US20140319914A1

US20140319914A1 - Battery system and its control method

Info

Publication number: US20140319914A1
Application number: US14/330,107
Authority: US
Inventors: Youjirou Nomura
Original assignee: NEC Corp
Current assignee: NEC Corp
Priority date: 2011-07-15
Filing date: 2014-07-14
Publication date: 2014-10-30
Also published as: US20130154570A1; EP2605359A4; JP6156919B2; EP2605359A1; JP2015159726A; US8810202B2; EP2605359B1; EP3151331A1; CN103168404A; JP2013179836A; BR112013006740A2; WO2013011758A1; JPWO2013011758A1; JP5327407B2

Abstract

A battery system includes a battery, a control section that controls the battery to charge electric power supplied from the electrical grid and to discharge electric power to the electrical grid; and a system controller. The system controller controls the control section such that the battery system operates in a first mode where electric power that is generated by a pre-designated distributed electric power source associated with the electrical grid is supplied preferentially to a user's load or in a second mode where electric power that is charged in the battery is supplied preferentially to the user's load.

Description

This is a divisional application based upon U.S. patent application Ser. No. 13/818,039 filed Feb. 20, 2013, which is a National Stage of International Application No. PCT/JP2012/064462 filed Jun. 5, 2012, claiming priority based on Japanese Patent Application No. 2011-156561 filed Jul. 15, 2011, the contents of all of which are incorporated herein by reference in their entirety.

TECHNICAL FIELD

The present invention relates to a battery system that is operable in association with an electrical grid (commercial electric power) and to its control method.

BACKGROUND ART

In order to achieve a low carbon society, distributed electric power sources such as photo voltage generation and wind farms are becoming essential. In addition, battery systems have been implemented so as to effectively use electric power generated by distributed electric power sources and rigid power sources (for example, nuclear power plants) that emit less carbon and that stably generate electric power.
In particular, since renewable electric power sources are subject to fluctuations of output electric power that depends on weather conditions, it is preferable that they be used together with a battery system so as to relatively stably supply desired electric power to the users.
An in-house electric power generation system provided with both a distributed electric power source such as a distributed electric power source or a fuel battery and a battery is described for example in Patent Literature 1.
To accelerate the promotion of the foregoing distributed electric power sources and battery systems, it is preferred that the users be able to enjoy high economic effects when they use electric power. For example, it is preferable that the power rates of the electric grid be reduced by prioritizing the supply of electric power generated by a renewable electric power source or electric power charged to a battery system to the user's load (electric equipment). In addition, it is preferable that surplus electric power that is not used for the user's load be sold to an electric power company. However, some users prioritize the use of electric power generated from natural energy (green electric power), not economic effects. Thus, it is preferable that a renewable electric power source and a battery system be operable in an operation mode that is optimum for each user.
On the other hand, renewable electric power sources and battery systems are still expensive. Thus, the user may not implement both a renewable electric power source and a battery system at the same time. Thus, it is preferable that a renewable electric power source and a battery system be independently operable in association with the electric grid.

RELATED ART LITERATURE

Patent Literature

Patent Literature 1: Japanese Patent Laid-Open No. 2011-003449

SUMMARY

Therefore, an object of the present invention is to provide a battery system that is independently operable in association with an electric grid and in an operation mode that is optimum for each user and also to provide its control method.
To accomplish the foregoing object, a battery system according to an exemplary aspect of the present invention is a battery system that is operable in association with an electrical grid, the battery system comprising:
a battery that charges or discharges electric power;
a control section that controls said battery to charge electric power supplied from said electrical grid and to discharge electric power to said electrical grid; and
a system controller that controls said control section such that said battery system operates in a first mode where electric power that is generated by a pre-designated distributed electric power source associated with said electrical grid is supplied preferentially to a user's load or in a second mode where electric power that is charged in said battery is supplied preferentially to said user's load.
On the other hand, a control method for a battery system according to an exemplary aspect of the present invention is a control method for a battery system that is operable in association with an electrical grid, the battery system including:
a battery that charges or discharges electric power; and
a control section that controls said battery to charge electric power supplied from said electrical grid and to discharge electric power to said electrical grid,
the control method comprising:
causing a computer to control said control section such that said battery system operates in a first mode where electric power generated by a pre-designated distributed electric power source associated with said electrical grid is supplied preferentially to a user's load or in a second mode where electric power that is charged in said battery is supplied preferentially to said user's load.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram showing an example of the structure of a battery system according to the present invention.

