JP5554371B2 - Charge / discharge display - Google Patents

Description

  The present invention relates to a charge / discharge display device for an electric vehicle, and more particularly to a charge / discharge display device capable of displaying electric power when discharging from an electric vehicle to a power system.

  An electric vehicle that obtains power by driving a motor using the power charged in the battery as an energy source not only charges the battery using commercial power (system power) supplied from the power system of the power company, but also recently Therefore, the role of an auxiliary power source that compensates for the shortage of electric power in the home and the electric power system by discharging electric power from the battery of the electric vehicle is beginning to be regarded as important.

  In addition, with the spread of electric vehicles, attention has been paid to charging costs generated by charging and traveling costs generated by traveling, and a method of displaying such information has been devised. As an example, as disclosed in Patent Document 1, when charging a battery from a plurality of charging sources, a charging amount display unit that classifies and displays the charging amount for each type of charging source, and traveling There has been devised a charge display device including a travel cost display unit that displays a travel cost calculated based on the power consumed by the battery and the charge cost for charging the battery.

JP 2012-71637 A

  When the electric power stored in the battery of the electric vehicle is consumed by traveling, the user bears an electric charge. On the other hand, when the electric power stored in the battery of the electric vehicle is discharged to the power system or the like, the user Can earn electricity sales. The difference between the electricity charge borne by the user and the power sales revenue is the operating cost of the electric vehicle power, which is a serious concern for the user who operates the electric vehicle.

  However, the charging display device disclosed in Patent Document 1 does not consider the case where power is discharged to the power system. For this reason, there is a problem that the user cannot know the power income from the power sale and it is difficult to recognize the cost including the operation cost of the electric vehicle.

  The present invention has been made to solve the above problems, and an object of the present invention is to provide a charge / discharge display device in which a user of an electric vehicle can easily recognize the cost.

An aspect of a charge / discharge display device according to the present invention is a charge / discharge display device for an electric vehicle that travels by driving a motor using power charged in a battery as a drive source, and the electric vehicle includes a plurality of charge sources. The battery has a function of charging the battery and discharging the electric power stored in the battery to an external discharge target, and the charge / discharge display device charges the battery from the plurality of charging sources. A charge amount display corresponding to each of the plurality of charge sources, and corresponding to a decrease in the amount of power stored in the battery when the battery power is discharged to the external discharge target. A charge / discharge amount display unit for changing and displaying the charge amount display.

According to the charge / discharge display device of the present invention, when the battery power is discharged to an external discharge target, the charge / discharge display is performed by changing the charge amount display corresponding to the decrease in the amount of power stored in the battery. Since it has a volume display, the user of the electric vehicle can recognize the power of the battery discharged to the external discharge target, and it becomes easy to know the operation cost of the electric vehicle power from the power income from power sale. It becomes easy to recognize.

It is a figure which shows typically the structure of the part relevant to this invention of an electric vehicle. It is a figure which shows the structure of the charging / discharging display apparatus which concerns on this invention. It is a figure explaining the example of the charge amount display in a charging / discharging amount display part. It is a figure explaining the change of the charge amount display in a charge / discharge amount display part. It is a flowchart explaining the operation | movement in charge / discharge mode. It is a flowchart explaining the operation | movement in driving | running | working / regeneration mode.

<Embodiment>
FIG. 1 is a diagram schematically illustrating a configuration of a portion related to the invention of an electric vehicle including a charge / discharge display device according to an embodiment.

  As shown in FIG. 1, an electric vehicle 1 includes an electric control unit (ECU) that controls a battery pack 2 that serves as a power source such as a motor (not shown) that serves as a power source of the electric vehicle 1 and the entire electric vehicle 1. Electronic Control Unit) 3, a regenerative power generation unit 4 that generates regenerative power during a braking operation, a charge / discharge display device 5, an in-vehicle charger 6, a charge source type determination unit 7, and a power cable 8.

  The battery pack 2 includes a plurality of battery cells 21 and a battery management unit 22, and the battery management unit 22 manages the charging state of the plurality of battery cells 21, and the charge rate (SOC: State of Charge) of the battery pack 2 and the like Is provided to the electronic control unit 3.

