JP3622291B2 - Vehicle travelable distance display device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vehicle travelable distance display device suitable for use by a driver to easily grasp the remaining capacity state of a battery in an electric vehicle and the remaining state of fuel in an internal combustion engine type vehicle.
[0002]
[Prior art]
At present, internal combustion engine vehicles equipped with gasoline engines, diesel engines, etc. are mainly used as automobiles, but electric vehicles are also attracting attention from the viewpoint of preventing air pollution and reducing noise caused by vehicles.
In the case of an internal combustion engine type vehicle, the fuel is energy for traveling, and in the case of an electric vehicle, the electricity charged in the battery is energy for traveling.
[0003]
If the driver does not recognize the remaining amount of energy for driving (that is, the remaining amount of fuel and the remaining capacity of the battery), the energy cannot be properly supplied (that is, the fuel is replenished and the battery is charged). .
Therefore, a normal automobile is equipped with a fuel meter and a battery remaining capacity meter, and the driver selects the timing for refueling and charging the battery while looking at such a meter. The remaining amount of driving energy (the remaining amount of fuel and the remaining capacity of the battery) indicates how much the vehicle can travel after this, that is, the remaining amount of driving energy is displayed by the driver so that the travelable distance of the vehicle is displayed. A technology that allows them to grasp the situation has also been developed.
[0004]
In order to display such a travelable distance, it is naturally necessary to estimate the travelable distance.
For example, in the case of an internal combustion engine-type automobile, the conventional estimation of the travelable distance is, as disclosed in Japanese Utility Model Publication No. 5-84828, a fuel consumption rate or a travel distance per unit consumption of fuel. Based on a differential value (difference value) of (= travel distance / unit consumption of fuel), a travelable distance until the remaining fuel amount at that time becomes empty is calculated.
[0005]
When such estimation is applied to an electric vehicle, it is based on a differential value (difference value) of a battery power consumption rate or a travel distance per unit discharge amount of the battery (= travel distance / unit discharge amount of the battery). It is conceivable to calculate a travelable distance until the battery capacity at that time reaches a level at which travel is impossible.
[0006]
[Problems to be solved by the invention]
However, as described above, when the travelable distance is estimated by a calculation based on a differential value such as the consumption rate of the mounted energy, the travelable distance display may suddenly change in a short time when the travel state suddenly changes depending on traffic conditions. .
For example, since the travel distance per unit consumption energy is shortened on a congested road, the travelable distance is also shortened. On a suburban road where there is no traffic jam, the travel distance per unit consumption energy is long, so the travelable distance is also long.
[0007]
For this reason, once the vehicle exits from a congested road, a situation may occur in which the travelable distance suddenly increases. If the travelable distance estimated in this way is displayed, the driver may be confused.
The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a travelable distance display device for a vehicle that can more accurately estimate the travelable distance and display the correct travelable distance. .
[0008]
[Means for Solving the Problems]
For this reason, the travelable distance display device for a vehicle according to the first aspect of the present invention uses energy storage means mounted on the vehicle for storing travel energy, and the travel energy for running the vehicle. The driving output generating means for driving the driving wheels of the vehicle, and the instruction output to be generated by the driving output generating means based on the operation through the operating means are calculated, and the drive from the energy storage means based on the instruction output A controller for controlling the supply of the traveling energy to the output generating means, and at leastActual output detecting means for detecting the actual output generated by the drive output generating means;Vehicle state detection means having travel distance detection means for detecting the travel distance of the vehicle, and residual energy amount detection means for detecting the remaining amount of travel energy stored in the energy storage means; and the travel distance First storage means for storing a plurality of sets of data consisting of a detected travel distance value and a detected remaining energy amount detected simultaneously by the detection means and the remaining energy amount detection means;A second storage means for storing a plurality of sets of data consisting of an actual output detection value and a residual energy amount detection value detected simultaneously or substantially simultaneously by the actual output detection means and the residual energy amount detection means; and the second storage Effective remaining energy amount calculating means for estimating the remaining energy amount by which the actual output generated by the drive output generating means is less than or equal to a preset lower limit value based on the stored data stored in the means, and the effective remaining amount By the time the remaining energy amount calculated by the energy amount calculating means reaches the first set value,Based on the plurality of sets of data stored in the first storage means, the travelable distance calculating means for calculating the travelable distance of the vehicle using the least square method, and the travelable distance calculating means It is characterized by comprising display means for displaying the travelable distance.
