JP2013135475A - Power supply apparatus, charger, and charging system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow a load, including a large power load such as a charger charging a charged device such as an electric vehicle, to become widely used at low cost.SOLUTION: A power supply apparatus 1 includes: a storage battery 13 storing electric power supplied from an electric power system 2 and having a battery body 13a and a battery management device 13b; a management device 14, a changeover switch 16, and a power conditioner 11 which serve as controlling means that controls the power supply from the electric power system 2 to the storage battery 13 and the power supply to a quick charger 20 serving as a load operated by electric power accumulated in the storage battery 13.

Description

  The present invention relates to a charging device that charges a device to be charged such as an electric vehicle or the like, a power feeding device that feeds power to a large power load, a charging device that receives power feeding from the power feeding device, and a charging system using them.

  2. Description of the Related Art In recent years, an electric vehicle has entered a practical use stage, and a charging device has been developed as a facility for a user to directly charge a storage battery mounted on the electric vehicle. In the charging apparatus, not only the improvement of the original charging function but also various technologies that are supposed to be used for the public like the conventional gas station have been proposed.

  As an example of such a technique, Patent Document 1 discloses a charging device that receives power from a commercial power system and supplies a voltage rectified and stepped down to direct current for an electric vehicle (Patent Document 1). (See FIG. 1, paragraphs (0002), (0012), etc.).

JP 2011-177003 A

  However, the above conventional techniques have the following problems.

  That is, the power system used in the conventional charging device is configured by a high-voltage distribution network or a special high-voltage distribution network mainly used for business use, and the current supplied from these power systems is suitable for charging an electric vehicle. Therefore, an expensive rectifier for stepping down and rectifying is required, and as a result, the cost of the charging device is increased.

  Moreover, it cannot be said that power systems that handle high-voltage currents beyond the high-voltage distribution network are widely developed in urban areas and residential areas where electric vehicles are used, which is an obstacle to installing charging devices. .

  Thus, the conventional charging device has a problem that it is expensive and difficult to spread.

  The present invention has been made in view of the above problems, and can be spread at a low cost. The power feeding device suitable for use with a load including a large power load such as a charging device, and the charging device and power feeding adapted thereto. The purpose is to provide a system.

In order to achieve the above object, the first aspect of the present invention provides:
A storage element for storing power fed from the power system;
And a control unit configured to control power supply from the power system to the power storage element and power supply to a load operated by the power stored in the power storage element.

The second aspect of the present invention is
The power system is a low voltage distribution network of 200V or less,
It is the electric power feeder of the 1st side surface of this invention.

The third aspect of the present invention is
The load is a high power load of 100 KW or less.
It is the electric power feeder of the 1st or 2nd side surface of this invention.

The fourth aspect of the present invention is
The large power load is a charging device that charges a device to be charged.
It is the electric power feeder of the 3rd side surface of this invention.

The fifth aspect of the present invention is
The control means communicates with the charging device,
Control operation is performed using information acquired from the charging device,
It is the electric power feeder of the 4th side surface of this invention.

The sixth aspect of the present invention is
The information acquired from the charging device includes information on an operation history of the charging device, or a current value or a voltage value of power fed from the power feeding device measured by the charging device.
It is the electric power feeder of the 5th side surface of this invention.

The seventh aspect of the present invention is
The information acquired from the charging device includes an identifier unique to the charging device.
It is the electric power feeder of the 5th or 6th side surface of this invention.

The eighth aspect of the present invention is
The charging device communicates with the device to be charged and obtains information on the device to be charged,
The information acquired from the charging device by the control means includes information on the charged device.
It is the electric power feeder of the 5th to 7th side surface of this invention.

The ninth aspect of the present invention is
The information on the charged device includes information on an operation history of the charged device, or a current value or a voltage value of power supplied from the charging device measured by the charged device.
It is the electric power feeder of the 8th side surface of this invention.

The tenth aspect of the present invention provides
The information on the charged device includes a unique identifier of the charged device.
It is the electric power feeder of the 8th or 9th side surface of this invention.

The eleventh aspect of the present invention is
The charged device is an electric vehicle,
Information acquired from the charging device or information on the charged device is information that conforms to the CHAdeMO standard.
It is the electric power feeder of the 8th to 10th side surface of this invention.

The twelfth aspect of the present invention is
Power generation means,
The control means further controls power feeding from the power generation means to the power storage element or the power system.
1 is a power feeding device according to any one of the first to eleventh aspects of the present invention;

The thirteenth aspect of the present invention provides
Powered from at least one of the power system, the storage element, or the DC power generation means, and provided with an auxiliary power feeding unit that feeds power to an external load.
1 is a power feeding device according to any one of the first to twelfth aspects of the present invention;

The fourteenth aspect of the present invention is
The control means performs communication with the outside by superimposing a communication signal on a line connecting the auxiliary power feeding unit and the power system, the power storage element, or the DC power generation means.
It is the electric power feeder of the 13th side surface of this invention.

The fifteenth aspect of the present invention is
The power system is a single-phase three-wire system.
It is the electric power feeder of the 1st thru | or 14th side surface of this invention.