  The battery cells 21 store electric power for driving the electric vehicle 1. Each battery cell 21 is connected to the in-vehicle charger 6, and the in-vehicle charger 6 is connected to the external power source 10 such as a household power source via the power cable 8. It is configured to be connected to.

  Here, as the external power source 10, when charging the electric vehicle 1, an electric power system maintained by an electric power company, a quick charger installed in a public facility, a home solar power generator, a home wind power generator Examples of targets for discharging from the electric vehicle 1 include power systems, power storage systems such as charge / discharge compatible PCS (Power Conditioning Subsystem), NAS batteries (Sodium-sulfur Battery), and household storage batteries. It is done.

  In order to recognize these external power supplies 10, identification information such as their names and IDs is necessary. However, in order to calculate the operation cost, the amount of charging power or discharging power, and the purchase of power at the time of charging It is also necessary to obtain information such as a power charge or a power charge for selling electricity at the time of discharge.

  In addition, the grid power supplied from the power grid may reduce the charge per unit power, such as the night charge that is set at a time when the system load is low, such as at night. Information is also needed.

  There are various methods for information communication means for obtaining such information at the time of charging or discharging, but typical examples include PLC communication (Power Line Communications) for superimposing a communication signal on a power line, and wireless communication. Wireless communication such as LAN and Bluetooth (trademark) can be mentioned. Information obtained through these information communication means (not shown) is given to the charging source / discharge target type determination unit 7 and is transmitted from the charging source / discharge target type determination unit 7 to the ECU 3 to calculate operation costs, etc. Arithmetic processing is performed.

  The ECU 3 receives the information about the SOC of the battery pack 2 received from the battery management unit 22 and the information about the type of the external power source 10 from the charge source / discharge target type determination unit 7, and associates the information with the information about the SOC of the battery pack 2. It is known how much charge has been performed by which charge source or how much discharge has been performed for which discharge target, and the result is displayed on the charge / discharge display device 5.

  In the electric vehicle 1, when braking (braking) is performed, braking by regenerative braking is first performed. At this time, regenerative power is generated by the regenerative power generation unit 4 and accumulated in the battery pack 2. This regenerative power is also one of the power supply sources. When the regenerative power is accumulated, the information is given to the ECU 3, and the degree of charging is performed by the regenerative power by making it correspond to the SOC information of the battery pack 2. You can know.

  And when the electric power of the battery pack 2 is consumed (discharged) by traveling of the electric vehicle 1, the traveling cost is calculated based on the amount of electric power and the unit price of electric power classified for each charging source, and the result is displayed as charge / discharge. Display on device 5.

  FIG. 2 is a diagram showing a configuration of the charge / discharge display device 5 according to the present invention. The charge / discharge display device 5 includes a charge / discharge amount display unit 50, a speed display unit 51, and a travel cost display unit 52.

  The charge / discharge amount display unit 50 is a part that displays the SOC of the battery pack 2 classified according to the type of the charge source, and shows an example of displaying it in a bar graph form here. The speed display unit 51 is a part that displays the vehicle speed during travel of the electric vehicle 1. In addition, the travel cost display unit 52 includes the amount of power stored in the battery pack 2, the power of the battery consumed by travel, the balance of power purchase revenue and operating revenue during charging, and the electric vehicle. This is a portion for displaying the travel cost (unit: yen / km) calculated by the ECU 3 based on the travel distance of 1 or the like.

  The charge / discharge display device 5 is configured by using a liquid crystal display (LCD) or an organic EL-organic display (Organic Electro-Luminescence Display), and the charge / discharge amount display unit 50 color-codes the type of charge source. Can be displayed.

  Note that the charge / discharge display device 5 is configured to be able to display even when the electric vehicle 1 is not traveling, such as when the electric vehicle 2 is charged and discharged.