FIG. 2 is a block diagram showing the structure of principal sections of the battery system shown in FIG. 1.

FIG. 3 is a flow chart showing an example of a process in which the battery system shown in FIG. 2 performs in a PV priority mode.

FIG. 4 is a flow chart showing an example of a process in which the battery system shown in FIG. 2 performs in a charging priority mode.

EXEMPLARY EMBODIMENT

Next, with reference to the accompanying drawings, the present invention will be described.
FIG. 1 is a block diagram showing an example of the structure of a battery system according to the present invention.
As shown in FIG. 1, the battery system has battery pack 10 that charges or discharges electric power; BMU (Battery Management Unit) 20 that protects battery pack 10 from overcharging, overdischarging, over current, and so forth; power conditioner (PCS) 30 that converts electric power such that battery pack 10 is operable in association with the electric grid and that controls charging of electric power to battery pack 10 and discharging electric power therefrom; and system controller 40 that controls the overall operations of the battery system including BMU 20 and PCS 30. Although FIG. 1 shows an example of the structure in which two battery packs 10 are connected in parallel, it should be appreciated that one battery pack 10 or three or more battery packs 10 may be used.
The electrical grid is used in association with both PV system 50 and the battery system. PV system 50 has PV (Photo Voltaic) panel 51 that uses solar light to generate electric power and PV power conditioner (PV PCS) 52 that converts DC electric power generated by PV panel 51 into AC electric power that can be supplied to the electrical grid. PV system 50 is a distributed electric power source (small power generation facility) that is independent from the battery system. The battery system and PV system 50 are operated in association with the electrical grid through a distribution board located in the user's house.
Power conditioner 30 is provided with DC/AC bidirectional inverter 31 that converts AC electric power supplied from the electrical grid to DC electric power that can be charged to battery pack 10 and converts DC electric power discharged from battery pack 10 into AC electric power that can be supplied to the load and the electrical grid; and control section 32 that controls the operation of power conditioner 30 including DC/AC bidirectional inverter 31 corresponding to a command issued from system controller 40 and that monitors the operation of BMU 20. Power conditioner 30 shown in FIG. 1 is operable in association with the electrical grid through electric power line 33 such that power conditioner 30 supplies electric power to the user's load through electric power line 33.
Battery pack 10 is provided with a battery (secondary battery) that can charge or discharge electric power. The battery is, for example, a lithium ion rechargeable battery, a nickel cadmium (NI—Cd) battery, or a nickel hydrogen (Ni-MH) battery. Battery pack 10 contains one battery or a plurality of batteries that are connected in series depending on the desired output voltage. The battery system contains one battery or a plurality of batteries that are connected in parallel depending on the desired charging amount. The battery system according to the present invention may be provided for example with a metal case type battery (secondary battery). It should be appreciated that the battery system according to the present invention is provided with a metal case type battery (secondary battery).
BMU 20 can be realized by an electronic circuit containing a known protection IC (Integrated Circuit) and various types of electronic devices corresponding to the battery or batteries of battery pack 10.
DC/AC bidirectional inverter 31 can be realized by a DC/AC inverter circuit, an AC/DC converter circuit, a DC/DC converter, a relay (switch) that switches between electrical paths, or the like, each of which is known.
Control section 32 can be realized by an electronic circuit composed of a known communication circuit that transmits and receives information to and from system controller 40; a known current-to-electric power conversion circuit that receives a current value from current sensor 70 that detects the current value (current sensor 70 will be described later) and converts the current value into an electric power value; and a known logic circuit that outputs a control signal that causes the operations of BMU 20, DC/AC bidirectional inverter 31, and so forth to be switched corresponding to a command issued from system controller 40. FIG. 1 shows an example of the structure in which control section 32 is located in power conditioner 30. However, it should be appreciated that control section 32 may be a unit that is independent from power conditioner 30 or a unit that is located in system controller 40.
System controller 40 can be realized by an information processing unit (computer) that is provided with a CPU, a storage unit, various types of logic circuits, and a communication means that transmits and receives information to and from control section 32, BMU 20, and DC/AC bidirectional inverter 31. System controller 40 executes a process corresponding to a program stored in the storage unit so as to operate the battery system. The operation of the battery system will be described later.