The sixteenth aspect of the present invention provides
Receiving power supply from a power supply device having a power storage element that stores power supplied from the power system, and a control unit that controls power supply from the power system to the power storage element and power supply stored in the power storage element. A charging device that operates and charges a charged device,
Comprising communication means for communicating with the power feeding device and / or the device to be charged;
The communication unit transmits its own information and / or information of the charged device to be used for the operation of the control unit to the power supply device.
It is a charging device.

The seventeenth aspect of the present invention provides
A power supply device that stores power supplied from an electric power system, and a control unit that controls power supply from the power system to the power storage element and power supply stored in the power storage element;
A power supply device that operates by receiving power from the power supply device and performs charging for the device to be charged;
The charging device has communication means for communicating with the power feeding device and / or the charged device,
The control unit of the power supply device performs a control operation using the information on the charging device and / or the information on the charged device acquired from the communication unit of the charging device.
It is a charging system.

The eighteenth aspect of the present invention is
Power generation means;
A power storage element for storing power supplied from an external power system or the power generation means; (a) power supply from the power generation means to the power storage element; (b) power supply from the power system to the power storage element; A power supply apparatus comprising: control means for controlling power supply to a load that operates with power stored in the power storage element; and (d) power supply from the power generation means to the power system;
A charging device that operates by feeding from the power feeding device as the load and charges the device to be charged,
It is a charging system.

The nineteenth aspect of the present invention provides
A power supply device comprising: a power storage element that stores power supplied from a power system; and a control unit that controls power supply from the power system to the power storage element and power supply stored in the power storage element, The control means uses information on the charging device and / or information on the charged device acquired from a charging device that operates by receiving power stored in the power storage element and charges the charged device. Of the power feeding device that performs the control operation by
A program for operating a computer as the control means.

The twentieth aspect of the present invention provides
A power generation means; an electricity storage element for storing power supplied from an external power system or the power generation means; (a) power supply from the power generation means to the power storage element; and (b) power supply from the power system to the power storage element. A power feeding device having power feeding, and (c) control means for controlling power feeding to a load operated by the power stored in the power storage element, and (d) power feeding from the power generation means to the power system, and A charging system comprising a charging device that operates as a load and that is charged by the power supply device and charges the device to be charged,
A program for operating a computer as the control means of the power supply apparatus.

  According to the present invention as described above, there is an effect that it is possible to provide a power feeding device that can spread a load including a large power load such as a charging device at low cost, and a charging device, a power feeding system, and the like adapted to the power feeding device.

The block diagram which shows the structure of the electric power feeding system which concerns on each embodiment of this invention The block diagram which shows the structure of the power conditioner vicinity of the electric power feeder which concerns on each embodiment of this invention (A) Block diagram showing a configuration of a quick charger according to each embodiment of the present invention (b) Block diagram showing a configuration of a charged device according to each embodiment of the present invention The figure which shows the flowchart of operation | movement of the electric power feeding system which concerns on Embodiment 1 of this invention. The figure which shows the flowchart of operation | movement of the electric power feeding system which concerns on Embodiment 1 of this invention. The figure which shows the flowchart of operation | movement of the electric power feeding system which concerns on Embodiment 2 of this invention. The figure which shows the flowchart of operation | movement of the electric power feeding system which concerns on Embodiment 3 of this invention. The block diagram which shows the other structural example of the electric power feeding system which concerns on embodiment of this invention. The block diagram which shows the other structural example vicinity of the power conditioner of the electric power feeder which concerns on embodiment of this invention The block diagram which shows the other structural example of the quick charger which concerns on embodiment of this invention

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a block diagram showing a configuration of charging system 1 according to Embodiment 1 of the present invention.

  As shown in FIG. 1, a charging system 1 according to the first embodiment includes a power supply device 10 to which a single-phase three-wire power system 2 that is a commercial power system for home use by a business operator and a solar cell 3 are connected. And a quick charger 20 that is used in connection with the power supply device 10 and charges the charged device 30. Hereinafter, each apparatus which comprises a system is demonstrated.

  The power supply device 10 includes a power conditioner 11, a received power detection unit 12, a storage battery 13, a management device 14, and an auxiliary power supply unit 15.

  The power conditioner 11 is means for receiving power from the power system 2 or the solar battery 3 and stepping down and rectifying the power so as to be suitable for the storage battery 15. The received power detection unit 12 is a unit that receives power from the power system 2 and detects a current value and a voltage value.

  The storage battery 13 is a storage battery that can be charged and discharged by the power supplied from the power conditioner 11, and is realized by, for example, a lithium ion secondary battery. The storage battery 13 operates based on the control of the management device 14 to be described later, and includes a battery management device 13b that controls charging / discharging of the battery body 13a.

  Further, the management device 14 is a means that incorporates a timer for measuring time, a storage device for storing information, a communication I / F, etc., realized by a microcomputer or the like, and communicates with the quick charger 20. Based on this, it is means for controlling operations of the power conditioner 11, the storage battery 13 and the auxiliary power supply unit 15.

