JP5118332B2 - Vehicle fuel consumption display system - Google Patents

Description

  The present invention relates to a vehicle fuel consumption display system that calculates the fuel consumption of a vehicle and displays the calculated fuel consumption on a display unit.

  In general, a vehicle such as an automobile or a motorcycle is provided with a meter unit (display device) including a speed meter that displays the speed of the vehicle at a position that is highly visible to the driver. Usually, such a meter unit is provided with an odometer for displaying the total travel distance, a trip meter for displaying the travel distance and allowing the driver to arbitrarily reset in addition to the speed meter.

  In recent years, with increasing interest in energy saving and environmental conservation, it has been proposed to add a fuel consumption indicator that displays the fuel consumption of a vehicle to this type of meter unit.

  Patent Document 1 describes a fuel consumption display device including a meter unit that can display an average fuel consumption and an instantaneous fuel consumption of an automobile. In this case, a liquid crystal display is used, and a display unit for an odometer and a display unit for switching and displaying a fuel consumption indicator, a trip meter, and the like for displaying average fuel consumption and instantaneous fuel consumption are provided side by side.

Japanese Patent Laid-Open No. 11-20508

  By the way, the instantaneous fuel efficiency indicates the fuel efficiency within a predetermined time, for example, the past several seconds to several tens of seconds, and usually changes from moment to moment according to the running condition of the vehicle. It is desirable that such instantaneous fuel efficiency can be visually recognized and grasped at an appropriate timing by the driver in accordance with the traveling state and the like from the viewpoint of economic traveling and the like.

  However, in the fuel consumption display device described in Patent Document 1, the timing for updating the instantaneous fuel consumption display on the fuel consumption indicator is not considered at all. Therefore, for example, when it is considered that it is a constant update timing for updating the display of the instantaneous fuel consumption every second, considering that the instantaneous fuel consumption varies greatly depending on the vehicle speed, the throttle opening, etc., the constant fuel consumption At the update timing, there is a problem that it is difficult for the driver to confirm the instantaneous fuel consumption at an appropriate timing.

  The present invention has been made in consideration of the above problems, and in the fuel consumption display system provided in the vehicle, the timing for updating the display of the instantaneous fuel consumption on the display unit is set to a timing at which the driver can appropriately visually recognize it. An object of the present invention is to provide a fuel consumption display system for a vehicle.

A vehicle fuel consumption display system (10, 10a) according to the present invention includes a distance information calculation unit that calculates a moving distance of a vehicle, a fuel consumption calculation unit that calculates a fuel consumption amount of the vehicle, and the distance information calculation unit. And an instantaneous fuel consumption calculation unit for calculating the instantaneous fuel consumption of the vehicle based on a calculation result from the fuel consumption calculation unit; a display unit (11) for displaying the instantaneous fuel consumption calculated by the instantaneous fuel consumption calculation unit; A vehicle comprising: a control unit (50, 102) that performs fuel consumption display processing on the display unit (11) based on calculation results from the distance information calculation unit, the fuel consumption calculation unit, and the instantaneous fuel consumption calculation unit. In the fuel consumption display system (10, 10a), the control unit (50, 102) changes the update timing of the display of the instantaneous fuel consumption on the display unit (11) according to a predetermined condition, and the instantaneous fuel consumption The display update timing is changed between an auto mode that is automatically set according to a predetermined condition and a manual mode that is arbitrarily set by an operator. The manual mode includes the first timing and the first mode. And an update timing between the first timing and the second timing in the auto mode. The second timing is shorter than the first timing.

According to the present invention, the update timing of the instantaneous fuel consumption display in the fuel consumption display system can be changed, so that the timing of the instantaneous fuel consumption display can be changed according to the driver's preference and driving situation. It is possible to easily grasp appropriate fuel consumption information.

According to the present invention, by adopting the shortest (fast) update timing and the longest (slow) update timing in the manual mode, the driver can easily recognize that the current update mode is the manual mode. Can be made.