[0009]
According to a second aspect of the present invention, there is provided the vehicle travelable distance display device according to the first aspect of the present invention, wherein the first storage means includesMultiple sets of dataAt regular intervalsRecorded inIt is characterized by memorizing.
A travelable distance display device for a vehicle according to a third aspect of the present invention is characterized in that, in the device according to the second aspect, the first storage means performs the above-mentioned storage in a shorter cycle when the device is started. Yes.
[0010]
ContractClaim4The travelable distance display device for a vehicle according to the present invention described in claim1In the described apparatus,The second storage meansWhen the ratio of the actual output to the instruction output is equal to or less than the second set value, the actual output detection value corresponding to each other and the remaining detected by the actual output detection means and the residual energy amount detection means simultaneously or substantially simultaneously Store multiple sets of energy detection valuesRukoIt is characterized by.
[0011]
Claim5The travelable distance display device for a vehicle according to the present invention described in claimAny one of 1-4In the described device, the second storage means periodically stores a plurality of sets of the actual output detection value and the residual energy amount detection value corresponding to each other at predetermined time intervals, and the effective residual energy amount calculation means includes: The residual energy amount is calculated using a least square method.
[0012]
Claim6The travelable distance display device for a vehicle according to the present invention described in claims 1 to5The device according to any one of the above, wherein the energy storage means is a battery and the drive output generation means is an electric motor..
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIGS. 1 to 6 show a travelable distance display device for a vehicle according to an embodiment of the present invention, and FIG. Is a diagram for explaining the motor instruction output, FIG. 3 is a diagram for explaining the calculation of the travelable distance, FIG. 4 is a diagram for explaining the calculation of the effective remaining capacity, and FIG. 5 is a diagram for explaining the calculation of the travelable distance. FIG. 6 is a flowchart for explaining the calculation of the effective remaining capacity.
[0014]
As shown in FIG. 1, the travelable distance display device for a vehicle according to the present embodiment is mounted on an electric vehicle. In FIG. 1, reference numeral 1 denotes an on-vehicle as an energy storage means mounted on the vehicle to store travel energy. This is a battery, and this battery 1 can be repeatedly charged by an external charger that is not installed in the vehicle. Reference numeral 2 denotes an electric motor (traveling motor) as drive output generating means to which electric power (that is, traveling energy) is supplied from the battery 1, and driving wheels 4 are connected to an output shaft of the motor 2 via a transmission 3. Has been driven.
[0015]
A power conversion circuit 5 is provided between the battery 1 and the motor 2 so that the power from the battery 1 is adjusted to a required size through the power conversion circuit 5 and supplied to the motor 2. It has become. The power conversion circuit 5 is controlled through a motor controller 6.
The motor controller 6 calculates an instruction output to be generated by the motor 2 based on an operation through the accelerator pedal (operation means) 7 when an accelerator pedal 7 as an operation means is depressed, and from the battery 1 based on the instruction output. The supply of electric power (travel energy) to the motor 2 is controlled. That is, the output of the motor 2 is controlled through the power conversion circuit 5 in accordance with the depression amount of the accelerator pedal 7. On the other hand, when the accelerator pedal 7 is not depressed, the regeneration amount of the motor 2 is controlled through the power conversion circuit 5 according to the depression amount of the brake pedal 8.
[0016]
The battery 1 is provided with a remaining capacity detection means (remaining energy amount detection means) 21 for detecting a ratio (charging rate) of the power capacity remaining in the battery 1 to the full charge amount. This remaining capacity detection means 21 is a well-known device configured to calculate based on the charge / discharge history of the battery from the fully charged state.
The travelable distance display device of the present vehicle is provided in such an electric vehicle, and as shown in FIG. 1, a travelable distance display control unit 11 that estimates the travelable distance and controls the display of the travelable distance, A display unit 12 that displays a travelable distance based on an instruction from the travelable distance display control unit 11 is provided.
