JP2012148615A - Fuel consumption management system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fuel consumption management system with which the occurrence of human error is prevented and power saving is achieved.SOLUTION: The fuel consumption management system 1 is provided with: a data transmission unit 20 loaded in an automobile; a data reception unit 40 carrying out wireless communication with the data transmission unit 20; and an arithmetic unit 60 computing the fuel consumption based on data which the data reception unit 40 receives from the data transmission unit 20. The data transmission unit 20 has: a timer 32 obtaining time; and a wireless transmission reception portion 28 acquiring the total mileage data and fuel residual quantity data of the automobile, to transmit them to the data reception unit 40. When the timer 32 reaches a fixed time, the wireless transmission reception portion 28 is controlled to transmit data respectively to the data reception unit 40, and the arithmetic unit 60 computes the fuel consumption per day by respectively comparing data transmitted from the data transmission unit 20 at the fixed time of the day to data transmitted from the data transmission unit 20 at the fixed time of the day before, and the resultant data is accumulated and stored in a mass storage 64.

Description

  The present invention relates to a fuel consumption management system for managing the fuel consumption of an automobile.

  Conventionally, when the user calculates the actual fuel consumption, after confirming the mileage displayed on the odometer after hand using the vehicle, it is recorded by handwriting. Check. Then, when refueling is necessary, the amount of refueling is obtained when going to the refueling station, and the fuel consumption is calculated manually or by the computer from the distance traveled from the previous refueling to the current refueling.

  Conventionally, techniques described in Patent Document 1 and Patent Document 2 have been proposed as fuel efficiency management systems. In Patent Document 1, a service person in a fueling facility inputs input data from the terminal device to the central management device by inputting the user ID, the amount of fueling, and the travel distance heard from the user to the terminal device. . The central management device creates various types of fuel consumption related information based on the input data, and the fuel consumption related information is transmitted from the central management device to the terminal device. A system is disclosed in which a terminal device prints fuel efficiency related information on a fuel efficiency management sheet, and a serviceman passes the fuel efficiency management sheet to a user.

  Patent Document 2 discloses a system in which an in-vehicle simple digital operation recorder has a wireless LAN communication function, and operation data recorded by the simple digital operation recorder is transmitted to a management terminal by wireless LAN. Has been.

JP 2002-167000 A JP 2007-102628 A

  However, in the system of Patent Document 1, a service man manually inputs the travel distance and the amount of fuel supply, and in the system of Patent Document 2, the vehicle crew or the management system operator manually inputs the fuel usage. For this reason, a human error may occur.

  In particular, in the system of Patent Document 2, the management terminal side needs to always activate the wireless LAN communication function. On the vehicle side, for example, if the vehicle-mounted device is not turned off while taking a rest in the parking area, the wireless LAN communication function is activated, and the communication partner is continuously searched. For this reason, in the worst case, the battery may run out. Further, even if only the wireless LAN communication function can be turned on / off by the driver, the battery may be wasted unless the wireless LAN communication function is turned off after the operation data is transmitted.

  It is an object of the present invention to solve such problems, and to provide a fuel consumption management system capable of preventing human error and collecting data without manpower.

  In order to achieve the above object, the present invention has the following configuration.

  (1) A data transmission device mounted in an automobile, a data reception device that performs wireless communication with the data transmission device, and an operation in which the data reception device calculates fuel consumption based on data transmitted from the data transmission device The data transmission device includes a timer unit for obtaining time, a data acquisition unit for acquiring total mileage data and fuel remaining amount data of the vehicle, and the data acquisition unit When the communication unit that transmits the total travel distance data and the remaining fuel amount data to the data receiving device and the timer unit arrive on time, the total travel distance data and the remaining fuel amount data are transmitted to the communication unit. A transmission control unit that performs control to be transmitted to the reception device, and the calculation device includes the total travel distance data and fuel transmitted from the data transmission device at a fixed time of the day. A calculation unit that compares the remaining amount data with the total mileage data and fuel remaining amount data transmitted from the data transmission device at the scheduled time on the previous day, and calculates the fuel consumption of the day, and the day calculated by the calculation unit A fuel consumption management system comprising: a cumulative storage unit that cumulatively stores the fuel consumption of the vehicle in association with date data.