  Hereinafter, preferred embodiments of a fuel consumption display system for a vehicle according to the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a schematic side view of a motorcycle 12 as a vehicle incorporating a vehicle fuel consumption display system 10 (hereinafter also referred to as a fuel consumption display system 10) according to an embodiment of the present invention. In the present embodiment, the present invention will be described by taking an on-road motorcycle 12 as an example. However, the present invention is not limited to this, and other types of vehicles, for example, scooter-type and off-road motorcycles, automobiles, etc. The present invention can also be applied. Furthermore, in the fuel consumption display system of the present invention, the fuel consumption has a broad meaning indicating the energy consumption rate, that is, not only the internal combustion engine vehicle as described above, but also a vehicle that travels while consuming the mounted energy, for example, It can also be suitably used for fuel cell vehicles that consume hydrogen, electric vehicles that consume power, and the like.

  In the motorcycle 12, regarding the mechanisms or components provided symmetrically one by one on the left and right of the vehicle body, "L" is attached to the reference symbol on the left and "R" is attached to the reference symbol on the right. Shall. Further, in order to facilitate understanding, in each drawing, “L” is attached to the arrow indicating the left side of the vehicle body, “R” is assigned to the arrow indicating the right side of the vehicle body, and An arrow indicating the front of the vehicle will be described with “Fr”, an arrow indicating the rear of the vehicle body with “Rr”, and so on.

  As shown in FIG. 1, a motorcycle 12 includes a cradle-type body frame 13 that constitutes a vehicle body, a front wheel 14 that is a steering wheel, a rear wheel 16 that is a driving wheel, a handle 18 that steers the front wheel 14, And a seat 20 on which an occupant is seated. The seat 20 is attached to seat rails 22L, 22R extending from the body frame 13 toward the rear of the vehicle body via a plurality of attachment support portions 24.

  In the front part of the vehicle body, a head pipe 26 that supports the handle 18 so as to be steerable is pivotally supported on the body frame 13 below the handle 18, and front forks 28 </ b> L and 28 </ b> R are pivotally supported on the lower end side of the head pipe 26. Has been. The front forks 28L and 28R rotatably support the front wheel 14. A front fender 30 that covers the front wheel 14 from above is attached to the front forks 28L, 28R. Further, a vehicle speed sensor (vehicle speed detection unit) 31 that detects the vehicle speed of the motorcycle 12 is disposed in the vicinity of the bearing portion of the front fork 28L on the front fork 28L. The vehicle speed sensor 31 is connected to an ECU 50, which will be described later, via an electric wiring (not shown).

  On the other hand, at the rear part of the vehicle body, below the seat 20, a swing arm 34 suspended by a rear cushion 32 is disposed at the rear part of the vehicle body frame 13, and the rear wheel 16 is rotatably supported by the swing arm 34. ing.

  A fuel tank 36 is attached to the upper portion of the vehicle body frame 13 between the handle 18 and the seat 20. In the cradle space of the vehicle body frame 13 below the fuel tank 36, for example, an engine 38 of a four-cycle type is disposed, and in the rear part of the vehicle body via an exhaust pipe 40 connected to the exhaust port of the engine 38. A silencer (muffler) 42 is provided. Further, an air chamber 44 for storing an air cleaner (not shown) is provided below the fuel tank 36 and above the engine 38.

  In the space between the fuel tank 36 and the seat 20 and covered with the cover 46, a battery 48 and an ECU (engine control ECU) 50 are provided side by side. The ECU 50 is a control unit that performs FI (fuel injection) control of the engine 38, control of various electrical components, fuel consumption calculation, display control, and the like.

  On the rear side of the cover 46, a U-shaped frame 52 extending obliquely upward from its rear portion is connected to the seat rails 22L and 22R. Further, a rear fender 54 is provided at the lower portion of the seat 20, and the winkers 56 </ b> L and 56 </ b> R are disposed on the rear fender 54. A taillight 58 is attached to the top of the rear fender 54, and a lattice-like guard cover 60 is attached to the front of the rear fender 54.

