed from a power generator,
A storage battery that is connected to the power distribution network and charges the surplus power that is reversely flowed to the power distribution network;
A rectifier that supplies power received from the power distribution network to the storage battery, and the rectifier determines impedance based on power information of the received power, and based on the received current that causes the change in impedance, the storage battery It is the surplus electric power charging device which determines the charging voltage to.

  According to the disclosed invention, when charging surplus PV power to a storage battery connected to the same distribution network, it can be efficiently charged without excess or deficiency.

The figure which shows the connection of the PV surplus electric power charging device and distribution network by embodiment. The block diagram of the PV surplus electric power charging device by embodiment. The figure which shows the voltage profile of the distribution network to which the PV surplus electric power charging device by embodiment is connected (at the time of PV output surplus). The figure which shows the voltage profile of the power distribution network to which the PV surplus power charging device by embodiment is connected (when PV output is not surplus). The figure which shows the impedance change which the PV surplus electric power charging device by embodiment utilizes. The flowchart for performing charge control of the PV surplus electric power charging device by embodiment. The figure which shows the voltage profile of the distribution network to which the PV surplus electric power charging device by another embodiment was connected (at the time of PV output surplus). The figure which shows the voltage profile of the distribution network to which the PV surplus electric power charging device by another embodiment was connected (when PV output is not surplus). The figure which shows the impedance change which the PV surplus electric power charging device by another embodiment utilizes. The flowchart for performing charge control of the PV surplus electric power charging device by another embodiment.

  Embodiments will be described from the following viewpoints with reference to the accompanying drawings. In the figures, similar elements are given the same reference numbers or reference signs.

1． Connection between PV surplus power charger and distribution network
2． Configuration of PV surplus power charger
3． Operating principle
Four. Charge control operation example
Five. Another embodiment
6． Effects of the embodiments The classification of these items is not essential to the present invention, and the items described in two or more items may be used in combination as necessary. It may apply to matters described in other items (unless inconsistent).

<1. Connection between PV surplus power charger and distribution network>
FIG. 1 shows a connection between a PV surplus power charging apparatus and a distribution network according to an embodiment. A pole transformer 102 is connected to the high voltage distribution network 101, and a low voltage distribution network 103 is formed below the pole transformer 102. A consumer 11 and a PV surplus power charging device 12 are connected to the low voltage distribution network 103. For simplicity of explanation and illustration, only one customer 11 and one PV surplus power charging device 12 are shown, but the number thereof is arbitrary. While the consumer 11 consumes electric power, the surplus electric power is caused to flow backward by performing solar power generation. Customer 11 is a photovoltaic power generation device (PV) 111, a power conditioner (power conditioner) 112 that performs DC and AC power conversion, and power that consumes power supplied from the low-voltage distribution network 103 or the photovoltaic power generation device 111. And a consuming device 113. Of the power generated by the photovoltaic power generation device (PV) 111, the surplus power (surplus power or PV surplus power) that is not consumed by the power consuming device 113 is output to the low-voltage distribution network 103 (reverse power flow). . When the solar power generation device (PV) 111 outputs surplus power, the system voltage or the photovoltaic power generation voltage V _PV rises, but the system voltage V _PV is limited to a predetermined limit value V _LIMIT or less, such as 107v. The output of the photovoltaic power generator (PV) is suppressed. For this reason, the power generation efficiency of the photovoltaic power generation device (PV) decreases.

  The PV surplus power charging device 12 receives surplus power from the solar power generation device (PV) of the customer 11 connected to the same low voltage distribution network 103 in order to improve the power generation efficiency of the solar power generation device (PV) 111. Charge. The PV surplus power charging device 12 includes a storage battery 121 and a rectifier 122. The PV surplus power charging device 12 charges surplus power of the demanding 11 that owns it, but in this configuration, it can also charge surplus power of other demanding 11 connected to the low voltage distribution network 103 Thus, it is significantly different from the conventional configuration. Details of the PV surplus power charging device 12 will be described with reference to FIG.