  According to (1), the data transmission device automatically acquires the total mileage data and fuel remaining amount data of the vehicle at the scheduled time, activates the communication unit, and starts the total mileage data and fuel remaining amount. The quantity data is transmitted to the data receiving device. For this reason, the arithmetic unit can automatically acquire the total travel distance data and the remaining fuel amount data and calculate the daily fuel consumption without manpower. In addition, by setting both the data transmission device and the data reception device in the activated state at regular times, it becomes possible to transmit the total travel distance data and the remaining fuel amount data to the arithmetic device. As a result, it is possible to shorten the time for starting up the data transmission device at times other than the regular time, and accordingly, it is possible to save power on the vehicle side. In addition, by calculating fuel consumption every day and accumulating data, it becomes possible to analyze, for example, what kind of driving the fuel consumption was good or bad, and fuel consumption trends in automobiles Can know.

  (2) In (1), the calculation unit calculates the total travel distance data and the remaining fuel amount data transmitted from the data transmission device at a fixed time on the day, and the total travel data transmitted from the data transmission device at a fixed time on the previous day. The distance data and the remaining fuel amount data are compared to calculate the daily travel distance and fuel consumption in addition to the daily fuel consumption, and the cumulative storage unit calculates the daily travel distance calculated by the calculation unit. A fuel consumption management system characterized by accumulating and storing daily fuel consumption and daily fuel consumption in association with date data.

  According to (2), in addition to the daily fuel consumption, the daily travel distance and daily fuel consumption can be obtained by calculation and accumulated.

  (3) In (1) or (2), the data receiving device performs wireless communication with a plurality of the data transmitting devices, and a wireless connection is established with the data transmitting device. After receiving the data and the fuel remaining amount data, the wireless communication unit has a reception control unit that disconnects the wireless connection, and the plurality of data transmitting devices transmit the data together with the total travel distance data and the fuel remaining amount data at a common time. Identification data for identifying a vehicle equipped with a device is transmitted to the data receiving device, and the computing device calculates fuel consumption per day for each vehicle based on the identification data, and the cumulative storage unit stores the daily data for each vehicle. Fuel consumption management system characterized by memorizing the fuel consumption.

  According to (3), the data reception device receives the total travel distance data, the remaining fuel amount data, and the identification data from the data transmission device with which the wireless connection has been established at a fixed time, and then disconnects the wireless connection, By repeatedly receiving the total mileage data, the remaining fuel amount data and the identification data from the data transmission device with which the connection has been established, the total mileage data, the remaining fuel amount data and the identification data are obtained from the plurality of data transmission devices. Obtain it and send it to the arithmetic unit. The calculation device calculates the daily fuel consumption for each vehicle based on the identification data, and cumulatively stores the daily fuel consumption for each vehicle in the cumulative storage unit. Thereby, it becomes possible to manage the fuel consumption of a plurality of automobiles simultaneously. As a result, for example, when handling a plurality of automobiles like a shipping company, it becomes possible to preferentially distribute automobiles with good fuel efficiency.

  (4) In (1) to (3), after performing transmission / reception between the data transmission device and the data reception device, the data reception device transmits data from the data transmission device to the arithmetic device. A fuel efficiency management system, wherein current time data is transmitted to the data transmitting device, and the data transmitting device updates a current time of the timer unit based on current time data from the data receiving device.

  According to (4), it is possible to reliably start the data receiving device and the arithmetic device in advance immediately before the timer unit of the data transmitting device reaches a fixed time. Wireless connection and data transmission between the apparatus and the data receiving apparatus can be performed smoothly.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the fuel consumption management system which prevents generation | occurrence | production of a human error and can collect data, without manipulating.

It is a block diagram which shows the outline | summary of the fuel consumption management system in 1st Embodiment of this invention. It is a block diagram which shows the control system of the fuel consumption management system in 1st Embodiment of this invention. It is a flowchart which shows the data transmission process performed in 1st Embodiment of this invention. It is a flowchart which shows the data reception process performed in 1st Embodiment of this invention. It is a flowchart which shows the fuel consumption calculation process performed in 1st Embodiment of this invention. It is a flowchart which shows the data reception process performed in 2nd Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[First Embodiment]
FIG. 1 is a block diagram showing an outline of a fuel consumption management system in the first embodiment of the present invention. The fuel consumption management system 1 includes a data transmission device 20 installed in the automobile 100, a data reception device 40 installed in the parking lot 110, and an arithmetic device 60 installed indoors.