  Next, an example of the charge / discharge display in the charge / discharge power display unit 50 will be described with reference to FIG. FIG. 3 shows a display state when electric power obtained from a plurality of charging sources is accumulated in the battery pack 2, and the type of the charging source is displayed in a bar graph on the charging / discharging power display unit 50 whose outer shape is rectangular. The electric power accumulated in the battery pack 2 is shown according to the display area.

  Fig. 3 shows an example of charging with grid power for daytime charges (system daytime power), grid power for night charges (system nighttime power), and power from solar power generation. An area R1 indicating charging, an area R2 indicating charging by grid night power in the middle stage, and an area R3 indicating charging by electric power from solar power generation are shown in the middle stage, and the SOC of the battery pack 2 is about 80% as a whole. ing. By performing such a display, it becomes easy to recognize the increase or decrease in power.

  Here, the display of the electric energy is not limited to the display by the bar graph, but the graphic display by the pie chart or the like, the digital display by the numerical value, and the display by the brightness of the lamp or the like can be considered.

  Next, changes in the display state of the charge / discharge power display unit 50 due to discharge will be described with reference to FIG. FIG. 4A shows a charge / discharge amount display unit 50 before the electric vehicle 1 travels. The battery pack 2 is charged by system daytime power (region R1) and system nighttime power (region R2). ) And photovoltaic power generation (region R3). The SOC of the battery pack 2 as a whole is almost 100%.

  FIG. 4 (b) shows a charge / discharge power display unit 50 when the electric vehicle 1 discharges power to the power system or the like to reduce the amount of power stored in the battery pack 2. The amount of power is displayed as the power consumed at the same rate in the regions R1 to R3 corresponding to the respective charging sources. By performing such display, it becomes easy to recognize power consumption.

  In addition, as a display method of the charge / discharge power display unit 50 when the amount of power decreases due to discharge, for example, a display area corresponding to a charging source with a low charge cost (a power purchase price per unit power) is given priority to an area. The display may be reduced, or conversely, the display area corresponding to the charging source having a high charging cost may be preferentially displayed with the area reduced. Furthermore, after the display area using the solar power generation for home use or the wind power generation for home use where the charging cost does not occur as a charging source is prioritized and the area is reduced, the display of those electric energy amounts becomes zero. For the display areas corresponding to the remaining charging sources, the amount of power may be displayed as if power was consumed at the same rate.

  By performing such display, the cost awareness of the user of the electric vehicle 1 can be increased.

  By preparing such a plurality of display methods, the options of the user of the electric vehicle 1 are expanded. Then, which of the display methods is selected is determined by how the user of the electric vehicle 1 recognizes the power purchase expenditure during charging and the balance (operating cost) of the power sales revenue due to the discharge. It is sufficient that the user can arbitrarily select from a plurality of display patterns.

  Thereby, the user of the electric vehicle 1 looks at the charging / discharging power display unit 50, and when charging by the external power source 10 or charging by power regeneration accompanying traveling, the type of charging source, the amount of charging power, and the charging cost Can be recognized in a timely and graphical manner. In addition, when performing power consumption by traveling or selling power to the power system, it is timely and graphically shown how much the power charged by which charging source is discharged and how much power sales revenue is generated. Can be recognized.

    And, for example, when charging from a high-cost charging source, the operation of electric vehicles that are cost-conscious, such as discharging at a time when the power unit price of power sale is high or when the power unit price of power sale is high Is possible.

  Next, a method for calculating the average value of travel costs displayed on the travel cost display unit 52 will be described. In the calculation of the average value of travel costs, first, for each charging source, the total amount is calculated by multiplying the charging power amount (kWh) by the unit price of electric power purchased at the time of charging (charging cost: yen / kWh). The total amount of electricity purchase is obtained. Further, when the discharge target is discharged, the discharge power amount (kWh) for each discharge target is multiplied by the power unit price of power sold at the time of discharge (discharge cost: Yen / kWh), and the total sum is obtained. To calculate the total amount of electricity sold. Here, the charging cost is multiplied as a negative value, the discharging cost is multiplied as a positive value, and the sum of the two is taken, so that the operation cost (the power purchase expenditure at the time of charging and the power selling revenue due to the discharge is calculated). Balance).