  The auxiliary power supply unit 15 is a means that can be connected to an external device provided on a power path that connects the power conditioner 11 and the power system 2. When the external device operates with power of the same standard as that of the power system 2, the auxiliary power feeding unit 15 is a means for passing through the output of the power system 2 or receiving the converted output from the power conditioner 11, for example, Realized as a business outlet or a business outlet. Further, the auxiliary power feeding unit 15 alternatively outputs the output from the power conditioner 11 or the output from the power system 2 under the control of the management device 14.

  Next, FIG. 2 is a block diagram illustrating a configuration of the power conditioner 11 in the power supply apparatus 10 and a configuration in the vicinity of the power conditioner 11. As shown in FIG. 2, the power conditioner 11 includes a bidirectional DC-DC converter 111, a changeover switch 112, a bidirectional AC-DC converter 113, a bidirectional DC-DC converter 114, and control means. 115.

  The DC-DC converter 111 is means for transforming direct-current power supplied from the solar cell 3, and the changeover switch 112 is used for the power path between the DC-DC converter 111, the AC-DC converter 113, and the DC-DC converter 114. It is a means for switching conduction.

  The AC-DC converter 113 is a means for performing conversion and step-up / step-down of AC power supplied from the power system 2 and DC power supplied from the solar battery 3 or the storage battery 15. The DC-DC converter 114 is means for transforming DC power flowing between the DC-DC converter 111 or the AC-DC converter 113 and the storage battery 15.

  The control means 115 is means for controlling the operation of each converter and changeover switch described above based on the control from the management device 14. Further, the control means 115 also controls the operation of the changeover switch 16. Here, the changeover switch 16 is provided on the power path of the power output of the power conditioner 11, the storage battery 13, and the power feeding device 10, and is a means for switching the conduction between the above-described parts.

  Next, FIG. 3A is a block diagram showing a configuration of the quick charger 20.

  As shown in FIG. 3A, the quick charger 20 includes a measuring device 201, a DC-DC converter 202, a communication I / F 203, a management device 204, and a storage device 205.

  The measuring device 201 is a means for measuring the current value and voltage value of the DC power supplied from the power conditioner 11, and the DC-DC converter 202 receives the voltage of the DC power supplied from the power conditioner 11. It is a means for moving up and down based on communication with the charging device 30.

  The communication I / F 203 is an interface for communicating with the power conditioner 11 and the charged device 30 using a predetermined protocol.

  The management device 204 is a means that is realized by a microcomputer, processes information acquired via the measurement device 201, the DC-DC converter 202, and the communication I / F 203, and manages the operation of the quick charger 20. The storage device 205 is a means for storing information processed by the management device 204, realized by a semiconductor memory, a magnetic recording medium, or the like.

  Next, FIG. 3B is a block diagram illustrating a configuration of the charged device 30.

  As illustrated in FIG. 3B, the charged device 30 includes a storage battery 301, a communication I / F 302, a management device 303, and a storage device 304.

  The storage battery 301 is a power source for the device 30 to be charged, and supplies power to an operation part of a device (not shown). Similarly to the storage battery 13, the storage battery 301 includes a battery main body 301 a and a battery management device 301 b for controlling charging / discharging of the battery main body 301 a.

  The communication I / F 302 is an interface for performing communication using a common protocol with the quick charger 20, and the management device 303 is realized by a microcomputer, via the battery management device 301 b and the communication I / F 302. The means for processing the acquired information and managing the operation related to the charging of the device to be charged 30. The storage device 304 is realized by a semiconductor memory, a magnetic recording medium or the like, and is a means for storing information processed by the management device 303. It is.

  In addition, as the to-be-charged device 30, an electric vehicle, a plug-in hybrid vehicle, an electric two-wheeled vehicle, a ship, a train, etc., such as a secondary battery or an electrochemical capacitor is mounted as a power source and operates. Any device can be used.

  In particular, when an electric vehicle is used as the device to be charged 30, the output voltage of the power supply device 10 is preferably about 300 to 360 VDC. However, it can be set to 400 V or the like as necessary. Similarly, when the electric vehicle is used, the output voltage of the quick charger 20 is preferably about 50 to 500 VDC. However, it is also possible to output DC 600V or 800V if necessary.

  1 to 3, the power path between the power system 2, the solar cell 3, the power feeding device 10, the quick charger 20 and the charged device 30 is indicated by a solid line, and the power feeding device 10, the quick charger 20 and the charged device 30 are Signal paths for communication and control inside and outside the charging device 30 are indicated by broken lines. In addition, configurations of relays and circuit breakers that are well known and commonly used in each system are omitted.

  In the above description, the power feeding device 10 corresponds to the power feeding device of the present invention, the quick charger 20 corresponds to the high power load or the charging device of the present invention, and the charged device 30 corresponds to the charged device of the present invention. The charging system 1 formed by combining the power feeding device 10 and the quick charger 20 corresponds to the charging system of the present invention.

  Moreover, in the electric power feeder 10, the storage battery 13 is equivalent to the electrical storage element of this invention, and the management apparatus 14, the changeover switch 16, and the power conditioner 11 are equivalent to the control means of this invention. The power system 2 corresponds to the low voltage distribution network of the present invention, the solar cell 3 corresponds to the DC power generation means of the present invention, and the auxiliary power supply unit 15 corresponds to the auxiliary power supply unit of the present invention. Further, in the quick charger 20, the communication I / F 203 and the management device 204 correspond to communication means of the present invention.