  Above the head pipe 26, in front of the handle 18, a meter unit (display device) 62 is disposed via a bracket 61 at a position that is easily visible to the driver, and extends from the front to the side of the meter unit 62. Is covered by a wind screen 66 connected above the upper cowl 64. A headlight 68 is disposed substantially at the center of the upper cowl 64.

  In the fuel consumption display system 10 according to the present embodiment incorporated in the motorcycle 12 basically configured as described above, the fuel consumption display meter (display unit) 11 for displaying the calculated fuel consumption is provided in the meter unit 62. Be placed. Next, the meter unit 62 will be described with reference to FIGS.

  As shown in FIG. 2, the meter unit 62 is supported by a meter panel 70 fixed to the bracket 61. In the case of this embodiment, a speedometer 72 is provided at a substantially central portion of the meter panel 70.

  In the speedometer 72, an odometer 76 that displays the total travel distance of the motorcycle 12 is provided above (in front of) the rotational axis of the pointer 74. A trip meter 80 that displays the travel distance of the motorcycle 12 and can be arbitrarily reset by the driver by a reset button 78 is provided below (rearward) the rotation axis.

  On both sides of the speedometer 72, a fuel meter 84 incorporating a fuel consumption indicator 11 and a fuel gauge 82 constituting the fuel consumption display system 10 is provided on the right side. On the left side of the speedometer 72, an upper beam indicator 86 and a neutral indicator 88 are provided. Further, turn signal indicators 90L and 90R are provided below (behind) the speedometer 72 with the shaft portion of the handle 18 interposed therebetween.

  FIG. 3 is an enlarged view around the fuel meter 84. The fuel meter 84 is constituted by a liquid crystal display 85, for example.

  In such a fuel meter 84, the fuel gauge 82 displays the remaining amount of fuel, and a plurality of lamps are arranged in parallel between the reserve (RES) indicating the remaining amount and the full amount (F). Thus, the driver can easily grasp the remaining fuel amount. Further, a fuel supply mark 92 is provided adjacent to the fuel gauge 82 to prompt the driver to supply fuel.

  The fuel consumption indicator 11 can display two fuel consumption modes of average fuel consumption (AVG) and instantaneous fuel consumption (INST), and these can be switched and displayed by a changeover switch 94 provided in parallel with the fuel meter 84. For example, when the change-over switch 94 is pressed for a short time (for example, within 1 second), the average fuel consumption and the instantaneous fuel consumption are switched and displayed. By pressing, the average fuel consumption or instantaneous fuel consumption being displayed is reset. In the fuel consumption indicator 11, when the fuel consumption mode is set to the average fuel consumption, the average fuel consumption display indicator (AV) 96 is turned on, and when the fuel consumption mode is set to the instantaneous fuel consumption, A fuel consumption indicator (INST) 98 is lit. For this reason, the driver can easily grasp which fuel consumption mode he is in.

  Further, the changeover switch 94 is configured to be capable of rotating by a predetermined angle to the left and right, whereby the scale 100 can be set at the position of “A”, “Mf”, or “Ms”. The “A” indicates an auto mode, which is an auto mode and a manual mode, which are two display modes (update modes) at the update timing of the instantaneous fuel consumption display. The “Mf” and “Ms” indicate two modes depending on the update timing in the manual mode.

  The auto mode is a display mode in which the update timing of the instantaneous fuel consumption display is automatically changed (variable) in consideration of the vehicle speed of the motorcycle 12, the amount of change in the throttle opening, and the like. The manual mode is a display mode in which the update timing of the instantaneous fuel consumption display is arbitrarily set by the driver. In this case, the “Mf (update is fast)”, “Ms (update is slow)”. ”Can be arbitrarily set. Note that such an Aude mode and a manual mode are also displayed in the liquid crystal display 85 using an indicator lamp, such as an average fuel consumption display indicator 96 indicating the fuel consumption mode, and are more easily visible. It may be configured.