  By dividing this operation cost by the travel distance (unit: km) of the electric vehicle 1, an average value (unit: yen / km) of the travel cost is obtained.

  By obtaining the average travel cost, the user of the electric vehicle 1 can know the travel cost for one operation of the electric vehicle 1.

  Next, a method for calculating the instantaneous value of travel costs will be described. First, an average unit price (unit: yen / kWh) of the electric power stored in the battery is obtained by dividing the above-mentioned operation cost (unit: yen) by the sum of the charged electric energy and the discharged electric energy. Then, the average unit price (unit: yen / kWh) of the electric power stored in the obtained battery is the electric power consumed by running the electric vehicle 1 (unit: kW) or the electric power charged by the electric power regeneration of the electric vehicle 1 By multiplying (unit: kW), the cost per unit (unit: yen / h) is obtained. By dividing this cost per hour by the speed (unit: km / h) of the electric vehicle 1, an instantaneous value (unit: yen / km) of the travel cost is obtained.

  Further, the travel distance (unit: km) is divided by the amount of power consumed (unit: kWh) by traveling, or the speed (unit: km / h) is consumed by traveling or charged by regeneration (unit: kW). It is also possible to calculate a so-called power consumption (unit: km / kWh) by dividing by. Note that the power consumption can be defined by the reciprocal number, and by switching these to be displayed, the range of user selection can be expanded.

  In addition, although the average value and the instantaneous value of the travel cost are expressed in units of yen / km, there are cases where they are expressed in units of km / yen. The range of selection can be expanded.

  Further, a value obtained by multiplying the consumed power amount (unit: kWh) by the charging cost (unit: yen / kWh) of the charging source without using the travel distance (unit: km) (unit: yen) Can be displayed as a cost related to charging or discharging. In this case, cost management as an electric power storage system connected to the electric power system becomes easy.

  Details of the method for calculating the average value and the instantaneous value of the travel costs described above will be described with reference to FIGS. 1 and 2 and the flowcharts of FIGS. 5 and 6.

  FIG. 5 shows a method of calculating the charge power amount or the discharge power amount in the charge / discharge mode, that is, when the electric vehicle 1 is connected to the external power source 10 via the power cable 8 and is in a state of charging or discharging. It is a flowchart to explain.

  A charging source stored in advance in a storage device (not shown) in the ECU 3 when the ECU 3 starts a control operation by turning on the power with the key switch of the electric vehicle 1 or connecting the power cable 8 to the electric vehicle 1. Then, data classified for each discharge target is read (step S1).

  The contents of this data include the identification information such as the name and ID of the charging source and discharging target, the charging power amount obtained at each charging source, and the purchase power at the time of charging corresponding to each charging source or discharging target. It includes information such as the unit price of electric power (charging cost), the amount of electric power discharged for each discharge target, and the electric power unit price (discharging cost) of selling power at the time of discharging.

  Next, charge / discharge power cost information necessary for calculating the operation cost is acquired from the external power supply 10 via an information communication means (not shown) (step S2). Here, the cost information of the charge / discharge power is information such as identification information related to the charge source or discharge target to which the electric vehicle 1 is currently connected, and the unit price of power corresponding to the charge source or discharge target.

  After acquiring the charge / discharge power cost information, charging or discharging is started (step S3).

  During charging or discharging, the charging power or discharging power is always measured (step S4), and the charging power or discharging power is displayed on the traveling cost display unit 52 of the charging / discharging display device 5 (step S5). The charge power or the discharge power is accumulated by time integration, and the charge power or the discharge power is calculated (step S6).

  In step S7, the end of charging or discharging is determined. If charging or discharging has not ended, the operations in step S4 and subsequent steps are repeated. On the other hand, when the charging or discharging is completed, the total amount of charging power or discharging power is displayed on the travel cost display unit 52 (step S8). Note that the end of charging or discharging is determined, for example, by the battery management unit 22 giving the ECU 3 information on whether or not the SOC of the battery pack 2 has been determined in advance.