  The charging system 1 according to the first embodiment of the present invention having such a configuration includes the power feeding device 1 that is charged by power feeding from the power system 2 that is a low-voltage distribution network and that feeds power to the quick charger 20. It is a feature.

  Hereinafter, the operation of the charging system 1 according to the first embodiment of the present invention will be described, and the operation of the embodiment of the power supply device and the charging device according to the present invention will be described.

  In the power supply device 10, the management device 14 performs different operations for each time zone by referring to the time of the built-in timer.

  First, the daytime operation will be described with reference to the flowchart of FIG. When the power supply apparatus 10 starts operation, the management apparatus 14 checks the power supply state of the power supply apparatus 10 from the power system 2 as step 101 and determines whether sound power supply is being performed (step 102). Specifically, a voltage value and a current value detected by the received power detection unit 12 are acquired, compared with a reference value stored in the storage device, and when a displacement exceeding a predetermined amount is recognized, it is determined that the sound is not healthy. To do.

  When it is determined in step 102 that the power system 2 is healthy, the process proceeds to step 103, and the management device 14 communicates with the battery management device 13b of the storage battery 13 to acquire the charge amount of the battery main body 13a. In step 105, it is checked whether or not the charging amount of the charging device 20 has reached a level at which rapid charging can be performed.

  On the other hand, when a displacement exceeding a predetermined amount occurs due to power supply interruption due to a power failure or the like, and it is determined that the state is not healthy, the process proceeds to step 104, and the management device 14 communicates with the power conditioner 11. The storage battery 13 is charged with the DC power generated by the solar battery 3. Specifically, the control means 115 shown in FIG. 2 receives a command from the management device 14 and switches the changeover switches 112 and 16 to form a power path between the solar cell 3 and the storage battery 13.

  The electric power generated by the solar cell 3 is transformed to a voltage suitable for the storage battery 13 through the DC-DC converters 111 and 114, and then charged to the battery body 13a. In addition, when the solar cell 3 cannot generate sufficient power due to bad weather or the like, the management device 14 detects this due to the small amount of charge detected by the battery management device 13b, and puts the power supply device 10 in a standby state. Put it in.

  Next, when it is determined in step 105 that the quick charging operation can be performed, the management device 14 further checks whether or not the battery body 13a is fully charged, and is determined to be fully charged in step 108. In such a case, communication with the power conditioner 11 is performed, and a reverse power flow is made to the power system 2 generated by the solar cell 3.

  Specifically, the control means 115 shown in FIG. 2 receives a command from the management device 14 and switches the changeover switches 112 and 16 to form a power path between the solar cell 3 and the power system 2. The electric power generated by the solar cell 3 is converted into AC power through the DC-DC converter 111 and the AC-DC converter 113 and then transmitted to the power system 2. When it is determined that the battery is not fully charged, charging of the storage battery 13 by the solar battery 3 is continued.

  On the other hand, if it is determined in step 105 that the quick charging operation cannot be performed, the management device 14 communicates with the power conditioner 11 and receives power from the power system 2 in addition to the DC power generated by the solar cell 3. The storage battery 13 is charged with the electric power. Specifically, the control means 115 shown in FIG. 2 receives a command from the management device 14, connects the changeover switch 112 to the solar battery 3 and the storage battery 13, and forms a power path between the storage battery 13.

  The quick charger 20 can charge the device to be charged 30 in each step after step 106 or between steps.

  Next, the operation at night will be described with reference to the flowchart of FIG.

  In step 201, the management device 14 communicates with the battery management device 13 b of the storage battery 13, acquires the charge amount of the battery main body 13 a, moves to step 202, and determines whether or not the charged device 30 can be rapidly charged. To check. The checking procedure is performed in the same manner as in step 104 above.

  If quick charging is possible, the process proceeds to step 209 and waits in a state where power supply to the quick charger 20 is always possible.

  On the other hand, if quick charging is not possible, the process proceeds to step 203, and the management device 14 checks the power supply state of the power system 2 by the same procedure as in step 101, and determines whether it is healthy (step). 204).

  When it is determined in step 204 that the power system 2 is healthy, the process proceeds to step 205, and the management device 14 charges the storage battery 13 with the power received from the power system 2. Specifically, the control means 115 shown in FIG. 2 switches the changeover switches 112 and 16 in response to an instruction from the management device 14, and forms a power path between the power system 2 and the storage battery 13.

  On the other hand, when it is determined that the power system 2 is not healthy, the fact is notified to the outside, and the operation itself of the power supply apparatus 10 is terminated, or the operation other than the management apparatus 14 is stopped and waits.

  Thereafter, the operation of looping Steps 207 and 208 is performed, and the charging operation to the storage battery 13 is continued until the quick charger 20 becomes operable. When the operation becomes possible, the process proceeds to Step 209 and the quick charging is performed. It waits in the state where the electric power supply to the device 20 is always possible.