Distribution switchboard 60 is provided with a plurality of branch electrical paths (not shown) through which electric power is supplied from the electrical grid to the user's load and which has switches corresponding to individual electrical grids and individual branch electrical paths.
The battery system according to this embodiment is provided with current sensors 70 each of which is located on the electrical path through which electric power is supplied from the electrical grid to the load and on the output electrical path of PV system 50. Electric power supplied from the electrical grid to the user's load and output electric power of PV system 50 are measured based on the current values detected by current sensors 70. Electric power supplied from the electrical grid to the user's load is measured by control section 32 of power conditioner 30. Output electric power of PV system 50 is measured by system controller 40. However, electric power supplied from the electrical grid to the user's load is measured both on the electrical grid side (node a shown in FIG. 1) and the user's load side (node b shown in FIG. 1) viewed from the association point of PV system 50. Thus, power conditioner 30 is provided with switch 36 that changes over between the connection of current sensor 70 at node a and control section 32 and the connection of current sensor 70 at node b and control section 32. System controller 40 operates switch 36.
FIG. 1 shows an example of the structure in which the battery system is used together with PV system 50. However, the battery system according to the present invention can perform the foregoing control even if the battery system is used together with a distributed electric power source that is an in-house electric power generator that uses a wind farm electric power generation system, a fuel battery, or fossil energy.
In this structure, PV system 50 generates electric power basically depending on weather conditions rather than the total electric power consumption of the user's load and outputs the generated electric power. Thus, if the total electric power consumption becomes low, surplus electric power that is not used for the load is generated by PV system 50. The surplus electric power that is not used for the load is caused to reversely flow to the electrical grid. Alternatively, the surplus electric power is charged to battery pack 10 through DC/AC bidirectional inverter 31 under the control of system controller 40.
Battery pack 10 discharges charged electric power in response to a control signal issued by control section 32 and supplies electric power to the user's load through DC/AC bidirectional inverter 31. Presently, in Japan, it is not permitted that electric power discharged from battery pack 10 is caused to reversely flow to the electrical grid. Thus, if the total electric power consumption of the load is low, the amount of electric power discharged from battery pack 10 is suppressed.
Battery pack 10 is charged with the foregoing surplus electric power of PV system 50 or electric power supplied from the electrical grid. Electric power may be charged to or discharged from battery pack 10 by the user at his or her convenience. When battery pack 10 is charged with electric power supplied from the electrical grid, nighttime electric power that is inexpensive compared to regular electric power can be used.
The battery system according to this embodiment is provided with two operation modes in which electric power is supplied to the user's load, a PV priority mode (first mode) in which electric power generated by PV system 50 is prioritized and a charging priority mode (second mode) in which electric power charged to battery pack 10 is prioritized.
In the PV priority mode, the measured value at node a shown in FIG. 1 is used as electric power P_GRIDsupplied from the electrical grid to the load. In the charging priority mode, the measured value at node b shown in FIG. 1 is used as electric power P_GRIDsupplied from the electrical grid to the load.
Assuming that the total electric power consumption (load electric power) of the user's load is denoted by P_LOAD, the electric power supplied from battery pack 10 to the electrical grid through power conditioner 30 is denoted by P_INV, and the electric power supplied from PV system 50 to the electrical grid is denoted by P_PV, in the PV priority mode, the relationship of P_LOAD=P_GRID+P_PV+P_INVis obtained. In contrast, in the charging priority mode, the relationship of P_LOAD=P_GRID+P_INVis obtained. In other words, in the PV priority mode, P_GRID=P_LOAD−(P_PV+P_INV) is measured. In the charging priority mode, P_GRID=P_LOAD−P_INVis measured.
In the PV priority mode, system controller 40 causes electric power that is output from PV system 50 to be supplied preferentially to the load. If electric power generated by PV system 50 does not satisfy electric power supplied to the load (P_LOAD−P_PV>0), system controller 40 causes battery pack 10 to discharge electric power through power conditioner 30 and supply the electric power to the load. If electric power generated by PV system 50 is equal to or greater than electric power supplied to the load (P_LOAD−P_PV<0), system controller 40 causes surplus electric power that is not used in the load to reversely flow to the electrical grid or to be charged to battery pack 10.