  The average fuel consumption is, for example, the average fuel consumption (km / l) over the entire travel distance from the time point once reset to the current time. For example, the entire travel distance (trip distance) set in the trip meter 80 The average fuel consumption (km / l) can also be obtained. On the other hand, the instantaneous fuel consumption indicates the fuel consumption (km / l) within a predetermined time, for example, the past several seconds, that is, is calculated from the fuel consumption corresponding to the travel distance within the predetermined time.

  Accordingly, the average fuel consumption changes relatively moderately except immediately after the start of calculation, while the instantaneous fuel consumption changes from moment to moment according to the traveling state of the motorcycle 12 and the like. That is, such instantaneous fuel efficiency can be effectively used for economic driving and the like if the driver can visually recognize and grasp at an appropriate timing according to the driving situation.

  In the case of this embodiment, the control method concerning the display of the instantaneous fuel consumption on the fuel consumption indicator 11 in the fuel consumption display system 10 configured as described above includes two control methods depending on the setting method of the display update timing. .

  First, a first control method relating to the display of instantaneous fuel consumption on the fuel consumption indicator 11 will be described with reference to the flowchart shown in FIG. The first control method is a control method for setting the display update timing on the fuel consumption indicator 11 in accordance with the vehicle speed of the motorcycle 12 in the auto mode.

  That is, when the first control method is executed in a state where the fuel consumption mode of the fuel consumption indicator 11 is set to the instantaneous fuel consumption by the changeover switch 94 while the motorcycle 12 is running, first, in step S1 in FIG. The instantaneous fuel efficiency of the motorcycle 12 is calculated by the ECU 50.

  This fuel consumption calculation method will be described with reference to FIG. FIG. 5 is a block configuration diagram showing a calculation system of fuel consumption (instantaneous fuel consumption, average fuel consumption) in the motorcycle 12.

  As shown in FIG. 5, a vehicle speed signal from the vehicle speed sensor 31 and a setting signal for the display mode (auto mode, manual mode) are input to the ECU 50. Further, the ECU 50 grasps and controls the injection valve opening information (INJ), and the ECU 50 calculates the injection valve opening time.

  Therefore, the ECU 50 calculates the travel distance (km) at the predetermined time based on the vehicle speed signal from the vehicle speed sensor 31 at the predetermined time, and calculates the fuel consumption (l at the predetermined time from the injection valve opening information at the predetermined time. ) To calculate the instantaneous fuel consumption (km / l). Note that the ECU 50 can also calculate the average fuel consumption in substantially the same manner as in the case of the instantaneous fuel consumption.

  That is, in this case, the ECU 50 in the fuel consumption display system 10, the distance information calculation unit that calculates the moving distance of the vehicle, the fuel consumption calculation unit that calculates the fuel consumption, the distance information calculation unit, and the fuel consumption It has each function as an instantaneous fuel consumption calculation part and an average fuel consumption calculation part which calculate an instantaneous fuel consumption and an average fuel consumption based on the calculation result from a calculation part. Further, the ECU 50 functions as a control unit that performs fuel consumption display processing for the fuel consumption indicator 11 that is a display unit based on the calculation results from the distance information calculation unit, the fuel consumption calculation unit, and the instantaneous fuel consumption calculation unit. Also have. That is, an update timing change unit that changes the update timing of the fuel consumption indicator 11 based on a calculation result from the distance information calculation unit and the like, and a fuel consumption display processing unit that performs a fuel consumption display process based on a signal from the update timing change unit As a function.

  In such a step S1, the instantaneous fuel consumption is calculated every predetermined time, for example, every second, and is appropriately displayed on the fuel consumption indicator 11 based on the control in the subsequent steps S2 to S15.