  And in the case of charge, the data in the said memory | storage device are updated by preserve | saving in the memory | storage device in ECU3 the information of charge electric energy and the electric power unit price (charging cost) of the charging source which received charge ( Step S9). In the case of discharging, the data in the storage device is updated by storing the information on the amount of discharged power and the unit price of electric power (discharge cost) when selling power to the discharge target in the storage device in the ECU 3. (Step S9). The update data obtained in step S9 is classified for each charging source or discharging target and stored in the storage device. When the data update is completed, the charge / discharge mode is terminated.

  In addition, the type of charging source and power unit price (charging cost) information when receiving the charge included in the updated data, the type of discharge target when discharging and the power unit price (discharging cost) when selling power Is displayed on the charge / discharge amount display unit 50 and the travel cost display unit 52.

  That is, when the data is updated when charging is performed, the display of the charge / discharge amount display unit 50 changes. For example, when the data is displayed as a bar graph as shown in FIG. 4, it corresponds to the charging source that performed the charging. The area of the display area increases in accordance with the amount of charging power, the name of the charging source in the area is displayed, and the charging cost is displayed on the travel cost display unit 52.

  On the other hand, even when the discharge is performed, when the data is updated, the display of the charge / discharge amount display unit 50 changes. For example, when the data is displayed as a bar graph as shown in FIG. The travel cost display unit 52 displays the discharge cost.

  Here, as a display method of the charge / discharge amount display unit 50 in the case of discharge, for example, as shown in the part (b) of FIG. 4, power is consumed at the same rate in the area corresponding to each charging source. However, the display area corresponding to the charging source having a low charging cost (power purchase price per unit power) may be displayed with a reduced area. Conversely, a display area corresponding to a charging source with a high charging cost may be preferentially displayed with a reduced area. Furthermore, after the display area using the solar power generation for home use or the wind power generation for home use where the charging cost does not occur as a charging source is prioritized and the area is reduced, the display of those electric energy amounts becomes zero. For the display areas corresponding to the remaining charging sources, the amount of power may be displayed as if power was consumed at the same rate.

  FIG. 6 is a flowchart for explaining a method for calculating an average value and an instantaneous value of travel costs when the vehicle is in the travel / regeneration mode, that is, when the electric vehicle 1 is traveling.

  The ECU 3 starts a control operation by turning on the power with the key switch of the electric vehicle 1 and reads out the data classified for each charging source and discharging target stored in a storage device (not shown) in the ECU 3 in advance. This is performed (step S21). Note that this data is data updated in the charge / discharge mode described with reference to FIG. 5, and is data obtained before the electric vehicle 1 travels.

  The contents of this data include the identification information such as the name and ID of the charging source and discharging target, the charging power amount obtained at each charging source, and the purchase power at the time of charging corresponding to each charging source or discharging target. It includes information such as the unit price of electric power (charging cost), the amount of electric power discharged for each discharge target, and the electric power unit price (discharging cost) of selling power at the time of discharging.

  Next, the charging power amount corresponding to each charging source, the charging cost at the time of charging at each charging source or the discharging power amount corresponding to each discharging target, and the discharging at the time of discharging to each discharging target The operating cost of the electric power stored in the battery pack 2 is calculated from the cost (step S22).

  In calculating the operation cost, the total amount of electricity purchased is obtained by multiplying the charging power amount and the charging cost for each charging source and calculating the sum. Furthermore, when discharging is performed on the discharge target, the total amount of power sold is obtained by multiplying the discharge power amount by the discharge cost for each discharge target and calculating the sum. Here, the charging cost is multiplied as a negative value, the discharging cost is multiplied as a negative value, and the sum of the two is taken, so that the operation cost (the power purchase expenditure at the time of charging and the power sales revenue due to the discharge is calculated). Balance).

  The operation until the operation cost of the electric power stored in the battery pack 2 is calculated is performed until the electric vehicle 1 can run after the power is turned on by the key switch of the electric vehicle 1. The cost may be displayed on the travel cost display unit 52 of the charge / discharge display device 5.