[0017]
The travelable distance display control unit 11 includes a function (storage means) 13 for storing various data, a function (determination means) 14 for performing a required determination, a function (calculation means) 15 for performing a required calculation, and an estimated travel A function (instruction means) 16 for sending an instruction signal to the display section 12 based on the possible distance is provided, and the travelable distance display control section 11 includes a vehicle state detection means 20, that is, a travel distance detection means 22, Respective detection signals from the remaining capacity detection means (remaining energy amount detection means) 21, the motor instruction output detection means 23, and the motor actual output detection means 24 are inputted.
[0018]
The travel distance detection means 22 is a known one that calculates the travel distance of the vehicle while accumulating the rotational speed of the output shaft of the transmission, and the motor instruction output detection means 23 is an accelerator pedal (operation means) by the motor controller 6. ) It can be detected from the instruction output of the motor calculated based on the operation through 7, or can be detected based on the operation amount situation of the accelerator pedal (operation means) 7. Further, the actual motor output detection means 24 detects based on the supply current to the motor 2 adjusted through the power conversion circuit 5 from the relationship between the current supplied to the motor 2 and the actual motor output as shown in FIG. can do.
[0019]
The storage means 13 in the travelable distance display control unit 11 is provided with a first storage means 13A and a second storage means 13B.
In the first storage means 13A, the travel distance detection value (travel distance data) detected by the travel distance detection means 22 and the remaining energy amount detection value (battery remaining capacity data) detected by the remaining capacity detection means 21 are stored. Are taken in every required period and stored in a state corresponding to each other (as a set). The sampling data stored in the first storage means 13A is stored so as to be accumulated every required period, and when the required number (the limit number n of memory data) is stored, the oldest data is deleted thereafter. The data is updated while subscribing to the latest data. Hereinafter, a plurality (n) of sampling data stored in the first storage means 13A will be denoted as D1, D2, D3,..., Dn.
[0020]
The second storage means 13B has a motor actual output detection value (motor output data) detected by the motor actual output detection means 24 and a residual energy amount detection value (battery remaining capacity data) detected by the remaining capacity detection means 21. Are also taken in every required cycle and stored in a state corresponding to each other (as a set). However, here, based on the respective detection signals from the motor instruction output detection means 23 and the motor actual output detection means 24, the value of the ratio between the actual output of the motor 2 and the instruction output (actual output / instruction output) is set in advance. Compared with the determined determination value d (d <1), the sampling data is stored only when the actual output / instruction output value is equal to or smaller than the determination value d. Further, the sampling data stored in the second storage means 13B is also stored so as to be accumulated every required period, and when the required number of data (the limit number n of memory data) is stored, the oldest data is thereafter stored. The data is updated while subscribing to the latest data. Note that a plurality (n) of sampling data stored in the second storage means 13B are expressed as DD1, DD2, DD3,..., DDn.
[0021]
The determination means 14 determines the determination for setting the sampling period and the start of calculation based on the sampling data. That is, in the present embodiment, immediately after the ignition key (IG key) is turned on (elapsed time after the IG key is turned on ≦ a, where a is a preset time), the cycle of storing the above sampling data ( (Sampling time) is set short so that the calculation and display described later can be performed immediately after the IG key is turned on, and when the ignition key (IG key) is turned on, a sufficient amount of time has passed (IG Elapsed time after key-on> a), the sampling time is set longer to suppress the calculation frequency and increase the calculation accuracy. Further, the calculation start determination is made based on whether or not the sampling data has reached a required amount.
[0022]
The calculation means 15 includes a travelable distance calculation means 15A for calculating the travelable distance of the vehicle, and an effective remaining energy amount calculation means 15B for calculating the effective remaining capacity (effective residual energy amount) of the battery used for the travelable distance calculation. Is provided.
The travelable distance calculation means 15A calculates the travelable distance of the vehicle based on a plurality of sets of stored data (sampling data) stored in the first storage means 13A. For this calculation, a linear expression of the least square method is used. An approximation is used.
[0023]
That is, as shown in FIG. 3, a straight line A is shown by linear approximation of the least square method based on a plurality of sets of sampling data D1, D2, D3,..., Dn stored in the first storage means 13A. Such battery consumption characteristics can be estimated. In the case of an electric vehicle, the travelable distance ΔL until the remaining capacity of the battery 1 decreases to a level that causes a reduction in the output of the motor 2 (this is the effective remaining capacity of the battery (effective remaining energy amount)) b. It can be obtained from the characteristic indicated by A. The travelable distance calculation means 15A calculates the travelable distance ΔL in this way. For the travelable distance ΔL, a quadratic approximation of the least square method is also conceivable.