  As described above, according to the charging system 1 according to the first embodiment of the present invention, the rechargeable battery that is charged by feeding from the power system 2 that is a low-voltage distribution network that is widely provided as a home AC power supply source. With the configuration including the power feeding device 1 having 13, expensive rectifiers and converters can be omitted in a load that requires high power, such as the quick charger 20 used for charging an electric vehicle or the like. Since the cost required to increase the storage capacity 13 is smaller than the cost of the rectifier or the like, the costs of the power supply device 1 and the quick charger 20 can be suppressed.

(Embodiment 2)
The charging system according to the second embodiment of the present invention is characterized in that the management device 14 of the power supply apparatus 10 controls the operation of each unit of the power supply apparatus 10 based on the information acquired from the quick charger 20. .

  The configuration of the charging system according to the second embodiment is the same as that of the first embodiment, and therefore, FIGS.

  As described in the first embodiment, the quick charger 20 is arbitrarily connected to the device 30 to be charged after the time point (step 106 in FIG. 4) when the power supply device 10 determines that the quick charging operation is possible. Can be charged.

  At this time, charging is performed between the quick charger 20 and the device to be charged 30 after establishing communication with the respective battery management devices 204 and 303.

  Next, when charging is started, in the quick charger 20, the measurement device 201 monitors the voltage value and current value of the direct current supplied from the power supply device 10 and sequentially transmits them to the management device 204. The management apparatus 204 transmits the acquired voltage value and current value to the power supply apparatus 10 at a request from the management apparatus 14 of the power supply apparatus 10 or at a predetermined timing.

  Hereinafter, the operation on the power feeding apparatus 10 side will be described with reference to the flowchart of FIG.

  In the power supply device 10, as the step 301, when the management device 14 acquires the voltage value and current value transmitted from the quick charger 20, the voltage value and current as the rated value stored in the storage device built in itself. Compared with the value, it is checked whether or not the difference between the power supplied by the power supply apparatus 10 and the power received by the quick charger 20 is within a stable range suppressed to a certain amount or less (step 302).

  If it is determined in step 302 that the measured value is within the stable range, the process proceeds to step 303 and the power feeding operation is continued.

  On the other hand, if it is determined that the measured value is not within the stable range, the process proceeds to step 304 where the management device 14 communicates with the battery management device 13b of the storage battery 13 and is monitored by the battery management device 13b. The voltage value and current value of the battery body 13a are obtained. Then, as in step 302, a comparison is made with the rated value, and it is checked whether or not the difference between the actual power supplied by the power supply apparatus 10 and the ideal value of the power supply apparatus 10 is within the stable range. (Step 305).

  As a result of step 305, when it is determined that the measured value is within the stable range, the management device 14 indicates that the storage battery 13 is operating stably and there is an abnormality on the downstream side of the power supply device 10 including the quick rechargeable battery 20. It is determined that it has occurred, and the power feeding operation is stopped (step 306).

  When it is determined that the measured value is not within the stable range, it is determined that an abnormality has occurred in the storage battery 13, and the management device 14 stops the power feeding operation (step 306).

  As described above, according to the charging system 1 according to the second embodiment of the present invention, information is acquired from the quick charger 20, and the operation of the power feeding apparatus 10 is controlled based on this information.

  Thereby, it becomes possible to provide a more reliable charging system by controlling the power supply apparatus 10 while monitoring the operation state of the power supply destination.

  In addition, by referring to the information of the quick charger 20, when an abnormality occurs in the power supply of the system, it is possible to determine whether the cause of the abnormality is the power supply device 10 side or the quick charger 20 side, It becomes possible to respond quickly to system failures.

  In the above description, the discharge operation of the storage battery 13 is controlled based on the information acquired from the quick charger 20, but the operation of the power conditioner 11 may be controlled. This is particularly effective in the control when the storage battery 13 performs charging and discharging at the same time.

  In addition, the information to be acquired is an actual measurement value of power supplied from the power supply apparatus 10, but may be an operation history of the quick charger 20 such as the number of times of charging the apparatus to be charged 30. In this case, the operation state of the quick charger 20 can be indirectly confirmed by combining with the actual measured value of the electric power. For example, the inspection time of the quick charger 20 can be easily known.

  Furthermore, the information to be acquired may be information unique to the quick charger 20, and may be an identifier that makes it possible to distinguish one charging device from a plurality of charging devices 20 of the same type and the same function. Such an identifier can be realized as a serial number assigned to the product by the manufacturer of the quick charger 20 or an ID set by the user. In this case, when a plurality of quick chargers 20 are connected to the power supply apparatus 10, they can be managed individually.

  In the above description, the operation of the present embodiment is performed during the daytime operation of the first embodiment, but may be performed during the nighttime operation.

(Embodiment 3)
The charging system according to the second embodiment of the present invention is based on the information acquired from the quick charger 20 by the management device 14 of the power supply device 10 and the information acquired from the charged device 30 by the quick charger 20. It is characterized by controlling the operation of.

  The configuration of the charging system according to the third embodiment is the same as that of the first embodiment. Therefore, in the description, FIGS. 1 to 3 will be referred to again, and the operation will be described with reference to the flowchart of FIG.