  Note that in FIG. 1 and the following description, power obtained by solar power generation is reversely flowed, but it is not essential for the disclosed invention that the power generation method uses solar light. The disclosed invention is applicable to a case where power generated by solar thermal power generation, geothermal power generation, wind power generation, hydroelectric power generation, marine power generation, thermal power generation, or any other appropriate method is reversely flowed to a power plant.

<2. Configuration of PV surplus power charger>
FIG. 2 shows a detailed functional block diagram of the PV surplus power charging device 11 shown in FIG. The PV surplus power charging device 12 includes a storage battery 121 and a rectifier 122. The storage battery 121 is charged with electric power supplied via the low-voltage distribution network (103 in FIG. 1) and the rectifier 122, and supplies electric power as necessary. The power supplied to the storage battery 121 via the rectifier 122 is typically surplus power from the photovoltaic power generation device (PV) connected to the low voltage distribution network 103.

  The rectifier 122 includes a rectifier 21, a commercial power supply impedance detector 22, a storage battery voltage detector 23, a voltage controller 24, and a DC / DC converter 25.

  The rectifier 21 converts an AC voltage and an AC current of a commercial power source into a DC voltage and a DC current.

The commercial power supply impedance detection unit 22 detects the received voltage V _{REC_AC} and the received current I ₂ from the AC power supply, thereby determining the impedance (dV _{REC_AC} / dI ₂ ), and transmits the impedance to the voltage control unit 24. Note that it is not essential for the embodiment to determine or measure both the received voltage V _{REC_AC} and the received current I ₂ . For example, the relationship between the received voltage V _{REC_AC} and the impedance may be examined in advance, and the impedance change point may be estimated from the value of the received voltage V _{REC_AC} . Alternatively, the relationship between the received current I ₂ and the impedance may be examined in advance, and the impedance change point may be estimated from the value of the received current I ₂ . That is, the commercial power supply impedance detection unit 22 can determine the impedance change point from the power information indicating both or one of the received voltage V _{REC_AC} and the received current I ₂ .

  The storage battery voltage detection unit 23 detects the voltage of the storage battery 121 and transmits the voltage of the storage battery 121 to the output voltage control unit 24.

  The output voltage control unit 24 sends a command to the DC / DC converter 25 based on the impedance and voltage notified from the commercial power source impedance detection unit 22 and the storage battery voltage detection unit 23.

  The DC / DC converter 25 determines a charging voltage for charging the storage battery 121 based on a command from the output voltage control unit 24.

<3. Principle of operation>
The operation principle of the embodiment will be described with reference to FIG. 3, FIG. 4 and FIG. FIG. 3 shows a state in which surplus power from the photovoltaic power generation device (PV) 111 of the customer 11 is supplied to the high-voltage distribution network 101 and the storage battery 121 via the low-voltage distribution network 103. It should be noted that, for the sake of simplicity, only the photovoltaic power generation device (PV) 111 and the power conditioner (power conditioner) 112 are shown among the elements provided in the consumer 11. In the illustrated example, the system voltage or the photovoltaic power generation voltage V _PV reaches a limit value V _LIMIT of 107 v, and surplus power flows through both the high-voltage distribution network 101 and the storage battery 121. The reverse flow current I ₁ from the customer 11 to the high voltage distribution network 101 shows a constant value. This is because the photovoltaic power generation voltage V _PV is limited to 107v. In this case, the surplus power generated by the photovoltaic power generation device (PV) is still left even if the reverse power flow is performed to the high voltage distribution network 101 side, and thus the surplus power should be charged to the storage battery 121. That is, in this case, there is a capacity to charge the storage battery (this state is referred to as a PV output surplus time). As shown in the figure, the voltage (rectifier voltage) V _{REC_AC} received by the rectifier 121 that controls the charging of the storage battery 121 can be written as follows.