  Next, in step S2, the ECU 50 determines whether the display mode of the fuel consumption indicator 11 set by the changeover switch 94 is the auto mode or the manual mode. In this case, when the changeover switch 94 is set to the “Mf” or “Ms”, that is, when the display mode is set to the manual mode, step S3 is executed next.

  In step S3, the ECU 50 determines whether the changeover switch 94 is set to the “Mf” side or the “Ms” side.

  If the changeover switch 94 is set to the “Mf” side, step S4 is subsequently executed, and the instantaneous fuel consumption is updated on the fuel consumption indicator 11 every second, for example. Step S15 is executed. On the other hand, when the changeover switch 94 is set to the “Ms” side, step S5 is subsequently executed, and the instantaneous fuel consumption is updated on the fuel consumption indicator 11 every 15 seconds, for example. Step S15 is executed.

  In step S15, the instantaneous fuel consumption display on the fuel consumption indicator 11 is updated based on the update timing set in step S4 or step S5.

  On the other hand, if the changeover switch 94 is set to “A” in step S2, that is, if the display mode is set to the auto mode, step S6 is executed next.

  In step S6, the ECU 50 determines whether the vehicle speed of the motorcycle 12 is lower than a predetermined speed or higher than a predetermined speed.

  Specifically, in step S6, when the vehicle speed of the motorcycle 12 is less than a predetermined speed, for example, less than 5 km / h, step S7 is subsequently executed, and the instantaneous fuel consumption display on the fuel consumption indicator 11 is performed. As a result, the process returns to step S1. Thus, the display is turned off when the vehicle speed of the motorcycle 12 is extremely low, for example, less than 5 km / h, for example, by the vehicle speed sensor 31 constituted by an electromagnetic pickup type or the like. This is because accurate detection is difficult. In other words, when the motorcycle 12 is traveling at an extremely low speed, the accuracy of detection of the vehicle speed is lowered, making it difficult to accurately calculate the fuel consumption. It is preferable that the instantaneous fuel consumption is not displayed on 11.

  The step S7 is not necessarily provided. In this case, for example, when the vehicle speed of the motorcycle 12 in step S6 is less than 5 km / h, the process may return to step S1 as it is. It may be omitted.

  On the other hand, in step S6, when the vehicle speed of the motorcycle 12 is equal to or higher than a predetermined speed, for example, 5 km / h or higher, step S8 is subsequently executed.

  In step S8, substantially in the same manner as in step S6, the ECU 50 determines whether the vehicle speed of the motorcycle 12 is less than a predetermined speed or greater than a predetermined speed.

  First, in step S8, when the vehicle speed of the motorcycle 12 is less than a predetermined speed, for example, less than 20 km / h, step S9 is subsequently executed to update the instantaneous fuel consumption on the fuel consumption indicator 11, for example, Next, step S15 is performed as what is performed every 3 seconds. In step S15, the instantaneous fuel consumption display on the fuel consumption indicator 11 is updated based on the update timing set in step S9. On the other hand, in step S8, when the vehicle speed of the motorcycle 12 is equal to or higher than a predetermined speed, for example, 20 km / h or higher, step S10 is continuously executed, and thereafter each step is executed in the same manner.

  That is, in step S10, when the vehicle speed of the motorcycle 12 is less than a predetermined speed, for example, less than 50 km / h, step S11 is subsequently executed to update the instantaneous fuel consumption on the fuel consumption indicator 11, for example, Next, step S15 is performed as what is performed every 5 seconds. On the other hand, in step S10, when the vehicle speed of the motorcycle 12 is equal to or higher than a predetermined speed, for example, 50 km / h or higher, step S12 is subsequently executed.

  In step S12, when the vehicle speed of the motorcycle 12 is less than a predetermined speed, for example, less than 80 km / h, step S13 is subsequently executed to update the instantaneous fuel consumption on the fuel consumption indicator 11 by, for example, 10 As what is performed every second, next step S15 is executed. On the other hand, in step S12, when the vehicle speed of the motorcycle 12 is equal to or higher than a predetermined speed, for example, 80 km / h or higher, step S14 is subsequently executed. In this step S14, the instantaneous fuel consumption is updated by the fuel consumption indicator 11 every 20 seconds, for example, and then step S15 is executed.