  The data transmission device 20 acquires total mileage data from the odometer 12 mounted on the automobile 100, acquires current fuel remaining amount data from the fuel meter 10 mounted on the vehicle 100, and stores remaining fuel data. The total travel distance data is transmitted to the data receiving device 40. Here, the fuel meter 10 acquires the value of the position of the float floating in the fuel tank as remaining fuel data.

  The data receiving device 40 transmits the remaining fuel amount data and the total travel distance data received from the data transmitting device 20 to the arithmetic device 60.

  The computing device 60 calculates the daily fuel consumption, the daily travel distance, and the daily fuel consumption based on the remaining fuel amount data and the total travel distance data received from the data receiving device 40, and together with the date data. Cumulative storage is performed on a daily basis.

  FIG. 2 is a block diagram showing a control system of the fuel consumption management system in the first embodiment.

[Configuration of data transmission device]
The data transmission device 20 includes a CPU 22 that controls the entire data transmission device 20, and a RAM 24, a ROM 26, a wireless transmission / reception unit 28 corresponding to a communication unit, an interface 30, and a timer 32 corresponding to a timer unit are connected to the CPU 22. Has been. In addition, the data transmission device 20 includes a built-in battery 34.

  The RAM 24 is used as a work area when the CPU 22 performs various data processing, and is used for temporary storage of the remaining fuel amount data and the total travel distance data.

  The ROM 26 stores various programs for the CPU 22 to perform processing. For example, a program for executing processing for acquiring data from the fuel meter 10 and the odometer 12 and transmitting the data to the data receiving device 40 at a fixed time is stored.

  The wireless transmission / reception unit 28 is wirelessly connected to the data reception device 40 and transmits / receives data between the data transmission device 20 and the data reception device 40.

  The interface 30 is connected to the fuel meter 10 and the odometer 12 mounted on the automobile in order to acquire the total travel distance data from the odometer 12 and the remaining fuel amount data from the fuel meter 10.

  The timer 32 measures the current time.

  The built-in battery 34 serves as a power source for driving the CPU 22 and the timer 32 when the automobile is stopped. Here, the data transmission device 20 is connected to the battery of the automobile, and the built-in battery 34 is charged during the operation of the automobile.

[Data receiver configuration]
The data receiving apparatus 40 includes a CPU 42 that controls the entire data receiving apparatus 40, and a RAM 44, a ROM 46, a wireless transmission / reception unit 48, and an interface 50 are connected to the CPU 42.

  The RAM 44 is used as a work area when the CPU 42 performs various data processing.

  The ROM 46 stores various programs for the CPU 42 to perform processing. For example, based on a command from the arithmetic device 60, a process for preparing data transmission / reception between the data transmission device 20 and the data reception device 40, a total mileage data received from the data transmission device 20, and fuel remaining A program for executing a process of transmitting the quantity data to the arithmetic device 60 is stored.

  The wireless transmission / reception unit 48 is wirelessly connected to the data transmission device 20 and transmits / receives data between the data transmission device 20 and the data reception device 40.

  The interface 50 is connected to the arithmetic device 60 in a wired or wireless manner so as to perform transmission / reception between the data receiving device 40 and the arithmetic device 60. In the present embodiment, the data receiving device 40 and the computing device 60 are connected by a cable, and power is supplied to the data receiving device 40 via the computing device 60.

[Configuration of arithmetic unit]
The arithmetic device 60 includes a CPU 62 that controls the entire arithmetic device 60, and a mass storage device 64, a timer 66, an interface 70, and the like are connected to the CPU 62. As the arithmetic device 60, a so-called personal computer is applicable.

  The mass storage device 64 is a storage device called a hard disk drive. The timer 66 measures the current time. The interface 70 is connected to the interface 50 of the data receiving device 40 by wire or wirelessly. In addition, the liquid crystal display device 80 is connected to the arithmetic device 60 via the interface 70.

  Next, processing executed in the data transmission device 20, the data reception device 40, and the arithmetic device 60 will be described.

[Data transmission processing]
First, data transmission processing executed in the data transmission device 20 will be described with reference to FIGS. In the data transmission device 20, the CPU 22 determines whether or not the time measured value of the timer 32 has arrived at a fixed time, and when it is determined that the time measured value of the timer 32 has reached a fixed time, the data transmission processing shown in FIG. Execute.

  As shown in FIG. 3, first, in step S10, the CPU 22 turns on the power supply from an in-vehicle battery (not shown) to the data transmission device 20, activates the communication function by the wireless transmission / reception unit 28, and the data Processing to wirelessly connect the transmission device 20 and the data reception device 40 is performed. Further, the power supply from the battery (not shown) is also turned on for the fuel meter 10 and the odometer 12. If this process ends, the process moves to a step S12.