In the charging priority mode, system controller 40 causes electric power that is charged in battery pack 10 to be supplied preferentially to the load. If electric power discharged from battery pack 10 does not satisfy electric power supplied to the load (P_LOAD−P_INV>0), system controller 40 causes electric power generated by PV system 50 to be supplied to the load. If electric power discharged from battery pack 10 is equal to or greater than electric power supplied to the load or if it is not necessary to supply all electric power generated by PV system 50 to the load, system controller 40 causes surplus electric power that is not used in the load to reversely flow to the electrical grid or to be charged to battery pack 10.
Moreover, the battery system according to this embodiment is provided with an economy mode (third mode) and a green mode (fourth mode) for the charging priority mode and for the PV priority mode. In the economy mode, economy is prioritized; in the green mode, charging to the battery is prioritized.
In the economy mode, system controller 40 causes surplus electric power that is generated by PV system 50 to be sold preferentially to the electric power company. In the green mode, system controller 40 causes surplus electric power that is generated by PV system 50 to be charged preferentially to battery pack 10. The PV priority mode, the charging priority mode, the economy mode, and the green mode can be set by the user using switches or the like located on the operation panel (not shown) and data that represents the mode that has been set is stored in the storage unit of system controller 40.
Next, with reference to the accompanying drawings, the operation of the battery system shown in FIG. 1 will be described.
FIG. 2 is a block diagram showing the structure of principal sections of the battery system shown in FIG. 1.
FIG. 3 is a flow chart showing an example of a process in which the battery system shown in FIG. 2 performs in the PV priority mode. FIG. 4 is a flow chart showing an example of a process in which the battery system shown in FIG. 2 performs in the charging priority mode.
FIG. 2 shows principal sections related to the operations in which the battery system and PV system 50 perform in the PV priority mode and the charging priority mode. In addition, arrows of P_GRID, P_LOAD, P_INV, and P_PVshown in FIG. 2 represent the directions in which currents flow in the forward direction.
FIG. 1 and FIG. 2 show an example of the structure in which current sensors 70 are located at node a and node b. As described above, the difference between the measured result at node a and the measured result at node b is whether or not the measured result contains P_PV. On the other hand, current sensor 70 is located on the output electrical path of PV system 50 and the value of P_PVis measured by system controller 40. Thus, even if current sensor 70 is located either at node a or node b, the battery system according to this embodiment can be controlled.
The processes shown in FIG. 3 and FIG. 4 are executed by system controller 40. Electric power P_GRIDsupplied from the electrical grid to the load is measured by control section 32 of the power conditioner and then transmitted from control section 32 to system controller 40.
As shown in FIG. 3, when the battery system starts discharging electric power, system controller 40 determines whether the battery system is operating in the PV priority mode or in the charging priority mode (at step S1). If system controller 40 is operating in the charging priority mode, the flow advances to the process shown in FIG. 4.
If the battery system is operating in the PV priority mode, system controller 40 determines whether the battery system is operating in the green mode or in the economy mode (at step S11).
If the battery system is operating in the green mode, system controller 40 determines whether or not total electric power consumption in the load (load electric power P_LOAD) is greater than electric power generated by PV system 50 (PV electric power P_PV), namely whether electric power P_GRIDsupplied from the electrical grid to the load is greater than 0 (at step S12).
If P_GRIDis greater than 0, system controller 40 controls power conditioner 30 so as to discharge electric power from battery pack 10 corresponding to load electric power P_LOADand to supply supplementary electric power (P_LOAD−P_PV) to the load (at step S13).
If P_GRIDis 0 or less, system controller 40 causes surplus electric power (P_PV−P_LOAD=−P_GRID) that is not used in the load of electric power generated by PV system 50 to be charged to battery pack 10 (at step S14). However, if battery pack 10 has been fully charged, system controller 40 causes surplus electric power to reversely flow to the electrical grid so as to sell the surplus electric power to the electric power company or the like.
If the battery system is operating in the economy mode, system controller 40 determines whether or not total electric power consumption in the load (load electric power P_LOAD) is greater than electric power generated by P_vsystem 50 (PV electric power P_PV), namely whether electric power P_GRIDsupplied from the electrical grid to the load is greater than 0 (at step S15).
If P_GRIDis greater than 0, system controller 40 controls power conditioner 30 so as to discharge electric power from battery pack 10 corresponding to load electric power P_LOADand to supply supplementary electric power (P_LOAD−P_PV) to the load (at step S16).