V _{REC_AC} = V ₀ + R ₁ I ₁ −R ₂ I ₂ (1)
Here, V ₀ is a constant voltage in the pole transformer 102 in the low voltage distribution network 103. R ₁ and I ₁ are the resistance (impedance) in the transmission line from the customer 11 to the pole transformer 102 and the current flowing through the transmission line. R ₂ and I ₂ are the resistance (impedance) in the transmission line from the customer 11 to the PV surplus power charging device 12 and the current flowing through the transmission line. In Formula (1), V ₀ , R ₁ , R ₂ and I ₁ are constant values. Therefore, the rectifier voltage V _{REC_AC} depends only on the received current I _2. More specifically, the rectifier voltage V _{REC_AC} is linearly proportional to the received current I ₂ , and the proportional coefficient is (−R ₂ ).

On the other hand, the photovoltaic power generation voltage V _PV by the customer 11 may be less than the limit value V _LIMIT such as 107v. FIG. 4 also shows how surplus power from the photovoltaic power generation device (PV) 111 of the customer 11 is supplied to the high-voltage distribution network 101 and the storage battery 121 via the low-voltage distribution network 103. However, since the system voltage or the photovoltaic power generation voltage V _PV does not reach the limit value V _LIMIT of 107 v, the photovoltaic power generation device (PV) 111 can flow the maximum current I _MAX . A part of this current I _MAX flows to the storage battery 121, and the remaining current flows to the high voltage distribution network 101. That is, when the storage battery 121 is charged, the power to be reversely flowed to the high voltage distribution network 101 is reduced. Therefore, in such a case, priority should be given to reverse surplus power generated by the photovoltaic power generation device (PV) to the high-voltage distribution network 101 side, and charging of the storage battery 121 should be refrained. That is, in this case, there is no capacity to charge the storage battery (this state is referred to as a PV output non-surplus). As shown in the figure, the voltage (rectifier voltage) V _{REC_AC} received by the rectifier 121 that controls the charging of the storage battery 121 can be written as follows.

V _{REC_AC} = V ₀ + R ₁ I ₁ −R ₂ I ₂
＝ V ₀ + R ₁ (I _MAX -I ₂ ) −R ₂ I ₂
= V ₀ + R ₁ I _MAX- (R ₁ + R ₂ ) I ₂ (2)
In Equation (2), V ₀ , R ₁ , R ₂ and I _MAX are constant values. Therefore, the rectifier voltage V _{REC_AC} depends only on the received current I ₂ , more specifically, the rectifier voltage V _{REC_AC} is linearly proportional to the received current I ₂ , and the proportionality coefficient is (− (R ₁ + R ₂ )) It is.

FIG. 5 is a diagram for explaining the case shown in FIGS. 3 and 4 from the viewpoint of the rectifier voltage V _{REC_AC} and the charging current I ₂ . As described with reference to FIG. 3, when there is a surplus power to charge the storage battery 121, the impedance that is the ratio of the rectifier voltage V _{REC_AC} and the charging current I ₂ is R ₂ . On the other hand, as described with reference to FIG. 4, when there is no surplus power to charge the storage battery 121, the impedance that is a ratio of the rectifier voltage V _{REC_AC} and the charging current I ₂ is (R ₁ + R ₂ ). is there. Therefore, if the rectifier voltage V _{REC_AC} and the charging current I ₂ near the boundary when there is surplus and when there is no surplus can be maintained, the surplus power is transferred to the storage battery 121 without excess or deficiency while promoting reverse power flow to the high voltage distribution network 101 side. Can be charged. In the embodiment, the rectifier 122 controls the charging current I ₂ to the storage battery 121 based on such an operation principle.

<4. Charge control operation example>
FIG. 6 is a flowchart illustrating an operation example of the PV surplus power charging device 12 (particularly, the rectifier 122) according to the embodiment. The flow begins at step 61 and proceeds to step 62.