  In step S <b> 12, the CPU 22 performs a process of starting a connection establishment time timer that measures the time until the wireless connection between the data transmission device 20 and the data reception device 40 is established. The connection establishment time timer functions as a timer by the CPU 22 performing a process of adding a count value to a predetermined storage area of the RAM 24 at regular intervals. If this process ends, the process moves to a step S14.

  In step S <b> 14, the CPU 22 performs a process of determining whether a wireless connection has been established between the data transmission device 20 and the data reception device 40. If it is determined that the wireless connection has been established, the process proceeds to step S16. If it is not determined that the wireless connection has been established, the process proceeds to step S24.

  In step S <b> 16, the CPU 22 performs a process of acquiring total travel distance data and remaining fuel amount data from the fuel meter 10 and the odometer 12. The acquired total travel distance data and remaining fuel amount data are temporarily stored in the RAM 24. At this time, the CPU 22 converts the voltage value acquired from the fuel meter 10 as fuel remaining amount data into numerical data in liters and temporarily stores it in the RAM 24. If this process ends, the process moves to a step S18. Thus, the CPU 22 corresponds to a data acquisition unit.

  In step S <b> 18, the CPU 22 performs a process of transmitting the total travel distance data and the remaining fuel amount data temporarily stored in the RAM 24 to the data receiving device 40. If this process ends, the process moves to a step S22. Thus, the CPU 22 corresponds to a transmission control unit.

  In step S <b> 20, the CPU 22 performs a process of determining whether or not the current time data has been received from the data receiving device 40. If it is determined that the current time data has been received, the process proceeds to step S22. If it is not determined that the current time data has been received, the process proceeds to step S20.

  In step S <b> 22, the CPU 22 performs a process of updating the time counted by the timer 32 to the current time received from the data receiving device 40. If this process ends, the process moves to a step S26.

  In step S24, the CPU 22 performs a process of determining whether or not the value of the connection establishment time timer has reached a predetermined time or more. If it is determined that the timer value has reached the predetermined time or more, the process proceeds to step S26. If it is not determined that the timer value has reached the predetermined time or more, the process proceeds to step S14.

  In step S26, the CPU 22 turns off the power supply from the battery to the fuel meter 10, the odometer 12, and the wireless transmission / reception unit 28, switches the power of the CPU 22 and the timer 32 from the battery to the built-in battery 34, and the time count value of the timer 32 is fixed. The process of monitoring whether or not has been reached is performed. The connection establishment time timer value is also cleared. When this process ends, the data transmission process ends.

  In this data transmission process, for example, if the regular time is 11:30 pm, the data transmission process is started at 11:30 pm. Here, when the automobile 100 (see FIG. 1) is parked in the parking lot (see FIG. 1) by 11:30 pm, the connection between the data transmission device 20 and the data reception device 40 is established. The total travel distance data and the remaining fuel amount data are transmitted from the data transmission device 20 to the data reception device 40. Thereafter, the current time data is received from the data receiving device 40, the time of the timer 32 is updated, and then the monitoring state is entered. Further, the wireless connection between the data transmission device 20 and the data reception device 40 cannot be established as in the case where the automobile 100 (see FIG. 1) is not parked in the parking lot (see FIG. 1) by 11:30 pm. In this case, the connection establishment time timer is in a monitoring state after a predetermined time (for example, 5 minutes).

[Data reception processing]
Next, data reception processing executed in the data reception device 40 will be described with reference to FIGS.

  As shown in FIG. 4, first, in step S <b> 30, the CPU 42 performs a process of determining whether or not an activation command has been received from the arithmetic device 60. If it is determined that the activation command has been received from the arithmetic device 60, the process proceeds to step S32. If it is not determined that the activation command has been received from the arithmetic device 60, the data reception process ends. Here, the activation command is transmitted from the arithmetic device 60 in order to activate the data receiving device 40 in advance immediately before the scheduled time and prepare to establish a wireless connection with the data transmitting device 20. is there.

  In step S <b> 32, the CPU 42 performs processing for starting the communication function by the wireless transmission / reception unit 48 of the data reception device 40. In a state where the communication function by the wireless transmission / reception unit 48 is activated, a communication partner, that is, the data transmission device 20 is searched for, and the data transmission device 20 and the data reception device 40 are wirelessly connected. If this process ends, the process moves to a step S34.