[0024]
Incidentally, the effective remaining capacity (effective remaining energy amount) b of the battery is calculated by the effective remaining energy amount calculating means 15B. This calculation will be described. In the effective residual energy amount calculation means 15B, when the value of the ratio between the actual output of the motor 2 and the instruction output (actual output / instruction output) becomes less than a preset determination value d (d <1) (that is, the motor When output is insufficientof)Based on sampling data DD1, DD2, DD3,..., DDn4As shown, the motor output reduction characteristic as shown by the curve B can be estimated by the quadratic approximation of the least square method. Then, an effective remaining capacity (effective remaining energy amount) b of the battery corresponding to a preset lower limit value of the motor output (a level that hinders running due to insufficient motor output) e can be calculated. The effective remaining energy amount calculating means 15B calculates the effective remaining capacity (effective remaining energy amount) b of the battery in this way.
[0025]
The vehicle travelable distance display device according to the first embodiment of the present invention is configured as described above.5As shown, the travelable distance ΔL is calculated and displayed.
That is, the figure5First, it is determined whether or not the required time has elapsed since the ignition key (IG key) was turned on (whether or not the elapsed time after turning on the IG key ≦ a) (step A10). The sample time is set short until the required time a elapses after the power is turned on (step A30), and after the required time a elapses after the ignition key is turned on, the sample time is increased. Set (step A20).
[0026]
Based on the sampling time set in this way, it is determined whether or not the elapsed time has reached the sampling time (step A40), and the elapsed time has reached the sampling time.TheSampling time periodso,Sampling data, that is, data Dk consisting of a detected distance (travel distance data) detected by the distance detector 22 and a residual energy detection value (battery remaining capacity data) detected by the remaining capacity detector 21. I will take in. Then, after the number of data is stored up to the limit number n of the memory data, the sampling data is updated (step A50).
[0027]
Then, after determining whether or not the number of sampling data has reached the number that can be approximated by the first-order equation of the least squares method (step A60), if the number of sampling data is sufficiently obtained, a plurality of sets of sampling data D1, Based on D2, D3,..., The consumption characteristics of the battery as shown by the straight line A (see FIG. 3) are estimated by a first-order approximation of the least square method, and the remaining capacity of the battery is determined as the effective remaining capacity (effective remaining capacity). The travelable distance ΔL until the energy amount is reduced to b is calculated (step A70). Then, the elapsed time is reset to 0 (step A80), and the calculated travelable distance ΔL is displayed on the display unit 12 (step A90).
[0028]
The above-described effective remaining capacity (effective remaining energy amount) b can be set as shown in FIG. 6, for example. That is, first, it is determined whether or not the first calculation of the effective remaining capacity b has been performed (step B10). If the first calculation of the effective remaining capacity b has been performed, this calculated value is used to If there is, the effective remaining capacity b immediately before the previous ignition key is turned off is used (step B20).
[0029]
And1If the second calculation has been performed, it is determined whether or not the elapsed time has reached the sampling set time c (step B30). If the elapsed time has reached the sampling set time c, the actual output and instruction output of the motor 2 are output. It is determined whether or not the ratio value (actual output / instruction output) is less than a predetermined determination value d (d <1) (step B40).
[0030]
Here, when (actual output / instruction output) becomes less than the determination value d, sampling data, that is, the motor actual output detection value (motor output data) detected by the motor actual output detection means 24 and the remaining capacity are detected. The data DDk consisting of the remaining energy amount detection value (battery remaining capacity data) detected by the detection means 21 is taken in, and after the number of data is stored up to the limit number n of the memory data, the sampling data is updated. (Step B50).
[0031]
Then, as shown in FIG. 4, the motor output reduction characteristic as shown by the curve B is estimated by quadratic approximation of the least square method, and the effective remaining of the battery corresponding to the preset lower limit e of the motor output is estimated. The capacity (effective residual energy amount) b is calculated (step B60). Further, the elapsed time is reset to 0 (step 760), and the current calculation is finished.
[0032]
The effective remaining capacity (effective residual energy amount) b obtained in this way is used for the calculation of the travelable distance ΔL.