If P_GRIDis 0 or less, system controller 40 causes battery pack 10 to stop discharging electric power (at step S17). In this case, system controller 40 causes surplus electric power (P_PV−P_LOAD=−P_GRID) that is not used in the load of electric power generated by PV system 50 to reversely flow to the electrical grid and causes the surplus electric power to be sold to the electric power company or the like.
If the battery system is operating in the charging priority mode as shown in FIG. 4, system controller 40 determines whether or not the battery system is operating in the green mode or in the economy mode (at step S21).
If the battery system is operating in the green mode, system controller 40 determines whether or not total electric power consumption in the load (load electric power P_LOAD) is greater than electric power generated by PV system 50 (PV electric power P_PV), namely whether electric power P_GRIDsupplied from the electrical grid to the load is greater than P_PV(at step S22).
If P_GRIDis greater than P_PV, system controller 40 controls power conditioner 30 so as to discharge electric power from battery pack 10 corresponding to load electric power P_LOADand to supply supplementary electric power (P_LOAD−P_PV) to the load.
If P_GRIDis equal to or less than P_PVor less, system controller 40 causes surplus electric power (P_PV−P_LOAD=P_PV−P_GRID) that is not used in the load of electric power generated in PV system 50 to be charged to battery pack 10 (at step S24). However, if battery pack 10 has been fully charged, system controller 40 causes the surplus electric power to reversely flow to the electrical grid and the electric power to be sold to the electric power company or the like.
If the battery system is operating in the economy mode, system controller 40 determines whether or not the total electric power consumption in the load (load electric power P_LOAD) is greater than the electric power generated by PV system 50 (PV electric power P_PV), namely electric power P_GRIDsupplied from the electrical grid to the load is greater than P_PV(at step S25).
If P_GRIDis greater than P_PV, system controller 40 controls power conditioner 30 so as to discharge electric power from battery pack 10 corresponding to load electric power P_LOADand supply supplementary electric power (P_LOAD−P_PV) to the load (at step S26).
If P_GRIDis equal to or less than P_PV, system controller 40 causes battery pack 10 to stop discharging electric power (at step S27). In this case, system controller 40 causes surplus electric power that is not used in the load (P_PV−P_LOAD=P_PV−P_GRID) of electric power generated in PV system 50 to reversely flow to the electrical grid and the electric power to be sold to the electric power company or the like.
According to this embodiment, battery pack 10 and power conditioner 30 that controls battery pack 10 to charge or discharge electric power can be operated in association with the electrical grid and independent from a distributed power source such as PV system 50. Even if a distributed electric power source has been implemented, the battery system can be operated in association with the electrical grid.
Moreover, in the battery system according to this embodiment, if the battery pack is charged with nighttime electric power that is relatively inexpensive and if the battery system is operated during the daytime either in the charging priority mode or the PV priority mode, since electric power supplied from the electrical grid during the daytime is prevented, electric rates can be reduced. At this point, if the battery system is operated in the charging priority mode, since surplus electric power that occurs in the PV system becomes relatively large, the amount of electric power that is sold increases. If the battery system is operated in the PV priority mode, electric power generated by the PV system can mostly satisfy electric power for the user's load. Thus, a battery system can be accomplished with high economic benefits.
Whether a higher economic benefit can be obtained in the charging priority mode or the PV priority mode in which the battery system operates depends on, for example, the amount of electric power used by the user, his or her electric power use pattern, and weather conditions (sunlight hours, wind force, and so forth) of the region where he or she lives. In addition, some users may prioritize the use of electric power that is generated from natural energy (green electric power), rather than high economic benefits.
The battery system according to this embodiment can switch between the foregoing charging priority mode and the PV priority mode. In addition, the battery system can switch between the economy mode and the green mode. Thus, the user can optimally select an operation mode in which the battery system operates based upon the preference of the user (i.e. green or economy mode) and so forth.
Thus, the battery system can be operated in association with the electrical grid, but independent from a distributed electric power source. As a result, a battery system that can be operated in a mode that satisfies the preference of each user can be realized.
With reference to the embodiments, the present invention has been described. However, it should be understood by those skilled in the art that the structure and details of the present invention may be changed in various manners without departing from the scope of the present invention.