  In step S <b> 34, the CPU 42 performs a process of starting a start-up time timer that measures the time after starting the data receiving device 40. The start-up time timer functions as a timer by the CPU 42 performing a process of adding a count value to a predetermined storage area of the RAM 24 at regular intervals. If this process ends, the process moves to a step S36.

  In step S <b> 36, the CPU 42 performs a process of determining whether or not a wireless connection is established between the data transmission device 20 and the data reception device 40. If it is determined that the wireless connection has been established, the process proceeds to step S38. If it is not determined that the wireless connection has been established, the process proceeds to step S44.

  In step S <b> 38, the CPU 42 performs processing for receiving the total travel distance data and the remaining fuel amount data transmitted from the data transmission device 20 and temporarily storing them in the RAM 44. If this process ends, the process moves to a step S40.

  In step S <b> 40, the CPU 42 performs a process of transmitting the total travel distance data and the remaining fuel amount data temporarily stored in the RAM 44 to the arithmetic device 60. If this process ends, the process moves to a step S42.

  In step S <b> 42, the CPU 42 performs processing for transmitting the current time data received from the arithmetic device 60 to the data transmission device 20. If this process ends, the process moves to a step S46. Here, the current time data is current time data measured by the timer 66 and transmitted after the arithmetic device 60 receives and temporarily stores the total travel distance data and the remaining fuel amount data.

  In step S44, the CPU 42 performs a process of determining whether or not the value of the start-up time timer has reached a predetermined time. If it is determined that the timer value has reached the predetermined time or more, the process proceeds to step S46, and if it is not determined that the timer value has reached the predetermined time or more, the process proceeds to step S36.

  In step S <b> 46, the CPU 42 performs processing for stopping the communication function by the wireless transmission / reception unit 48 of the data reception device 40. When this process ends, the data reception process ends.

  In this data receiving process, the communication function of the data receiving device 40 is activated when an activation command is received from the arithmetic device 60. Then, the total travel distance data and the remaining fuel amount data transmitted from the data transmission device 20 are transmitted to the arithmetic device 60. After that, the current time data transmitted from the arithmetic device 60 is transmitted to the data transmitting device 20, or the communication function of the data receiving device 40 is stopped after a predetermined time has elapsed since the communication function of the data receiving device 40 is activated. To do.

  For example, the fixed time is 11:30 pm, the calculation device 60 is set so that the start command is transmitted 5 minutes before the fixed time, and the communication function is activated after the data receiving device 40 starts the communication function. When the predetermined time until the stop (the predetermined time in step S44 in FIG. 4) is set to 10 minutes, the time of the timer 66 of the arithmetic device 60 is between 11:25 pm and 11:35 pm. The data receiving device 40 is in a state where wireless connection is possible. Therefore, when the automobile 100 is parked in the parking lot 110 between 11:25 pm and 11:35 pm, the travel distance data and the remaining fuel amount data are transmitted to the computing device 60.

[Fuel consumption calculation processing]
Next, the fuel consumption calculation process executed in the arithmetic device 60 will be described with reference to FIGS.

  First, in step S50 shown in FIG. 5, the CPU 62 determines whether or not the time value of the timer 66 has reached a time before a predetermined time, and the time value of the timer 66 becomes a time before the predetermined time. If it is determined that the time has been reached, the process proceeds to step S52. If it is not determined that the predetermined time has come, the process proceeds to step S54.

  In step S <b> 52, the CPU 62 performs processing for transmitting an activation command to the data receiving device 40. If this process ends, the process moves to a step S54. As described above, the data reception device 40 activates the communication function by receiving the activation command.

  In step S54, the CPU 62 determines whether or not the total travel distance data and the remaining fuel amount data have been received from the data receiving device 40. If it is determined that the data has been received, the process proceeds to step S56. If it is not determined that it has been received, the fuel consumption calculation process is terminated.

  In step S <b> 56, the CPU 62 performs processing for saving the total travel distance data and the remaining fuel amount data from the data receiving device 40 in the large capacity storage device 64. If this process ends, the process moves to a step S58.

  In step S <b> 58, the CPU 62 performs a process of transmitting the current time data measured by the timer 66 to the data receiving device 40. The current time data is sent to the data transmitting device 20 via the data receiving device 40. Therefore, the data transmission device 20 can determine that the total travel distance data and the remaining fuel amount data have been transmitted to the arithmetic device 60 by receiving the current time data. If this process ends, the process moves to a step S60.