In step 62, PV surplus power charging device 12 increases the charging current I ₂ to the battery 121. The lower limit value of the range of the charging current I ₂ is, for example, 0 ampere, and the upper limit value is, for example, the maximum current that can be passed through the device. The increase amount of the charging current I ₂ may be any appropriate value. Increasing gradually charging current I ₂ from the lower limit value corresponds to trace the graph of FIG. 5 from left to right.

In Step 63, the PV surplus power charging device 12 _{obtains the} impedance from the ratio of the rectifier voltage V _{REC_AC} and the charging current I ₂ and determines whether or not the impedance has increased. In the graph shown in FIG. 5, the impedance is R ₂ when there is a surplus power charging capacity, and R ₁ + R ₂ when there is no surplus power charging capacity. If the impedance has not increased, the flow returns to step 62 and the described procedure is performed. If the impedance has increased, the flow proceeds to step 64.

In step 64, PV surplus power charging device 12 reduces the charging current I _2.

In Step 65, the PV surplus power charging device 12 _{obtains the} impedance from the ratio of the rectifier voltage V _{REC_AC} and the charging current I ₂ and determines whether or not the impedance is reduced. If not, the flow returns to step 64 and the described procedure is performed. If the impedance decreases, the flow returns to step 62 and the described procedure is performed.

  Note that the increase amount that increases the charging current in step 62 and the decrease amount that decreases the charging current in step 64 may be the same, or one may be less than the other. Furthermore, the increase amount and / or the decrease amount may be variably controlled. For example, when returning to step 62 via step 65, the increment used in step 62 may be less than the previously used value. This is so that the impedance change point can be gradually approached.

Further, in step 63 and 55, PV surplus power charging device 12, the rectifier is a voltage V _{REC_AC} seeking impedance from the ratio of the charging current I _2, the rectifier voltage V _{REC_AC} and determining or measuring both the charging current I ₂ This is not essential to the embodiment. For example, the relationship between the rectifier voltage V _{REC_AC} and the impedance may be examined in advance, and the impedance change point may be estimated from the value of the rectifier voltage V _{REC_AC} . Alternatively, the relationship between the charging current I ₂ and the impedance may be examined in advance, and the impedance change point may be estimated from the value of the charging current I ₂ . Therefore, the PV surplus power charging device 12 can determine the impedance change point from the power information indicating both or one of the rectifier voltage V _{REC_AC} and the charging current I ₂ .

_Maintaining the charging current I ₂ and the rectifier voltage V _{REC_AC} near the optimum region in FIG. 5 (or converging the charging current I ₂ to the optimum value) by increasing / decreasing the charging current I ₂ while performing such control. Can do. Thus, according to the illustrated operation example, the charging current I ₂ is increased or decreased, the accompanying increase or decrease in impedance is detected, and the charging current I ₂ is feedback-controlled.

<5. Another embodiment>
As described above, for simplification of illustration, only one customer 11 and one PV surplus power charging device 12 are illustrated, but the number thereof is arbitrary. Even if two or more PV surplus power charging devices 12 are arranged in the same distribution network (low-voltage distribution network 103), the impedance that is the ratio of the received voltage or rectifier voltage V _{REC_AC} and the charging current I ₂ There is no difference in changing.

  In the example shown in FIG. 1, FIG. 3 and FIG. 4, in the low voltage distribution network 103, the customer 11 is located between the pole transformer 102 connected to the high voltage distribution network 101 and the PV surplus power charging device 12. However, this is not essential for the disclosed invention, and the disclosed invention is applicable to other arrangements. For example, the PV surplus power charging device 12 may be positioned between the pole transformer 102 connected to the high-voltage distribution network 101 and the customer 11.