  As described above, in the first control method related to the instantaneous fuel consumption display on the fuel consumption indicator 11 in the fuel consumption display system 10 of the present embodiment, the steps are based on the update timing of the fuel consumption indicator 11 set in each step. After the display of the instantaneous fuel consumption on the fuel consumption indicator 11 is updated in S15, the process returns to step S1. The calculation of the instantaneous fuel consumption in step S1 may be performed immediately after the update timing is set in steps S4, S5, S9, S11, S13, and S14.

  In this case, in the auto mode, in step S6 to step S14, the update timing of the instantaneous fuel consumption display on the fuel consumption indicator 11 is changed according to the vehicle speed of the motorcycle 12, and more specifically, the vehicle speed is changed. The higher the timing, the longer the update timing. As a result, an environment in which the driver can easily recognize the instantaneous fuel consumption according to the traveling state of the motorcycle 12 is provided. Then, by setting the update timing longer as the vehicle speed becomes higher, the driver can appropriately set the line-of-sight movement timing necessary for checking the instantaneous fuel consumption even during high-speed driving or the like. For this reason, the driver can easily check the instantaneous fuel consumption regardless of the traveling state, and can be used effectively for economical traveling or the like. Further, when the vehicle is traveling at a high speed on an expressway or the like, it is often performed at a substantially constant speed, and since the change in instantaneous fuel consumption is small, it is preferable to extend the update timing.

  Further, in this case, the update timing of the instantaneous fuel consumption is about 1.7 times from 3 seconds to 5 seconds when the vehicle speed is 2.5 times from 20 km / l to 50 km / l, and from 50 km / l to 80 km / l. It is set to double from 5 seconds to 10 seconds when 1.6 times to l, that is, when the vehicle speed is doubled, the update timing is also doubled accordingly. Has been. This makes it possible to change the update timing in a symmetric and wide range, which is easy for the driver to grasp and handle.

  Moreover, in the manual mode, the update timing of the instantaneous fuel consumption on the fuel consumption indicator 11 can be set at a timing arbitrarily set by the driver. In this case, the setting of the manual mode by the changeover switch 94 may be set not only in the two steps consisting of “Mf” and “Ms”, but also in three steps or more, or an analog continuous amount. Further, as in step S7 in the auto mode, when the motorcycle 12 is less than a predetermined minimum speed (for example, 5 km / h), the display may be turned off.

  Furthermore, in such a first control method, the instantaneous fuel consumption may be updated on the fuel consumption indicator 11 in step S5 corresponding to the manual mode, for example, every 25 seconds. In this case, the update timing of the instantaneous fuel consumption is set every 1 second or every 25 seconds in the manual mode, and is set every 3 to 20 seconds in the auto mode. Then, the shortest (fast) update timing and the longest (slow) update timing are set to the manual mode, and the update timing between them is set to the auto mode, so that the current display mode (update mode) is set to the manual mode for the driver. The mode can be easily recognized.

  Next, a second control method relating to the display of instantaneous fuel consumption on the fuel consumption display meter 11 in the fuel consumption display system 10 will be described with reference to the flowchart shown in FIG. This second control method is a control method for setting the update timing of the fuel consumption indicator 11 in accordance with the amount of change (rate of change) in the throttle (TH) opening of the motorcycle 12 in the auto mode. The amount of change in the throttle opening is, in a narrow sense, the amount of change (% / s) of the opening in a predetermined time in a throttle valve that adjusts the amount of air or fuel / air mixture into the engine 38. ). In a broad sense, an accelerator change amount, an FI change amount, and the like may be included, and processing based on these may be performed. Moreover, the update timing of the fuel consumption indicator 11 may be set based on the detection amount (change amount) by the negative pressure sensor.