  In step S60, the CPU 62 performs fuel consumption calculation. Further, in step S62, the CPU 62 performs processing for storing the calculation result in the mass storage device 64 in association with the date on which the fuel consumption calculation is performed. Specifically, based on the difference between the total mileage data and fuel remaining amount data acquired on time and the total mileage data and remaining fuel data acquired on time the previous day, the daily mileage and daily fuel usage A quantity is required. Further, by calculating the ratio between the daily travel distance and the daily fuel consumption, the daily fuel consumption can be obtained. The date and time in which the mileage calculated per day, the amount of fuel used per day, and the fuel consumption per day were calculated together with the total mileage data and fuel remaining amount data saved earlier. The date is stored in the mass storage device 64 in association with the day. When this process ends, the fuel consumption calculation process ends.

  Next, operation | movement of the fuel consumption management system 1 of this embodiment is demonstrated in detail. In the following description, the regular time is 11:30 pm, the start command transmission time (predetermined time in step S50 in FIG. 5) is 11:25 pm, and the transmission / reception available time of the data receiving device 40 (step in FIG. 4). The predetermined time of S44 is 10 minutes. In addition, the transmission / reception possible time of the data transmission device 20 (predetermined time in step S24 in FIG. 3) is 5 minutes.

  First, when the timer 66 of the arithmetic device 60 measures 11:25 pm, the arithmetic device 60 transmits an activation command to the data receiving device 40 and waits with the communication function of the data receiving device 40 activated. Thereafter, the communication function of the data transmission device 20 is activated when the timer 32 of the data transmission device 20 measures 11:30 pm.

  When the wireless connection between the data transmission device 20 and the data reception device 40 is established, the total travel distance data and the remaining fuel amount data are transmitted from the data transmission device 20 to the arithmetic device 60 via the data reception device 40. The

  When the calculation device 60 receives the total travel distance data and the remaining fuel amount data, the current time data is transmitted from the calculation device 60 to the data transmission device 20 via the data reception device 40. The data transmission device 20 updates the time data of the timer 32 with the current time data transmitted from the arithmetic device 60.

  Further, in the arithmetic device 60, based on the total travel distance data and fuel remaining amount data acquired at regular times and the total travel distance data and fuel remaining amount data acquired at regular times on the previous day, Find the daily fuel consumption and daily fuel consumption. The calculated results are accumulated and stored in the large-capacity storage device 64 as the daily travel distance, the daily fuel consumption, and the daily fuel consumption in association with the date on which the fuel consumption calculation was performed.

  The daily mileage, daily fuel consumption, and daily fuel consumption accumulated and stored in the large-capacity storage device 64 are displayed on the liquid crystal display device 80 as a table or graph by the processing of the arithmetic device 60. The The driver can grasp the daily fuel consumption by looking at the display on the liquid crystal display device 80. Further, by looking at the past history, it is possible to analyze what kind of driving the fuel consumption was good or bad, and it is possible to know the fuel consumption tendency. The data accumulated in the large-capacity storage device 64 includes total travel distance data and remaining fuel amount data. For example, when it is desired to know the remaining fuel amount or the total travel distance, the driver must park the vehicle. Even if he / she does not go to the parking lot, he / she can know by operating the arithmetic device 60 and displaying it on the liquid crystal display device 80.

  On the automobile side, in order to acquire the total travel distance data from the odometer 12 and the remaining fuel data from the fuel meter 10, it is necessary to temporarily start the fuel meter 10 and the odometer 12. At this time, power is taken from the battery of the automobile. In the present embodiment, the time for starting the fuel meter 10 and the odometer 12 is 11 pm in order to obtain the total travel distance data and the remaining fuel amount data. Since it is limited to between 30 minutes and 5 minutes, battery consumption can be suppressed.

  As described above, according to the first embodiment, the data transmission device 20 acquires the total travel distance data and the remaining fuel amount data of the automobile, and activates the wireless transmission / reception unit 28 at regular times to perform the total travel. The distance data and the remaining fuel amount data are transmitted to the arithmetic device 60 via the data receiving device 40. For this reason, the calculation device 60 can automatically obtain the total travel distance data and the remaining fuel amount data and calculate the daily fuel consumption without manpower. As described above, since it is not necessary to manually acquire the total travel distance data and the remaining fuel amount data, it is possible to prevent the occurrence of a human error.