FIG. 7 shows that in the form where the PV surplus power charging device 12 is located between the pole transformer 102 and the customer 11, the surplus power by the photovoltaic power generation device (PV) 111 of the customer 11 is A state of being supplied to the high-voltage distribution network 101 and the storage battery 121 via 103 is shown. It should be noted that, for the sake of simplicity, only the photovoltaic power generation device (PV) 111 and the power conditioner (power conditioner) 112 are shown among the elements provided in the consumer 11. In the illustrated example, the system voltage or the photovoltaic power generation voltage V _PV reaches a limit value V _LIMIT of 107 v, and surplus power flows through both the storage battery 121 and the high-voltage distribution network 101. In the illustrated example, the photovoltaic power generation voltage V _PV is limited to 107v. In this case, the surplus power generated by the photovoltaic power generation device (PV) is still left even if the reverse power flow is performed to the high voltage distribution network 101 side, and thus the surplus power should be charged to the storage battery 121. That is, in this case, there is a capacity to charge the storage battery (this state is referred to as a PV output surplus time). As shown in the figure, the voltage (rectifier voltage) V _{REC_AC} received by the rectifier 121 that controls the charging of the storage battery 121 can be written as follows.

V _PV = V _LIMIT = V _{REC_AC} + R ₂ (I ₁ + I ₂ )
V _{REC_AC} = V _LIMIT −R ₂ I ₁ −R ₂ I ₂ (3)
Here, R ₁ and I ₁ are the resistance (impedance) in the transmission path from the PV surplus power charging device 12 to the pole transformer 102 and the current flowing through the transmission path. R ₂ and I ₂ are the resistance (impedance) in the transmission path from the customer 11 to the PV surplus power charging device 12 and the current flowing into the PV surplus power charging device 12. In Equation (3), V _LIMIT , R ₁ , R ₂ and I ₁ are constant values. Therefore, the rectifier voltage V _{REC_AC} depends only on the received current I _2. More specifically, the rectifier voltage V _{REC_AC} is linearly proportional to the received current I ₂ , and the proportional coefficient is (−R ₂ ).

On the other hand, the photovoltaic power generation voltage V _PV by the customer 11 may be less than the limit value V _LIMIT such as 107v. FIG. 8 also shows how surplus power from the photovoltaic power generation device (PV) 111 of the customer 11 is supplied to the high-voltage distribution network 101 and the storage battery 121 via the low-voltage distribution network 103. However, since the system voltage or the photovoltaic power generation voltage V _PV does not reach the limit value V _LIMIT of 107 v, the photovoltaic power generation device (PV) 111 can flow the maximum current I _MAX . A part of this current I _MAX flows to the storage battery 121, and the remaining current flows to the high voltage distribution network 101. That is, when the storage battery 121 is charged, the power to be reversely flowed to the high voltage distribution network 101 is reduced. Therefore, in such a case, priority should be given to reverse surplus power generated by the photovoltaic power generation device (PV) to the high-voltage distribution network 101 side, and charging of the storage battery 121 should be refrained. That is, in this case, there is no capacity to charge the storage battery (this state is referred to as a PV output non-surplus). As shown in the figure, the voltage (rectifier voltage) V _{REC_AC} received by the rectifier 121 that controls the charging of the storage battery 121 can be written as follows.

V _{REC_AC} = V ₀ + R ₁ I ₁
= V ₀ + R ₁ (I _MAX -I ₂ )
= V ₀ + R ₁ I _MAX −R ₁ I ₂ (4)
In Equation (4), V ₀ , R ₁ and I _MAX are constant values. Therefore, the rectifier voltage V _{REC_AC} depends only on the received current I _2. More specifically, the rectifier voltage V _{REC_AC} is linearly proportional to the received current I ₂ , and the proportionality coefficient is (−R ₁ ).

FIG. 9 is a diagram for explaining the cases shown in FIGS. 7 and 8 from the viewpoint of the rectifier voltage V _{REC_AC} and the charging current I ₂ . As described with reference to FIG. 7, when there is a surplus power to charge the storage battery 121, the impedance that is a ratio of the rectifier voltage V _{REC_AC} and the charging current I ₂ is R ₂ . On the other hand, as described with reference to FIG. 8, when there is no surplus power to charge the storage battery 121, the impedance that is the ratio of the rectifier voltage V _{REC_AC} and the charging current I ₂ is R ₁ . Therefore, if the rectifier voltage V _{REC_AC} and the charging current I ₂ near the boundary when there is surplus and when there is no surplus can be maintained, the surplus power is transferred to the storage battery 121 without excess or deficiency while promoting reverse power flow to the high voltage distribution network 101 side. Can be charged. Based on such a principle, the rectifier 122 may control the charging current I ₂ to the storage battery 121.