  As in the case of the second embodiment, when the quick charger 20 starts charging the charged device 30 at an arbitrary time after step 106 in FIG. 4, in the quick charger 20, the measuring device 201 is a power feeding device. The voltage value and current value of the direct current supplied from 10 are monitored and sequentially transmitted to the management device 204. The management apparatus 204 transmits the acquired voltage value and current value to the power supply apparatus 10 at a request from the management apparatus 14 of the power supply apparatus 10 or at a predetermined timing.

  Further, charging is performed between the quick charger 20 and the charged device 30 after establishing communication with the respective battery management devices 204 and 303. Even during charging, information is exchanged between the quick charger 20 and the device to be charged 30, and the quick charger 20 has the direct current power charged to the battery body 301a monitored by the battery management device 301b in the device to be charged 30. The voltage value and the current value are acquired and stored in the storage unit 205 together with their own measured values.

  The power supply apparatus 10 performs the same operations as steps 301 to 303 in the second embodiment as steps 401 to 403. That is, when the management device 14 acquires the measurement values transmitted from the quick charger 20, the management device 14 compares these with the rated values stored in the management device 14, and compares the power supply power of the power supply device 10 and the power reception power of the quick charger 20. Check if the difference is within the stable range. If it is determined that the measured value is within the stable range, the power feeding operation is continued.

  On the other hand, when it is determined that the measured value is not within the stable range, the process proceeds to step 404, where the management device 14 uses the information acquired from the quick charger 20 as information on the charged device 30 as the battery management device. The measured value of the DC power charged to the battery body 301a measured by 301 is extracted. The extracted measured value is compared with the voltage value and current value of the storage battery 301 as the rated value stored in the storage device built in the management device 14. Note that the measurement value as information on the charged device 30 may be acquired from the charged device 30 for the first time in step 404.

  As a result, the management device 14 determines whether or not the difference between the power supplied to the charged device 30 from the quick charger 20 and the power received by the quick charger 20 is within a stable range that is suppressed to a certain amount or less. Check (step 405).

  As a result of step 405, when it is determined that it is within the stable range, the process proceeds to step 406, where it is determined that an abnormality has occurred on the downstream side of the power supply apparatus 10 including the quick charger 20, and the management apparatus 14 performs the power supply operation. Is canceled (step 407).

  On the other hand, if it is determined that the measured value is not within the stable range, it is determined that an abnormality has occurred in the device to be charged 30, the process proceeds to step 408, and the management device 14 notifies the quick charger 20 to that effect ( Step 409). The quick charger 20 that has received the notification from the management device 14 stops the charging operation for the charged device 30, or the quick charger 20 further passes the notification to the charged device 30, whereby the charged device 30 side The charging is stopped by the control from.

  As described above, according to the charging system 1 according to the second embodiment of the present invention, information on the quick charger 20 and the charged device 30 to be charged is acquired from the quick charger 20, and based on these information, the power supply device 10 The operation is controlled. It is possible to provide a more reliable charging system by controlling the charging operation while monitoring the state of both of the two devices having storage batteries that are more susceptible to changes over time than other components. Become.

  In addition, when an abnormality occurs in the power supply of the system by referring to the information on the charged device 30 via the quick charger 20, the cause of the abnormality is on the charged device 30 side or on the charged device 30 side. Therefore, it is possible to quickly and easily perform an inspection at the time of malfunction.

  In the above description, the discharge operation of the storage battery 13 is controlled based on the information acquired from the quick charger 20 and the charged device 30, but the operation of the power conditioner 11 is controlled. Also good. This is particularly effective in the control when the storage battery 13 performs charging and discharging at the same time.

  In addition, the information to be acquired is an actual measurement value of the power supplied from the power supply device 10, but the operation history of the quick charger 20 such as the number of times of charging of the charged device 30, and the battery in the charged device 30 The temperature of 301, the integrated value of the charge / discharge amount, and other quantities indicating the performance of the storage battery may be selectively included. In this case, the operation state of the quick charger 20 can be indirectly checked by combining with the measured value of the electric power, and therefore the inspection time can be easily known.

  Furthermore, the information to be acquired is information unique to the device to be charged 30 and may be an identifier that makes it possible to distinguish one charged device from a plurality of charged devices 30 of the same type and the same function. . In this case, when the plurality of quick chargers 20 are connected to the power feeding device 10 or when the quick charger 20 has a configuration capable of connecting a plurality of charged devices 30, the power feeding device 10 has a plurality of charged devices. When power is supplied to 30, it is possible to manage these charged devices individually.

  In particular, when an electric vehicle or a plug-in hybrid vehicle is used as the device to be charged 30, centralized management is possible by using a registration number written on a chassis number or a license plate as unique information. . Moreover, you may make it memorize | store the identifier which identifies the storage battery 301 in the battery management apparatus 301b as information intrinsic | native to the to-be-charged apparatus 30. FIG.

  Furthermore, particularly when the device to be charged 30 is an electric vehicle, the above control can be performed more easily by adapting the communication protocol of the power supply apparatus 10 to the Chademo standard together with the quick charger 20 and the device 30 to be charged. It can be realized. Further, although the operation of the present embodiment is performed during the daytime operation of the first embodiment, it may be performed during the nighttime operation as in the second embodiment. Further, it may be operated in combination with the second embodiment.