  In addition, the data transmission device 20 is automatically activated at a fixed time, the total travel distance data and the remaining fuel amount data are transmitted to the arithmetic device, and stopped after transmission, thereby making the activation time of the data transmission device 20 longer than necessary. It can be prevented from becoming longer. Accordingly, it is possible to save power on the automobile side.

  Also, by calculating the daily mileage, fuel remaining amount and fuel consumption for each day and accumulating data in the mass storage device 64, for example, what kind of driving did the fuel consumption better Or it becomes possible to analyze whether it was bad and to know the fuel consumption tendency in the automobile.

  The data receiving device 40 transmits the data from the data transmitting device 20 to the arithmetic device 60, and then transmits the current time data transmitted from the arithmetic device 60 to the data transmitting device 20. The data transmitting device 20 Based on the current time data from the receiving device 40, the current time of the timer 32 is updated. As a result, the error between the timer 66 of the arithmetic device 60 and the data transmitter 20 timer 32 is reduced, and the data transmitter 20 and the arithmetic device 60 are activated in advance immediately before the timer unit of the data transmitter 20 reaches a fixed time. After the data transmission device 20 is activated, the wireless connection between the data transmission device 20 and the data reception device 40 and the data transmission can be performed smoothly. In addition, it is possible to prevent the occurrence of a situation in which the data receiving device 40 is not activated when the data transmitting device 20 is activated at a regular time.

[Second Embodiment]
Next, a second embodiment of the present invention will be described.
In the first embodiment described above, the total mileage data and the remaining fuel amount data are acquired from one vehicle, and the fuel consumption calculation per day is performed. On the other hand, in the second embodiment, the total travel distance data and the remaining fuel amount data are obtained from a plurality of automobiles, and the daily travel distance and the remaining fuel amount in each automobile are obtained by one arithmetic device 60. The fuel consumption per day is calculated, and the result of the fuel consumption calculation is stored in the mass storage device 64.

  The configuration of the data transmission device 20, the data reception device 40, and the calculation device 60 in the fuel consumption management system of the second embodiment is the same as that of the data transmission device 20, the data reception device 40, and the calculation in the fuel consumption management system shown in FIG. Since it is the same as the structure of the apparatus 60, detailed description is abbreviate | omitted.

  In the first embodiment and the second embodiment, a data transmission process executed in the data transmission apparatus 20, a data reception process executed in the data reception apparatus 40, and a fuel consumption calculation process executed in the arithmetic apparatus 60 are used. Some are different.

  An identification number is set in advance for each automobile. In the second embodiment, in the data transmission process shown in FIG. Processing for transmitting identification data corresponding to the identification number set in the automobile to the data receiving device 40 is performed. In the data transmission process of the second embodiment, the other processes are the same as the processes in each step shown in FIG.

  FIG. 6 is a flowchart showing data reception processing in the second embodiment. In the data reception process in the second embodiment, when the process in step S42 is completed in the data reception process in the first embodiment shown in FIG. 4, the process moves to step S36 as shown in FIG. . In the data reception process shown in FIG. 6, the same processes as those in each step shown in FIG. 3 are denoted by the same step numbers, and detailed description thereof is omitted.

  That is, a wireless connection is established between the data reception device 40 and the data transmission device 20 of one vehicle among a plurality of vehicles (step S36), and the data reception device 40 transmits from the data transmission device 20 of one vehicle. After transmitting the total travel distance data, the remaining fuel amount data, and the identification data to the arithmetic device 60 (steps S38 and S40), the current time data transmitted from the arithmetic device 60 is transmitted to the data transmitting device 20.

  The data transmitting apparatus 20 that has received the current time data updates the current time data of the timer 32, and then stops the communication function and enters the monitoring state (steps S22 and S26 in FIG. 3). Here, when the data transmission device 20 of one automobile wirelessly connected to the data reception device 40 stops the communication function, the wireless connection with the data reception device 40 is disconnected. A wireless connection is newly established with the data transmission device 20 of one automobile among the other automobiles that have started up. In this way, the data receiving device 40 establishes a wireless connection with the plurality of data transmitting devices 20 one by one, receives the total travel distance data, the remaining fuel amount data, and the identification data from the data transmitting device 20, and calculates To device 60.

  Then, the calculation device 60 performs the fuel consumption calculation in step S60 shown in FIG. 5, and further, in step S62, the calculation result is associated with the date of the fuel consumption calculation and the identification data in the mass storage device 64. Process to save.