  FIG. 10 is a flowchart showing an operation example of the PV surplus power charging device 12 (particularly, the rectifier 122) in another embodiment. The flow begins at step 101 and proceeds to step 102.

In step 102, PV surplus power charging device 12 increases the charging current I ₂ to the battery 121. The lower limit value of the range of the charging current I ₂ is, for example, 0 ampere, and the upper limit value is, for example, the maximum current that can be passed through the device. The increase amount of the charging current I ₂ may be any appropriate value. Increasing gradually charging current I ₂ from the lower limit value corresponds to trace the graph of FIG. 9 from left to right.

In step 103, PV surplus power charging device 1 ₂ calculates the impedance from the ratio of the rectifier voltage V _{REC_AC} and the charging current I _2. In the case of the graph shown in FIG. 9, the impedance is R ₂ when there is a surplus power for charging surplus power, and R ₁ when there is no surplus power for charging surplus power. If the impedance is a R ₂ flow returns to step 102, and the procedure described above is performed. If the impedance is R ₁ , the flow proceeds to step 104.

In step 104, PV surplus power charging device 12 reduces the charging current I _2.

In step 105, the PV surplus power charging device 12 obtains the impedance from the ratio between the rectifier voltage V _{REC_AC} and the charging current I ₂ . When the impedance was R _1, the flow returns to step 104, and the procedure described above is performed. When the impedance was R _2, the flow returns to step 102, and the procedure described above is performed.

As in the case of FIG. 6, the increase amount that increases the charging current in step 102 and the decrease amount that decreases the charging current in step 104 may be the same, or one may be less than the other. . Furthermore, the increase amount and / or the decrease amount may be variably controlled. Further, in step 103 and 105, PV surplus power charging device 12, the rectifier is a voltage V _{REC_AC} seeking impedance from the ratio of the charging current I _2, the rectifier voltage V _{REC_AC} and determining or measuring both the charging current I ₂ This is not essential to the embodiment. For example, the relationship between the rectifier voltage V _{REC_AC} and the impedance may be examined in advance, and the impedance change point may be estimated from the value of the rectifier voltage V _{REC_AC} . Alternatively, the relationship between the charging current I ₂ and the impedance may be examined in advance, and the impedance change point may be estimated from the value of the charging current I ₂ . Therefore, the PV surplus power charging device 12 can determine the impedance change point from the power information indicating both or one of the rectifier voltage V _{REC_AC} and the charging current I ₂ .

_Maintaining the charging current I ₂ and the rectifier voltage V _{REC_AC} near the optimum region in FIG. 9 (or converging the charging current I ₂ to the optimum value) by increasing / decreasing the charging current I ₂ while performing such control. Can do. According to this operation example, the charging current I ₂ can be increased or decreased, the accompanying increase or decrease in impedance can be detected, and the charging current I ₂ can be feedback controlled.

<6. Advantages of the embodiment>
The PV surplus power charging device 12 according to the embodiment charges surplus power reversely flowed from the photovoltaic power generation device (PV) 111 in the low voltage distribution network 103 below the pole transformer 102. This device is connected to the low-voltage distribution network 103 and receives the AC power V _{REC_AC} from the low-voltage distribution network 103 and the storage battery 121 that charges the surplus power that has flowed back to the low-voltage distribution network 103, and converts the AC power into DC power. And a rectifier 122 for supplying DC power to the storage battery. The rectifier 122 detects the received voltage V _{REC_AC} from the AC power and the received current I ₂ to determine or measure the impedance, detects the output voltage of the storage battery 121, and determines the charging voltage to the storage battery 121, the impedance and the output of the storage battery Determine from voltage. Thereby, the charging power of the storage battery 121 can be optimally controlled.