  As described above, according to each embodiment of the present invention, it is possible to supply power to a load including a large power load such as a charger for an electric vehicle at a lower cost, and it is possible to easily supply a power supply system. Can be built.

  However, the present invention is not limited to the above embodiments.

  In the first embodiment, the switching of the operation flow between the daytime and nighttime of the management device 14 is performed by a timer built in the management device, but may be switched based on the amount of light received by the solar cell 3. In this case, the time determined to be daytime can be increased, and the power consumption of the apparatus can be suppressed.

  In addition, the auxiliary power feeding unit 15 of the present invention is realized as an output from the power system 2 or converted from the power conditioner 11, for example, as a household outlet or a business outlet. It was supposed to be. This can be used as an emergency AC power source, and the AC 100V power obtained by converting the power of the power system 2 or the storage battery 3 by the power conditioner 11 is selectively controlled by the management device 14 or by manual switching (not shown). To be taken out to the outside.

  However, the auxiliary power feeding unit of the present invention may be output in a form converted to other output via a conversion circuit (not shown). In this case, various electric powers such as AC 200 V, DC 12 V, and DC 24 V can be output in addition to AC 100 V, depending on the rating of the device to be used. In addition, the configuration of the connection portion with the external device can be in the form of a connection terminal, a socket, a terminal block, etc. for a mobile phone or a computer in addition to a household outlet or a business outlet.

  Further, in the present invention, the auxiliary power feeding unit may be used as a communication path with the quick charger 20.

  FIG. 8 is a block diagram showing another configuration example of the charging system of the present invention. The charging system 4 shown in FIG. 8 includes a power feeding device 40 having an auxiliary power feeding unit 17 that also functions as a communication I / F.

  As shown in FIG. 9, the auxiliary power feeding unit 17 superimposes or separates a high-frequency signal on the power feeding unit main body 17 b having the same function as that of the auxiliary power feeding unit 15 of the first embodiment and an alternating current passing through the power feeding unit main body 17 b. Modulation / demodulation means 17a.

  FIG. 10 is a configuration diagram of the quick charger 50 constituting the charging system 4. As shown in FIG. 10, the quick charger 50 includes an AC-DC converter 501 for receiving AC power and a modulation / demodulation unit 502 having the same function as that incorporated in the auxiliary power feeding unit 17. Note that the DC power converted from the AC-DC converter 501 is suitable for a low load that is used for the operation of the management device 204 and the storage device 205.

  By providing such a configuration, the charging system 4 can communicate with the management device 14 and an external device operable by feeding AC power using the AC current path connected to the auxiliary power feeding unit 17 as a signal path. Become. In particular, when the quick charger 50 is used as an external device, information necessary for controlling the operation of the power feeding device 40 is transmitted to the auxiliary power feeding unit even when a failure occurs in the communication line normally housed in the same cable as the power line. 17, the redundancy can be ensured and the reliability of the system can be improved. Furthermore, the auxiliary power supply unit 15 or 17 may be omitted.

  In the above description, the power supply device 10 includes the solar cell 3. However, the power generation means of the present invention is a means capable of generating power by using renewable energy such as solar heat, wind power, etc. in addition to sunlight. It may be realized. Moreover, you may implement | achieve as a generator which operate | moves with a fossil fuel like an internal combustion engine. Further, it may be a means for generating AC power. Furthermore, the power feeding apparatus 10 may be configured to operate only by power feeding from the power system 2 without the solar battery 3.

  In the above description, the power system 2 is a single-phase three-wire system. However, as long as it is classified as a low-voltage distribution network, other electrical systems such as a three-phase three-wire system and a three-phase four-wire system are used. It may be a method. In the present invention, “low pressure” is preferably 200 V or less. However, 200 V used for the low voltage distribution network in the present invention is not necessarily required to be a strict value in terms of science and engineering, and is a rated value that is stably supplied on the power system side. A range having a width of ± several tens of volts is also included as long as it is clearly distinguishable from other rated values of power provided by the power system side.

  In the above description, the quick charger 20 has been described as an example of the large-capacity load of the present invention. However, the large-capacity load of the present invention can be used as long as it operates with power of 100 kW or less. It may be realized as another device such as an electric vehicle or a power supply device.

  In the above description, the storage battery 13 is exemplified as a lithium ion secondary battery. However, the storage element of the present invention may be a nickel-hydrogen battery or other various secondary batteries. Furthermore, it may be an element that directly stores electricity as electric charges, such as an electric double layer capacitor. In short, as long as the element can repeatedly store and discharge electricity, it is not limited by its specific method.

  Further, the present invention is a program for realizing all or part of the operation of the power supply device of the charging system of the present invention or the control means of the power supply device alone as the operation of the computer, and cooperates with the computer. The program may be a program that can be read by a computer, and the program may be readable by a computer and the read program may be recorded on a recording medium that performs the operation in cooperation with the computer.

  The “partial operation” of the present invention means a part of all the operations executed by the control means, or further means a part of one operation.