  When the electric vehicle 1 travels, power regeneration is possible (step S23), and speed measurement is started (step S24). Then, the travel distance is calculated by integrating the measured speed over time (step S25). Moreover, the discharge electric power by driving | running | working and the charging electric power by regeneration are measured (step S26), and the discharge electric energy by driving | running | working and the charging electric energy by regeneration are calculated by integrating this (step S27).

  Next, based on the results obtained in steps S22 and S24 to S27, an instantaneous value of travel cost is calculated (step S28).

  In calculating the instantaneous value of the travel cost, first, the power stored in the battery pack 2 is divided by dividing the operation cost (unit: yen) obtained in step S22 by the sum of the charge power amount and the discharge power amount. The average unit price (unit: yen / kWh) is obtained. Then, the cost per unit (unit: yen / h) is obtained by multiplying the average unit price of the obtained power by the power consumption (unit: kW) obtained in step S26 or the regenerative charge power (unit: kW). Get. By dividing the cost per time by the speed (unit: km / h) obtained in step S24, an instantaneous value (unit: yen / km) of the travel cost is obtained. The obtained instantaneous value of the travel cost is displayed on the travel cost display unit 52 (step S29).

  In the determination of whether or not the traveling / regenerative mode has ended (step S30), the traveling / regenerative mode is continued, that is, the electric vehicle 1 is traveling or the gear of the electric vehicle 1 is neutral. If this is the case, the processes in and after step S24 are repeated.

  On the other hand, when it is determined that the travel / regenerative mode has ended, for example, when the ECU 3 confirms that the gear of the electric vehicle 1 is in the parking position, the final value of the travel distance calculated in step 25 is used. The sum of the travel distances is obtained, and the sum of the discharge power amounts and the sum of the charge power amounts are obtained from the discharge power amount calculated in step S27 and the final value of the charge power amount by regeneration. Then, an average value of the travel cost is calculated from the total travel distance and the operation cost information (step S31).

  That is, the average value (unit: yen / km) of the travel cost is obtained by dividing the operation cost (unit: yen) obtained in step S22 by the total travel distance (unit: km) of the electric vehicle 1. The average value of the obtained travel costs is displayed on the travel cost display unit 52 (step S32).

  Next, the data in the storage device is updated by storing the information on the amount of charging power obtained by regeneration in the storage device in the ECU 3 (step S33). Here, the electric power obtained by regeneration has a power unit price (charging cost) of 0, but the information is also stored in the storage device in the ECU 3.

  In the traveling / regenerative mode, when the charge / discharge amount display unit 50 is displayed as a bar graph as shown in FIG. 4, the display area is displayed so that the area of the display area decreases in accordance with the amount of electric power discharged by traveling. In addition, a display area using power regeneration as a charging source is added. When the data update is completed, the traveling / regenerative mode is terminated.

  As described above, in the charge / discharge mode, the travel cost display unit 52 of the charge / discharge display device 5 displays the charge power or discharge power, the charge power amount or the discharge power amount, and the charge / discharge amount. In the display unit 50, the name of the charging source is displayed when charging is performed, the charging cost is displayed on the traveling cost display unit 52, and the discharging cost is displayed on the traveling cost display unit 52 when discharging is performed. The cost is displayed.

  In the travel / regenerative mode, the travel cost display unit 52 displays the operation cost (the balance of power purchase revenue during charging and the revenue of power sales due to discharge), the instantaneous value of travel cost, and the average value of travel cost. Can be displayed.

  For this reason, the user of the electric vehicle 1 can know the charging cost when charging from the external power source 1, can know the discharging cost when selling power to the external power source 1, and It is possible to accurately and timely grasp the cost (the amount of electricity purchased during charging and the income and expenditure of electricity sales due to discharging).

  In addition, since the instantaneous value of the travel cost can be obtained during travel, it is possible to operate the electric vehicle in consideration of cost, such as avoiding unnecessary rapid acceleration or actively utilizing power regeneration.

  In the present invention, the embodiments can be appropriately modified and omitted within the scope of the invention.

  2 battery pack, 5 charge / discharge display device, 21 battery cell, 50 charge / discharge amount display section, 52 travel cost display section.