  The PV surplus power charging device 12 according to the embodiment is based on the fact that the impedance changes between the output surplus time and the non-output surplus time of the solar power generation device (PV) 111. Is detected, and charging of the storage battery 121 is controlled. Charging to the storage battery 121 is controlled with the impedance change point, that is, the change point when the output is excessive and when the output is not excessive, as a target. With the configuration in which the charging of the storage battery 121 is controlled so that the impedance converges at the impedance change point, the charging power can be suppressed to the minimum necessary.

  The PV surplus power charging device 12 according to the embodiment can not only improve the PV power generation efficiency, but also can suppress the charging power to the storage battery 121 to the minimum necessary. Furthermore, according to the embodiment, not only can the burden of the existing storage battery be reduced, but also the capacity of the newly installed storage battery can be minimized, leading to an effect of reducing costs.

  As mentioned above, while giving priority to the reverse power flow to the high-voltage distribution network side, the embodiment for charging the storage battery without excess or deficiency has been described, but the disclosed invention is not limited to such a form, and those skilled in the art Various variations, modifications, alternatives, substitutions, etc. will be understood. Although specific numerical examples have been described in order to facilitate understanding of the invention, these numerical values are merely examples and any appropriate values may be used unless otherwise specified. In addition, although specific mathematical formulas have been used to facilitate understanding of the invention, these mathematical formulas are merely examples unless otherwise specified, and other mathematical formulas that yield similar results may be used. Good. The classification of items in the above description is not essential to the present invention, and the items described in two or more items may be used in combination as necessary, or the items described in one item may be used in different items. It may apply to the matters described in (as long as there is no conflict). The boundaries between functional units or processing units in the functional block diagram do not necessarily correspond to physical component boundaries. The operations of a plurality of functional units may be physically performed by one component, or the operations of one functional unit may be physically performed by a plurality of components. For convenience of explanation, the communication terminal and the information processing apparatus have been described using functional block diagrams. However, such an apparatus may be realized by hardware, software, or a combination thereof. Software operating in accordance with the present invention includes random access memory (RAM), flash memory, read only memory (ROM), EPROM, EEPROM, registers, hard disk (HDD), removable disk, CD-ROM, database, server and other suitable It may be stored in any storage medium. The present invention is not limited to the above embodiments, and various modifications, modifications, alternatives, substitutions, and the like are included in the present invention without departing from the spirit of the present invention.

101 High voltage distribution network
102 pole transformer
103 Low voltage distribution network
11 Consumer
111 Solar power generator
112 Power conditioner
113 Power consumption device
12 PV surplus power charger
121 battery
122 Rectifier
21 Rectifier
22 Commercial power supply impedance detector
23 Battery voltage detector
24 Voltage controller
25 DC / DC converter

Claims (3)

In a distribution network connected to a pole transformer, a surplus power charging device that charges surplus power reversely flowed from a power generator,
A storage battery that is connected to the power distribution network and charges the surplus power that is reversely flowed to the power distribution network;
A rectifier that supplies power received from the power distribution network to the storage battery, and the rectifier determines impedance based on power information of the received power, and based on the received current that causes the change in impedance, the storage battery A surplus power charging device that determines the charging voltage to.   2. The surplus power charging device according to claim 1, wherein the rectifier determines the impedance from the received voltage and received current received from the distribution network when determining the impedance from the power information of the received power. In the distribution network connected to the pole transformer, a charge control method executed by a device for charging surplus power reversely flowed from the power generation device,
The apparatus includes a storage battery that is connected to the power distribution network and charges the surplus power that has been reversely flowed to the power distribution network, and a rectifier that supplies power received from the power distribution network to the storage battery,
The charge control method includes a step of determining an impedance from power information of the received power and determining a charge voltage to the storage battery based on a received current that causes a change in the impedance.

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