  As described above, according to the second embodiment, the daily travel distance, the remaining fuel amount, and the daily fuel consumption can be classified on an individual vehicle basis based on the identification data. Can be managed simultaneously. As a result, for example, when handling a plurality of automobiles like a shipping company, it becomes possible to preferentially distribute automobiles with good fuel efficiency.

  As mentioned above, although embodiment of this invention was described, this invention is not restricted to embodiment mentioned above. For example, according to the above-described embodiment, narrow-range wireless communication is assumed. However, the present invention is not limited thereto, and the data transmission device 20 and the data reception device 40 can be transmitted and received with each other through a mobile phone line or an Internet line. Good. Thereby, even if the automobile is not in the parking lot, it is possible to transmit the total travel distance data and the remaining fuel amount data from the data transmission device 20 to the data reception device 40 at regular times.

  Further, according to the above-described embodiment, the total travel distance data and the remaining fuel amount data acquired from the fuel meter 10 and the odometer 12 are stored in the large-capacity storage device 64 of the arithmetic device 60. The data may be stored in the RAM 44 of the data receiving device 40, and the arithmetic device 60 may appropriately extract the total travel distance data and the remaining fuel amount data from the RAM 44 and perform the fuel consumption calculation. Further, according to the above-described embodiment, the timer 66 is provided in the arithmetic device 60, but the timer 66 may be provided in the data receiving device 40.

DESCRIPTION OF SYMBOLS 1 Fuel consumption management system 10 Fuel meter 12 Odometer 20 Data transmission device 22, 42, 62 CPU
24, 44 RAM
26, 46 ROM
28, 48 Wireless transmission / reception unit 30, 50, 70 Interface 32, 66 Timer 34 Built-in battery 40 Data receiving device 60 Arithmetic device 64 Mass storage device 80 Liquid crystal display device 100 Car 110 Car park

Claims (4)

A data transmission device mounted in an automobile;
A data receiving device that performs wireless communication with the data transmitting device;
A fuel consumption management system comprising a calculation device for calculating the fuel consumption based on data transmitted from the data transmission device by the data receiving device,
The data transmission device includes:
A timer unit for obtaining time;
A data acquisition unit for acquiring the total mileage data and fuel remaining amount data of the vehicle;
A communication unit that transmits the total travel distance data and fuel remaining amount data acquired by the data acquisition unit to the data receiving device;
A transmission control unit that performs control to cause the communication unit to transmit the total travel distance data and the remaining fuel amount data to the data receiving device when the timer unit reaches a fixed time;
The arithmetic unit is:
The total travel distance data and fuel remaining amount data transmitted from the data transmission device at the scheduled time on the day are compared with the total travel distance data and fuel remaining amount data transmitted from the data transmission device at the scheduled time on the previous day. A calculation unit for calculating the fuel consumption of the day,
A fuel consumption management system comprising: a cumulative storage unit that cumulatively stores fuel consumption per day calculated by the calculation unit in association with date data. The calculation unit includes a total travel distance data and fuel remaining amount data transmitted from the data transmission device at a fixed time of the day, and a total travel distance data and fuel remaining amount data transmitted from the data transmission device at a predetermined time on the previous day. In addition to the daily fuel consumption, calculate the daily mileage and daily fuel consumption,
2. The fuel consumption according to claim 1, wherein the cumulative storage unit cumulatively stores the daily travel distance, the daily fuel consumption, and the daily fuel consumption calculated by the calculation unit in association with date data. Management system. The data reception device performs wireless communication with the plurality of data transmission devices, establishes a wireless connection with the data transmission device, and receives total travel distance data and fuel remaining amount data from the data transmission device, and then wirelessly A reception control unit for disconnecting the connection;
The plurality of data transmission devices transmit identification data for identifying a vehicle equipped with the data transmission device to the data reception device together with total mileage data and fuel remaining amount data at a common fixed time,
3. The fuel consumption management according to claim 1, wherein the arithmetic unit calculates a daily fuel consumption for each vehicle based on the identification data, and stores the daily fuel consumption for each vehicle in the cumulative storage unit. system. Sending and receiving between the data transmitting device and the data receiving device,
The data receiving device transmits the current time data to the data transmitting device after transmitting the data from the data transmitting device to the arithmetic device,
The fuel consumption management system according to any one of claims 1 to 3, wherein the data transmission device updates the current time of the timer unit based on current time data from the data reception device.

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