  Further, one usage form of the program of the present invention may be an aspect in which the program is read by a computer while being carried on a recording medium and operates in cooperation with the computer. Here, the computer is not limited to pure hardware such as a CPU, but may include firmware, an OS, and peripheral devices. The recording medium means an optical disk, a magneto-optical disk, a magnetic disk, a non-volatile memory, or other medium that can be externally accessed and can carry the program of the present invention.

  Therefore, the configuration of the present invention may be realized by software or hardware.

  In short, various modifications may be made to the above-described embodiments, including those described above, as long as they do not depart from the spirit of the present invention.

  The present invention as described above is suitable for use of a load including a large power load, has an effect that can be spread at low cost, and is useful in a power supply device and a charging device as a large power load cooperating with the power feeding device. .

DESCRIPTION OF SYMBOLS 1 Charging system 2 Electric power system 3 Solar cell 10 Power supply apparatus 11 Power conditioner 12 Received power detection part 13 Storage battery 13a Battery body 13b Battery management apparatus 14 Management apparatus 15 Auxiliary power supply part 16 Changeover switch 20 Quick charger 30 Charged device

Claims (20)

A storage element for storing power fed from the power system;
Control means for controlling power supply from the power system to the power storage element and power supply to a load operated by the power stored in the power storage element;
Power supply device. The power system is a low voltage distribution network of 200V or less,
The power feeding device according to claim 1. The load is a high power load of 100 KW or less.
The power feeding device according to claim 1 or 2. The large power load is a charging device that charges a device to be charged.
The power feeding device according to claim 3. The control means communicates with the charging device,
Control operation is performed using information acquired from the charging device,
The power feeding device according to claim 4. The information acquired from the charging device includes information on an operation history of the charging device, or a current value or a voltage value of power fed from the power feeding device measured by the charging device.
The power feeding device according to claim 5. The information acquired from the charging device includes an identifier unique to the charging device.
The power feeding device according to claim 5 or 6. The charging device communicates with the device to be charged and obtains information on the device to be charged,
The information acquired from the charging device by the control means includes information on the charged device.
The power feeding device according to claim 5. The information on the charged device includes information on an operation history of the charged device, or a current value or a voltage value of power supplied from the charging device measured by the charged device.
The power feeding device according to claim 8. The information on the charged device includes a unique identifier of the charged device.
The power feeding device according to claim 8 or 9. The charged device is an electric vehicle,
Information acquired from the charging device or information on the charged device is information that conforms to the CHAdeMO standard.
The power feeding device according to claim 8. Power generation means,
The control means further controls power feeding from the power generation means to the power storage element or the power system.
The power feeding device according to claim 1. Powered from at least one of the power system, the storage element, or the power generation means, and provided with an auxiliary power feeding unit that feeds power to an external load.
The power feeding device according to any one of claims 1 to 12. The control means performs communication with the outside by superimposing a communication signal on a line connecting the auxiliary power feeding unit and the power system, the power storage element, or the DC power generation means.
The power feeding device according to claim 13. The power system is a single-phase three-wire system.
The electric power feeder in any one of Claim 1 to 14. Receiving power supply from a power supply device having a power storage element that stores power supplied from the power system, and a control unit that controls power supply from the power system to the power storage element and power supply stored in the power storage element. A charging device that operates and charges a charged device,
Comprising communication means for communicating with the power feeding device and / or the device to be charged;
The communication unit transmits its own information and / or information of the charged device to be used for the operation of the control unit to the power supply device.
Charging device. A power supply device that stores power supplied from an electric power system, and a control unit that controls power supply from the power system to the power storage element and power supply stored in the power storage element;
A power supply device that operates by receiving power from the power supply device and performs charging for the device to be charged;
The charging device has communication means for communicating with the power feeding device and / or the charged device,
The control unit of the power supply device performs a control operation using the information on the charging device and / or the information on the charged device acquired from the communication unit of the charging device.
Charging system. Power generation means;
A power storage element for storing power supplied from an external power system or the power generation means; (a) power supply from the power generation means to the power storage element; (b) power supply from the power system to the power storage element; A power supply apparatus comprising: control means for controlling power supply to a load that operates with power stored in the power storage element; and (d) power supply from the power generation means to the power system;
A charging device that operates by feeding from the power feeding device as the load and charges the device to be charged,
Charging system. A power supply device comprising: a power storage element that stores power supplied from a power system; and a control unit that controls power supply from the power system to the power storage element and power supply stored in the power storage element, The control means uses information on the charging device and / or information on the charged device acquired from a charging device that operates by receiving power stored in the power storage element and charges the charged device. Of the power feeding device that performs the control operation by
A program for operating a computer as the control means. A power generation means; an electricity storage element for storing power supplied from an external power system or the power generation means; (a) power supply from the power generation means to the power storage element; and (b) power supply from the power system to the power storage element. A power feeding device having power feeding, and (c) control means for controlling power feeding to a load operated by the power stored in the power storage element, and (d) power feeding from the power generation means to the power system, and A charging system comprising a charging device that operates as a load and that is charged by the power supply device and charges the device to be charged,
A program for operating a computer as the control means of the power supply apparatus.

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