In this way, by performing the estimation calculation of the travelable distance ΔL using the least squares method, an extremely accurate travelable distance ΔL without variation can be obtained, and for example, the traffic situation changes. Even if the driving state changes suddenly, the display of the travelable distance does not change suddenly in a short time, and the driver can grasp the state of the remaining fuel without anxiety. (Capacity) can be managed more easily by the driver.
[0033]
Further, the effective remaining capacity (effective remaining energy amount) b used for the estimation calculation of the travelable distance ΔL can be estimated more appropriately by using the least square method.
Furthermore, in the case of a series hybrid electric vehicle equipped with a generator, power generation is generally performed with a constant charging efficiency, so that it depends on the energy provided for the prime mover driving the generator (ie, the amount of remaining fuel). Thus, since the remaining capacity of the battery is considered to increase, the increase amount of the remaining capacity of the battery with respect to the remaining fuel amount can be estimated. Therefore, if the amount of remaining fuel is detected, the amount of increase in the remaining capacity of the battery can be obtained according to this detected value, and the amount of increase thus obtained is added to the above-mentioned remaining capacity of the battery, and this added value is obtained. Based on this, it is conceivable to calculate the travelable distance ΔL.
[0034]
Next, a second embodiment of the present invention will be described. FIGS. 7 and 8 show a travelable distance display device for a vehicle as a second embodiment of the present invention. FIG. These are figures explaining the calculation of the travelable distance.
The vehicle travelable distance display device of the present embodiment is an internal combustion engine.(engine)As shown in FIG. 7, the travelable distance display control unit 11 that estimates the travelable distance and controls the display of the travelable distance, as shown in FIG. A display unit 12 that displays a travelable distance based on an instruction from the distance display control unit 11 is provided.
[0035]
The travelable distance display control unit 11 includes a function (storage means) 13 for storing various data, a function (determination means) 14 for performing a required determination, a function (calculation means) 15 for performing a required calculation, and an estimated travel A function (instruction means) 16 for sending an instruction signal to the display section 12 based on the possible distance is provided, and the travelable distance display control section 11 includes a vehicle state detection means 20, that is, a travel distance detection means 22, Each detection signal from the residual fuel amount detection means (residual energy amount detection means) 25 is input. The storage unit 13, the determination unit 14, the calculation unit 15, and the instruction unit 16 have some or all of the same functions as those in the first embodiment.
[0036]
Further, in this embodiment, since the vehicle is an internal combustion engine type vehicle, fuel is stored in a fuel tank (not shown) as energy storage means for traveling energy. Since the vehicle can travel until the fuel amount becomes 0 or substantially 0, the travel distance when the remaining fuel amount becomes 0 or substantially 0 is set as the travelable distance ΔL as shown in FIG.
[0037]
Since the vehicle travelable distance display device according to the second embodiment of the present invention is configured as described above, for example, as shown in FIG. 4 relating to the first embodiment, the travelable distance ΔL is calculated and displayed. Is done.
That is, as shown in FIG. 4, first, it is determined whether or not the required time has elapsed since the ignition key (IG key) was turned on (whether or not the elapsed time after turning on the IG key ≦ a) (step A10). ) After the ignition key is turned on until the required time a elapses, the sampling time is set short (step A30), and after the required time a elapses after the ignition key is turned on, the sump time is set. A long link time is set (step A20).
[0038]
Based on the sampling time set in this way, it is determined whether or not the elapsed time has reached the sampling time (step A40). When the elapsed time reaches the sampling time (that is, at the sampling time period), the sampling is performed. Data, that is, data Dk consisting of the detected distance (travel distance data) detected by the distance detector 22 and the remaining energy detection value (remaining fuel amount data) detected by the remaining capacity detector 21 Go. Then, after the number of data is stored up to the limit number n of the memory data, the sampling data is updated (step A50).
[0039]
Then, after determining whether or not the number of sampling data has reached the number that can be approximated by the first-order equation of the least squares method (step A60), if the number of sampling data is sufficiently obtained, a plurality of sets of sampling data D1, Based on D2, D3,..., A fuel consumption characteristic as shown by a straight line A (see FIG. 8) is estimated by a first-order approximation of the least square method, and the remaining fuel amount is reduced to 0 or substantially 0. Is calculated (step A70). Then, the elapsed time is reset to 0 (step A80), and the calculated travelable distance ΔL is displayed on the display unit 12 (step A90).