Claims

1. A battery system comprising:

a battery configured to charge using electric power supplied from an electrical grid and electric power generated by a photo voltaic generation device, and supply electric power to a load; and

a controller configured to control a supply of electric power generated by said photo voltaic generation device to said load, and configured to control a mode in which surplus electric power generated by said photo voltaic generation device is sold and a mode in which surplus electric power generated by said photo voltaic generation device is supplied to said battery.

2. The battery system according to claim 1, wherein

said controller is further configured to, if the supply of electric power generated by said photo voltaic generation device to said load is insufficient, control the supply of electric power stored in said battery to said load.

3. The battery system according to claim 2, wherein

the supply of electric power generated by said photo voltaic generation device to said load has a higher priority that the supply of electric power stored in said battery to said load.

4. The battery system according to claim 1, wherein

said controller is further configured to control a supply of electric power stored in said battery to said load, and

the supply of electric power stored in said battery to said load has a higher priority than the supply of electric power generated by said photo voltaic generation device to said load.

5. The battery system according to claim 1, wherein

said surplus electric power is equal to a difference between an amount of electric power generated by said photo voltaic generation device and a total amount of electric power consumed by said load.

6. The battery system according to claim 3, wherein

the supply of electric power stored in said battery to said load is greater than zero nearer to a side of said electrical grid than an association point where said photo voltaic generation device associates with said electrical grid.

7. The battery system according to claim 4, wherein

8. The battery system according to claim 7, wherein

said controller is further configured to use a measurement result, as electric power that is supplied to said load, on said side of said electrical grid rather than the association point that said photo voltaic generation device associates with said electrical grid.

9. The battery system according to claim 8, wherein

said controller is further configured to use a measurement result, as electric power that is supplied to said load, on said load side rather than the association point that said photo voltaic generation device associates with said electrical grid.

10. A battery system comprising:

a battery configured to charge using electric power supplied from an electrical grid and electric power generated by a distributed electric power source, and supply electric power to a load; and

a controller configured to control a supply of electric power generated by said distributed electric power source to said load, and configured to control a mode in which surplus electric power generated by said photo voltaic generation device is sold and a mode in which surplus electric power generated by said photo voltaic generation device is supplied to said battery.

11. A battery system comprising:

a battery configured to charge using electric power supplied from an electrical grid and electric power that is generated by a photo voltaic generation device, and supply electric power to a load; and

a controller configured to control a supply of electric power generated by said photo voltaic generation device to said load, and control a supply of electric power stored in said battery to said load, wherein

the supply of electric power generated by said photo voltaic generation device to said load has higher priority than the supply of electric power stored in said battery to said load.

12. A battery system comprising:

the supply of electric power stored in said battery to said load has higher priority than the supply of electric power generated by said photo voltaic generation device to said load.

13. A battery system comprising:

one of the supply of electric power generated by said photo voltaic generation device to said load has higher priority than the supply of electric power stored in said battery to said load and the supply of electric power stored in said battery to said load has higher priority than the supply of electric power generated by said photo voltaic generation device to said load.

14. The battery system according to claim 12, wherein

the controller is further configured to control a mode in which surplus electric power generated by said photo voltaic generation device is sold and a mode in which surplus electric power generated by said photo voltaic generation device is supplied to said battery.

15. The battery system according to claim 13, wherein

16. The battery system according to claim 14, wherein

17. A battery system comprising:

a battery is configured to charge using electric power supplied from an electrical grid and electric power that is generated by a distributed electric power source, and supply electric power to a load; and

a controller configured to control a supply of electric power generated by said distributed electric power source to said load, and if the supply of electric power generated by said distributed electric power source to said load is insufficient to satisfy the total electric power requirement of said load, control a supply of electric power stored in said battery to said load.