Claims (10)

A charge / discharge display device for an electric vehicle that travels by driving a motor using power charged in a battery as a drive source,
The electric vehicle is
While charging the battery from a plurality of charging sources, and having a function of discharging the electric power stored in the battery to an external discharge target,
The charge / discharge display device
When the battery is charged from the plurality of charging sources, the charge amount is displayed in correspondence with each of the plurality of charging sources, and the battery power is discharged to the external discharge target. A charge / discharge display device comprising: a charge / discharge amount display unit that changes and displays the charge amount display in response to a decrease in the amount of power stored in the battery. The charge / discharge amount display section
When the battery power is discharged to the discharge target,
The charge / discharge display device according to claim 1, wherein in the charge amount display corresponding to each of the plurality of charge sources, the charge amount display is changed and displayed on the assumption that power is consumed at the same rate. The charge / discharge amount display section
When the battery power is discharged to the discharge target,
In the charge amount display corresponding to each of the plurality of charge sources,
The charge / discharge display device according to claim 1, wherein the charge amount display corresponding to a charging source with a low charging cost defined by a power purchase price per unit power is preferentially changed and displayed. The charge / discharge amount display section
When the battery power is discharged to the discharge target,
In the charge amount display corresponding to each of the plurality of charge sources,
The charge / discharge display apparatus according to claim 1, wherein the charge amount display corresponding to a charge source having a high charge cost defined by a power purchase price per unit power is preferentially changed and displayed. The charge / discharge amount display section
When the battery power is discharged to the discharge target,
In the charge amount display corresponding to each of the plurality of charge sources,
First, after changing the charge amount display corresponding to a charging source that does not require a charging cost, the charge amount display corresponding to the remaining charge sources is assumed to have consumed power at the same rate. The charge / discharge display device according to claim 1, wherein the charge / discharge display device is displayed while being changed. The charge / discharge amount display section
The charge amount display corresponding to each of the plurality of charge sources displays an increase / decrease in the amount of power stored in the battery by increasing / decreasing a display area. Charge / discharge display device. The charge / discharge display device
The operating cost defined by the balance between the purchase of electricity for charging the battery and the revenue of power sales obtained by discharging the battery power to the discharge target, and the running of the electric vehicle The charge / discharge display apparatus according to claim 1, further comprising a travel cost display unit that displays the calculated travel cost. The electricity sales revenue is
It is defined by a value obtained by multiplying a discharge power amount corresponding to the discharge target by a power sale price per unit power,
The electricity purchase expenditure is
It is defined by a value obtained by multiplying the amount of electric power charged to the battery and a power purchase price per unit power,
The travel cost display section
When the battery power is discharged to the discharge target,
The charge / discharge display device according to claim 7, wherein a value obtained by dividing an operation cost defined by a balance between the power purchase expenditure and the power sale revenue by a travel distance of the electric vehicle is displayed as the travel cost. . The electricity sales revenue is
It is defined by a value obtained by multiplying a discharge power amount corresponding to the discharge target and a power sale price per unit power,
The electricity purchase expenditure is
It is defined by a value obtained by multiplying the amount of electric power charged to the battery and a power purchase price per unit power,
The travel cost display section
When the battery power is discharged to the discharge target,
The charge / discharge display device according to claim 7, wherein a value obtained by dividing a travel distance of the electric vehicle by an operation cost defined by a balance between the power purchase expenditure and the power sale revenue is displayed as the travel cost. . The electric vehicle is
The discharge power discharged from the battery during travel and the charge power due to regeneration are measured, and the discharge power amount due to travel and the charge power amount due to regeneration are calculated by integrating this, and the travel speed is measured,
The travel cost display section
To the average unit price of the electric power stored in the battery obtained by dividing the operation cost by the sum of the charged electric energy and the discharged electric energy, the electric power consumed by running or the electric power charged by electric power regeneration is The charge / discharge display device according to claim 7, wherein a cost per time is obtained by multiplication, and a value obtained by dividing the cost per time by a travel speed is displayed as the travel cost.

Images