[0040]
In this way, by performing the estimation calculation of the travelable distance ΔL using the least square method, an extremely accurate travelable distance ΔL with no variation can be obtained even in an internal combustion engine type automobile. Even if the driving condition changes suddenly due to traffic conditions, the display of the distance that can be traveled does not change suddenly in a short time, and the driver can grasp the state of the remaining fuel without worrying about the driving energy (remaining battery power). (Capacity) can be managed more easily by the driver.
[0041]
【The invention's effect】
As described above in detail, according to the travelable distance display device for a vehicle according to the first aspect of the present invention, the energy storage means mounted on the vehicle for storing the travel energy and the vehicle for traveling the vehicle A drive output generating means for driving the driving wheels of the vehicle while using the traveling energy, and an instruction output to be generated by the drive output generating means based on an operation through the operation means, and based on the instruction output, A controller for controlling the supply of the traveling energy from the energy storage means to the drive output generation means; and at leastActual output detecting means for detecting the actual output generated by the drive output generating means;Vehicle state detection means having travel distance detection means for detecting the travel distance of the vehicle, and residual energy amount detection means for detecting the remaining amount of travel energy stored in the energy storage means; and the travel distance First storage means for storing a plurality of sets of data consisting of a detected travel distance value and a detected remaining energy amount detected simultaneously by the detection means and the remaining energy amount detection means;A second storage means for storing a plurality of sets of data consisting of an actual output detection value and a residual energy amount detection value detected simultaneously or substantially simultaneously by the actual output detection means and the residual energy amount detection means; and the second storage Effective remaining energy amount calculating means for estimating the remaining energy amount by which the actual output generated by the drive output generating means is less than or equal to a preset lower limit value based on the stored data stored in the means, and the effective remaining amount By the time the remaining energy amount calculated by the energy amount calculating means reaches the first set value,Based on the plurality of sets of data stored in the first storage means, the travelable distance calculating means for calculating the travelable distance of the vehicle using the least square method, and the travelable distance calculating means By providing the display means for displaying the travelable distance, the travelable distance can be estimated more accurately and without variation.Further, an effective travelable distance can be calculated, and a more practical travelable distance can be displayed.
[0042]
According to the vehicle travelable distance display device of the present invention as set forth in claim 2, in the device according to claim 1, the first storage means includesMultiple sets of dataAt regular intervalsRecorded inThe configuration of remembering makes it possible to collect appropriate data and contribute to improving the estimation accuracy of the travelable distance.
According to a travelable distance display device for a vehicle according to a third aspect of the present invention, in the device according to the first aspect, the travelable distance calculating means determines that the remaining energy amount reaches the first set value. With the configuration of calculating the travelable distance of the vehicle, a more effective travelable distance can be calculated according to the setting of the first set value, and a more practical travelable distance can be displayed.
[0043]
ContractClaim4According to the vehicle travelable distance display device of the present invention described in claim1In the described apparatus,The second storage meansWhen the ratio of the actual output to the instruction output is equal to or less than the second set value, the actual output detection value corresponding to each other and the remaining detected by the actual output detection means and the residual energy amount detection means simultaneously or substantially simultaneously Store multiple sets of energy detection valuesRukoThus, an effective travelable distance can be calculated, and a more practical travelable distance can be displayed.
[0044]
Claim5According to the vehicle travelable distance display device of the present invention described in claimAny one of 1-4In the described apparatus, the second storage means periodically stores a plurality of sets of the actual output detection value and the residual energy amount detection value corresponding to each other at predetermined time intervals, and the effective residual energy amount calculation means includes: With the configuration of calculating the remaining energy amount using the least square method, the effective remaining energy amount can be calculated with high accuracy.
[0045]
Claim6According to the vehicle travelable distance display device of the present invention, in the device according to any one of claims 1 to 5, the energy storage means is a battery, and the drive output generation means is an electric motor. According to the configuration, it is possible to accurately display the travelable distance in the electric vehicle, and the driver can easily manage the charging of the battery.
[Brief description of the drawings]
FIG. 1 is a configuration diagram illustrating a travelable distance display device for a vehicle according to a first embodiment of the present invention.
FIG. 2 is a diagram illustrating a motor instruction output of the vehicle travelable distance display device according to the first embodiment of the present invention.
FIG. 3 is a diagram illustrating calculation of a travelable distance of the travelable distance display device for a vehicle as the first embodiment of the present invention.
FIG. 4 is a diagram for explaining calculation of an effective remaining capacity related to a travelable distance of the travelable distance display device for a vehicle according to the first embodiment of the present invention.
FIG. 5 is a flowchart for explaining calculation of a travelable distance of the travelable distance display device for a vehicle according to the first embodiment of the present invention.
FIG. 6 is a flowchart for explaining calculation of an effective remaining capacity related to a travelable distance of the travelable distance display device for a vehicle according to the first embodiment of the present invention.
FIG. 7 is a configuration diagram showing a travelable distance display device for a vehicle according to a second embodiment of the present invention.
FIG. 8 is a diagram for explaining calculation of a travelable distance of a travelable distance display device for a vehicle according to a second embodiment of the present invention.
[Explanation of symbols]
1 In-vehicle battery as energy storage means
2 Electric motor (driving motor) as drive output generating means
3 Transmission
4 Drive wheels
5 Power conversion circuit
6 Motor controller
7 Accelerator pedal
8 Brake pedal
11 Travel distance display controller
12 Display section
13 Storage means
14 judgment means
15 Calculation means
16 Instruction means
20 Vehicle state detection means
21 Remaining capacity detection means (remaining energy amount detection means)
22 Travel distance detection means
23 Motor instruction output detection means
24 Motor actual output detection means
25 Remaining fuel amount detection means (residual energy amount detection means)

Claims (6)

Energy storage means mounted on the vehicle for storing travel energy;
Drive output generating means for driving the driving wheels of the vehicle while using the traveling energy to drive the vehicle;
A controller that calculates an instruction output to be generated by the drive output generation means based on an operation through the operation means, and controls supply of the traveling energy from the energy storage means to the drive output generation means based on the instruction output When,
At least an actual output detecting means for detecting an actual output generated by the drive output generating means, a travel distance detecting means for detecting a travel distance of the vehicle, and the remaining of the traveling energy stored in the energy storage means Vehicle state detection means having residual energy amount detection means for detecting the amount;
First storage means for storing a plurality of sets of data consisting of a detected travel distance value and a detected remaining energy amount detected simultaneously or substantially simultaneously by the travel distance detection means and the remaining energy amount detection means;
Second storage means for storing a plurality of sets of data comprising actual output detection values and residual energy amount detection values detected simultaneously or substantially simultaneously by the actual output detection means and the residual energy amount detection means;
Effective residual energy amount calculating means for estimating by calculation the remaining energy amount at which the actual output generated by the drive output generating means is less than or equal to a preset lower limit value based on the stored data stored in the second storage means; ,
The travelable distance of the vehicle is determined based on the plurality of sets of data stored in the first storage unit until the remaining energy amount calculated by the effective remaining energy amount calculation unit reaches the first set value . Travelable distance calculation means for calculating using the least square method,
A travelable distance display device for a vehicle, comprising display means for displaying the travelable distance calculated by the travelable distance calculating means. The travelable distance display device for a vehicle according to claim 1, wherein the first storage means periodically stores the plurality of sets of data at predetermined time intervals. 3. The travelable distance display device for a vehicle according to claim 2, wherein the first storage means performs the storage in a shorter cycle when the device is started. The second storage means corresponds to each other detected at the same time or substantially simultaneously by the actual output detection means and the remaining energy amount detection means when the ratio of the actual output to the instruction output is equal to or less than a second set value. plural sets stored actual output detection value and the remaining energy amount detection value
Characterized the this, travelable distance display apparatus for a vehicle according to claim 1. The second storage means periodically stores a plurality of sets of the actual output detection value and the residual energy amount detection value corresponding to each other at predetermined time intervals,
The effective residual energy amount calculating means, characterized by calculating the residual energy amount using the least squares method, the travelable distance display apparatus for a vehicle according to claim 1. The energy storage means is a battery;
Characterized in that the drive output generating means is a motor, the travel distance display apparatus for a vehicle according to any one of claims 1-5.

Images