18. A battery system comprising:

a battery configured to charge using electric power supplied from an electrical grid and electric power that is generated by a distributed electric power source, and supply electric power to a load; and

a controller configured to control the supply of electric power stored in said battery to said load, and if the supply of electric power stored in said battery to said load is insufficient to satisfy the total electric power requirement of said load, control the supply of electric power generated by said distributed electric power source to said load.

19. A battery system comprising:

a controller configured to one of, control a supply of electric power generated by said distributed electric power source to said load, and if the supply of electric power generated by said distributed electric power source to said load is insufficient to satisfy the total electric power requirement of said load, control a supply of electric power stored in said battery to said load, and control the supply of electric power stored in said battery to said load, and if the supply of electric power stored in said battery to said load is insufficient to satisfy the total electric power requirement of said load, control the supply of electric power generated by said distributed electric power source to said load.

20. The battery system according to claim 18, wherein

said controller is further configured to one of reversely direct surplus electric power generated by said distributed electric power source to the electrical grid, and control a supply of surplus electric power generated by said distributed electric power source to charge said battery.

21. The battery system according to claim 19, wherein

22. The battery system according to claim 20, wherein

23. A battery control device configured to supply electric power that is generated by a photo voltaic generation device to a load, and configured to supply surplus electric power generated by said photo voltaic generation device to charge a battery system, the battery system comprising

a battery configured to charge using electric power supplied from an electrical grid and electric power that is generated by said photo voltaic generation device, and supply electric power to a load, and

24. The battery control device according to claim 23, wherein

said battery control device is further configured to supply electric power stored in said battery to a load, and

25. The battery control device according to claim 24, wherein

said battery control device is further configured to supply electric power stored in said battery to said load, and

26. A battery control device configured to supply one of electric power generated by a photo voltaic generation device to a load with a higher priority than electric power stored in a battery system, and supply electric power stored in said battery system to said load with a higher priority than electric power generated by said photo voltaic generation device, said battery system comprising

a battery configured to charge using electric power supplied from an electrical grid and electric power that is generated by said photo voltaic generation device, and supply electric power to a load.

27. The battery control device according to claim 26, wherein

said battery control device is further configured to control a mode in which surplus electric power generated by said photo voltaic generation device is sold and a mode in which surplus electric power generated by said photo voltaic generation device is supplied to said battery.

28. A control method for a battery system, comprising:

charging a battery using electric power supplied from an electrical grid and electric power that is generated by a photo voltaic generation device;

supplying electric power to a load from said photo voltaic generation device with a higher priority; and

supplying electric power to a load from said battery with a lower priority as compared to the supply of electric power to a load from said photo voltaic generation device.

29. A control method for a battery system, comprising:

supplying electric power to a load from said battery with a higher priority; and

supplying electric power to a load from said photo voltaic generation device with a lower priority as compared to the supply of electric power to a load from said battery.

30. A control method for a battery system, comprising:

supplying electric power to a load from said battery; and

supplying electric power to a load from said photo voltaic generation device; wherein

31. The control method for a battery system according to claim 29, further comprising:

operating in a mode in which surplus electric power generated by said photo voltaic generation device is sold, and

operating in a mode in which surplus electric power generated by said photo voltaic generation device is supplied to said battery.

32. The control method for a battery system according to claim 30, further comprising:

33. The control method for a battery system according to claim 31, further comprising:

34. A control method for a battery system, comprising:

charging a battery using electric power supplied from an electrical grid and electric power that is generated by a pre-designated distributed electric power source;

supplying electric power to a load from said pre-designated distributed electric power source; and

supplying, if electric power supplied to said load from said pre-designated distributed electric power source is insufficient to satisfy the total electric power requirement of said load, electric power stored in said battery to said load.

35. A control method for a battery system, comprising:

supplying electric power to a load from said battery; and

supplying, if electric power supplied to said load from said battery is insufficient to satisfy the total electric power requirement of said load, electric power that is generated by said pre-designated distributed electric power source to said load.

36. The control method for a battery system according to claim 35, further comprising: