JP2013183594A - Electric vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To construct an on-vehicle charger for performing optimum charging for an electric vehicle.SOLUTION: In the electric vehicle having a charger for charging electric power into a battery, the charger calculates required electric energy of the battery on the basis of respective information about a distance of a travel route up to a destination of the electric vehicle, an estimated traffic state of the travel route, weather forecast of the travel route and fuel economy data by the driver and performs charging so that battery electric energy becomes the required electric energy.

Description

  The present invention relates to battery charging of an electric vehicle.

  The structure of the conventional vehicle-mounted charger 6 for electric vehicles and the electric vehicle 1 is shown in FIG. The in-vehicle charger 6 converts the alternating current (AC) power drawn from the distribution line 12 into direct current (DC) power according to a command from the charger management unit 21 that controls the entire in-vehicle charger and the charger management unit 21. And a power converter (AC → DC) 23 for charging the battery 4 of the electric vehicle 1. The electric vehicle 1 includes a battery 4 that stores electric power, a battery management unit 3 that manages the remaining electric power of the battery 4, and the like. In addition, the structure of the vehicle-mounted charger 6 and the electric vehicle 1 is abbreviate | omitting about the apparatus which is not related to battery charge.

 The operation of the conventional on-vehicle charger 6 for electric vehicles and the electric vehicle 1 is shown in FIG. The driver of the electric vehicle connects the distribution line 12 and the electric vehicle 6 with the charging outlet 7. The in-vehicle charger 6 requests the remaining power and the chargeable amount of the battery 4 from the battery management unit 3. The battery management unit 3 returns the remaining power of the battery 4 and the chargeable amount to the in-vehicle charger 6. The on-vehicle charger 6 determines the amount of charge and starts charging. During charging, the battery management unit 3 monitors the state of the battery 4. When the on-vehicle charger 6 is charged for the amount of charge, the charging ends. The driver disconnects the charging outlet 7.

Charging the battery 4 of the electric vehicle 1 is often performed at night after returning home. Here, as shown in FIG. 2, when there is a home (= charging place) in the middle of a road with a difference in elevation, the electric vehicle 1 that goes down the slope from the home toward the point A tomorrow morning, Electric power can be recovered and charged to the battery 4 by regenerative braking of the motor during traveling down. At the same time, the driver can go down the hill while the engine brake is working. Therefore, the in-vehicle charger 6 must leave the battery 4 with a charge capacity sufficient to store the recovered power by the motor regenerative braking. If the battery 4 is fully charged, the battery 4 cannot be charged, and there is a danger that the engine brake by the motor regenerative braking is not effective when going down the slope. In addition, there is a problem of throwing away recoverable power.
Conversely, if the amount of charge to the battery 4 is reduced in consideration of power recovery by motor regenerative braking when going down the hill, the electric vehicle 1 that goes up the hill toward the B point from the home is charged frequently. It becomes a problem that must be reached, and in some cases, it may not be possible to reach point B.

 Therefore, as in Patent Document 1, a system is known in which a charger is used to acquire weather information and traffic information, and optimal power purchase is performed. In addition, as disclosed in Patent Document 2, it is also known to use route information to a destination for calculating an optimum power consumption amount. However, in any of the above prior arts, there is a possibility that power consumption fluctuations due to fuel consumption differences based on driving habits or the like of individual drivers may occur, and optimal charging cannot be achieved.

JP 2007-206889 JP 2011-120327 A

  In view of the above problems, an object of the present invention is to avoid the possibility of fluctuations in power consumption due to differences in fuel consumption based on driving habits of individual drivers and to ensure more appropriate charging.

In order to solve the above problem, in the present invention, in an electric vehicle equipped with a charger for charging power to a battery, the charger is a distance of a travel route to a destination of the electric vehicle, a traffic of the travel route. The required power amount of the battery is calculated based on the information on the situation prediction, the weather forecast of the travel route, and the fuel consumption data for each driver.
In the electric vehicle of the present invention, the charger may be charged so that the battery power amount becomes the required power amount.
In the electric vehicle of the present invention, the charger may charge the battery using a difference between the calculated required power amount of the battery and the remaining power amount of the battery at the time of calculation as the charging power amount.

Furthermore, in the electric vehicle of the present invention, in the electric vehicle equipped with a charger for charging power to the battery, the charger is the distance of the travel route to the destination of the electric vehicle, the traffic situation prediction of the travel route, The required power amount of the battery is calculated based on the information about the weather forecast of the driving route and the fuel consumption data for each driver, and the required power amount calculated by the charger is larger than the remaining battery power amount at the time of calculation. If it is smaller, all or part of the difference between the remaining battery power at the time of calculation and the calculated required power is sold.
In the electric vehicle of the present invention, the charger may store fuel efficiency data for each driver in advance.

  According to the present invention, the in-vehicle charger comprehensively determines the destination of the electric vehicle, the distance of the travel route, the traffic congestion prediction information of the travel route, the weather forecast information, and the fuel consumption data of the driver, Since the amount of charge is calculated, if you go down the hill, reduce the amount of charge, increase the amount of charge because the air conditioner is used when the summer temperature is high, or move the wiper on rainy days so increase the amount of charge It is possible to make adjustments. As a result, there is an effect that it is possible to reduce the risk that electric power is wasted and engine braking is not effective when going down a slope. Furthermore, when the amount of charge of the battery of the electric vehicle is large, such as when going down a hill, surplus power can be taken out from the battery of the electric vehicle and sold to the distribution line, so that energy is not wasted. There is also an effect that can be completed.

The block diagram of the vehicle-mounted charger and electric vehicle of this invention. The figure which shows the positional relationship of a destination and a home. FIG. 3 is a diagram illustrating an operation of the first embodiment of the present invention. The figure which shows operation | movement of 2nd Embodiment of this invention. The block diagram of the conventional vehicle-mounted charger and an electric vehicle. The figure which shows operation | movement of conventional embodiment.

FIG. 1 shows a configuration of an electric vehicle 1 according to a first embodiment of the present invention. In FIG. 1, devices not related to battery charging are omitted.
The electric vehicle 1 includes an in-vehicle charger 6 that charges a battery 4, a battery 4 that stores electric power, a battery management unit 3 that manages remaining electric power of the battery 4, and a car navigation system 5 that navigates a driving route to a driver. Become.

The in-vehicle charger 6 converts the alternating current (AC) power drawn from the distribution line 12 into direct current (DC) power according to a command from the charger management unit 21 that controls the entire in-vehicle charger and the charger management unit 21. And an electric power converter (AC⇔DC) 22 for charging the battery 4 of the electric vehicle 1.
The car navigation system 5 is set with information on the surroundings of the home (flat ground / downhill / on the slope / uphill, height difference of surrounding road, slope of slope). Furthermore, the car navigation system 5 acquires traffic congestion prediction information (closed traffic, traffic congestion, etc.) and weather prediction information (weather, season, temperature, humidity, etc.) from the information distribution center via the network, and stores them. I can leave.

The information distribution center 8 collects and stores surrounding information, traffic congestion prediction information, and weather prediction information in each place, and can distribute the information to the car navigation system 5 in response to a request from the car navigation system 5.
The on-vehicle charger 6 obtains the travel distance from the previous charging from the car navigation system 5 when the battery 4 is charged. Next, the on-vehicle charger 6 obtains the amount of power used since the previous charging from the battery management unit 3 and stores fuel consumption data for each driver.
FIG. 2 shows the location of the driver's home of the electric vehicle 1 equipped with the on-vehicle charger 6 of the present invention, and is an example in which the home is in the middle of a slope.

FIG. 3 shows the operation of each device in the electric vehicle during battery charging according to the first embodiment of the present invention. After returning home, the driver of the electric vehicle 1 sets the driver in the morning and the destination in the morning to the car navigation system 5. The car navigation system 5 searches for and determines a travel route to the destination in the morning. Further, the car navigation system 5 acquires traffic congestion prediction information and weather prediction information of the driving route for tomorrow from the information distribution center 8.
Next, in order to charge the battery 4 of the electric vehicle 1, the driver of the electric vehicle 1 connects the power distribution line 12 and the in-vehicle charger 21 of the electric vehicle through the charging outlet 7. The charger management unit 21 acquires the remaining power amount and chargeable amount of the battery 4 from the battery management unit 3. Further, the charger management unit 21 obtains the destination of the morning car 1, the travel route, traffic congestion prediction information of the travel route, weather forecast information, and fuel consumption data of the driver in the morning from the car navigation system 5. To do.

 The charger management unit 21 comprehensively determines the destination of the electric vehicle 1 in the morning, the travel route, traffic congestion prediction information of the travel route, weather forecast information, and fuel consumption data of the driver, and the required power of the battery 4 Calculate the amount. The charger management unit 21 instructs the power conversion unit (AC⇔DC) 22 as charging power by using the difference between the calculated required power amount and the remaining power amount of the battery 4 at the time of calculation. The power conversion unit (AC⇔DC) 22 starts charging the commanded charging power to the battery 4. During charging, the battery management unit 3 monitors the state of the battery 4. The power conversion unit (AC⇔DC) 22 ends the charging when the charging of the charging power is completed. The driver disconnects the charging outlet 7 when going out. When calculating the amount of power required for the battery 4, for example, it is reduced when going down a hill, it is increased because an air conditioner is used when the summer temperature is high, and it is increased because a wiper is moved on a rainy day, etc. Adjustments are made.

FIG. 4 shows the operation of each device in the electric vehicle when the battery is charged in the second embodiment of the present invention. After returning home, the driver of the electric vehicle 1 sets the driver in the morning and the destination in the morning to the car navigation system 5. The car navigation system 5 searches for and determines a travel route to the destination in the morning. Further, the car navigation system 5 acquires traffic congestion prediction information and weather prediction information of the driving route for tomorrow from the information distribution center 8.
Next, in order to charge the battery 4 of the electric vehicle 1, the driver of the electric vehicle 1 connects the power distribution line 12 and the in-vehicle charger 21 of the electric vehicle through the charging outlet 7. The charger management unit 21 acquires the remaining power amount and chargeable amount of the battery 4 from the battery management unit 3. Further, the charger management unit 21 obtains the destination of the morning car 1, the travel route, traffic congestion prediction information of the travel route, weather forecast information, and fuel consumption data of the driver in the morning from the car navigation system 5. To do.

 The charger management unit 21 comprehensively determines the destination of the electric vehicle 1 in the morning, the travel route, traffic congestion prediction information of the travel route, weather forecast information, and fuel consumption data of the driver, and the required power of the battery 4 Calculate the amount. Here, the operation in the case where the electric vehicle 1 travels from the point B in FIG. 2 to the home and returns home and the destination in the morning is the point A will be described below. The electric vehicle 1 is charged with electric power to the battery 4 when traveling from the point B to the home.

 Here, since it is a downhill from home to the point B and does not consume power, the required power amount of the battery 4 may be smaller than the remaining battery power amount. In this case, power is sold from the battery 4 to the power distribution line 12 instead of charging the battery 4 at home. The charger management unit 21 instructs the power conversion unit (AC⇔DC) 22 as a power sale amount using the difference power between the remaining power amount of the battery 4 and the calculated necessary power amount. At this time, it is possible to arbitrarily determine whether the power sale amount is all or part of the difference power between the remaining power amount of the battery 4 and the required power amount. The power conversion unit (AC⇔DC) 22 moves the power for the commanded power sale amount from the battery 4 to the power distribution line 12. During power sale, the battery management unit 3 monitors the state of the battery 4. When the power conversion unit (AC⇔DC) 22 moves a predetermined amount of electricity to the distribution line, the power conversion unit (AC⇔DC) 22 ends the power sale.

  DESCRIPTION OF SYMBOLS 1 ... Electric vehicle, 3 ... Battery management part, 4 ... Battery, 5 ... Car navigation system, 6 ... In-vehicle charger, 7 ... Charging outlet, 8 ... Information distribution center, 12 ... Distribution line, 21 ... Charger management part, 22, 23 ... Power converter

Claims (5)

In an electric vehicle equipped with a charger for charging power to a battery,
The charger determines the required amount of battery power based on information about the distance of the travel route to the destination of the electric vehicle, the traffic condition prediction of the travel route, the weather forecast of the travel route, and the fuel consumption data for each driver. An electric vehicle characterized by calculating. The electric vehicle according to claim 1,
The battery charger is charged so that a battery power amount becomes the required power amount. The electric vehicle according to claim 2,
The charger is configured to charge the battery by using a difference between the calculated required power amount of the battery and the remaining power amount of the battery at the time of calculation as a charging power amount. In an electric vehicle equipped with a charger for charging power to a battery,
The charger determines the required amount of battery power based on information about the distance of the travel route to the destination of the electric vehicle, the traffic condition prediction of the travel route, the weather forecast of the travel route, and the fuel consumption data for each driver. Calculate
When the required power amount calculated by the charger is smaller than the remaining battery power at the time of calculation, sell all or a part of the difference between the remaining battery power at the time of calculation and the calculated required power Electric car characterized by. The electric vehicle according to claim 1,
The battery charger stores fuel consumption data for each driver in advance.