  In this case, as shown in FIG. 5, the ECU 50 grasps and controls the throttle opening (Th) detected by the throttle opening detecting means 101 (see FIG. 1), and the ECU 50 changes the throttle opening. A quantity is calculated.

  That is, when the second control method is executed in a state where the fuel consumption mode of the fuel consumption indicator 11 is set to the instantaneous fuel consumption by the changeover switch 94 while the motorcycle 12 is traveling, first, in step S21 in FIG. The instantaneous fuel efficiency of the motorcycle 12 is calculated by the ECU 50. Note that the fuel consumption calculation method is substantially the same as that in step S1 in the first control method, and thus detailed description thereof is omitted.

  Next, in step S22, the ECU 50 determines whether the display mode of the fuel consumption indicator 11 set by the changeover switch 94 is the auto mode or the manual mode. In this case, if the changeover switch 94 is set to the manual mode, step S23 is executed next. Note that the control in steps S23 to S25 in such a manual mode is substantially the same as that in steps S3 to S5 in the first control method, and detailed description thereof will be omitted.

  On the other hand, if the changeover switch 94 is set to the auto mode in step S22, step S26 is executed next.

  In step S26, the ECU 50 determines whether the amount of change in the throttle opening of the motorcycle 12 (hereinafter also referred to as TH opening change amount) is less than a predetermined change amount or greater than a predetermined change amount.

  Specifically, in step S26, when the TH opening change amount of the motorcycle 12 is less than a predetermined change amount, for example, less than 1% / s, step S27 is subsequently executed. When the amount of change in the TH opening is extremely small, for example, less than 1% / s, it is conceivable that the motorcycle 12 is stopped or traveling constantly.

  Accordingly, in step S27, it is determined whether the vehicle speed of the motorcycle 12 is less than a predetermined speed or greater than a predetermined speed. That is, in step S27, when the vehicle speed of the motorcycle 12 is less than 5 km / h, for example, it is determined that the vehicle is stopped, and then step S28 is executed. Therefore, it returns to step S21 not to display the instantaneous fuel consumption on the fuel consumption display meter 11.

  In addition, you may perform the process (vehicle speed judgment) in the said step S27 in the middle of step S22 and step S26.

  On the other hand, when the vehicle speed of the motorcycle 12 is 5 km / h or higher in step S27, it is determined that the vehicle is traveling at a constant speed, and then step S29 is executed. Therefore, step S37 is executed next, assuming that the instantaneous fuel consumption is updated on the fuel consumption indicator 11 every 20 seconds, for example. In step S37, the instantaneous fuel consumption display on the fuel consumption indicator 11 is updated based on the update timing set in step S29. When it is determined that the vehicle is traveling at a constant speed as described above, the fluctuation range of the instantaneous fuel consumption is usually very small. Therefore, the display is not updated, that is, step S37 is not executed, and the process proceeds to step S1. It can also be controlled to return.

  The steps S27 to S29 are not necessarily provided. In this case, for example, when the amount of change in the TH opening of the motorcycle 12 in step S26 is less than 1% / s, the process returns to step S21 as it is. Alternatively, step S26 itself may be omitted.

  On the other hand, in step S26, if the TH opening change amount of the motorcycle 12 is equal to or greater than a predetermined change amount, for example, 1% / s or more, step S30 is subsequently executed.

  In step S30, as in step S26, the ECU 50 determines whether the TH opening change amount of the motorcycle 12 is less than a predetermined change amount or greater than a predetermined change amount.

  First, in step S30, when the amount of change in the TH opening of the motorcycle 12 is less than a predetermined change amount, for example, less than 2% / s, step S31 is subsequently executed, and the fuel consumption indicator 11 Assuming that the fuel efficiency is updated every 10 seconds, for example, step S37 is executed next. On the other hand, in step S30, if the TH opening change amount of the motorcycle 12 is equal to or greater than a predetermined change amount, for example, 2% / s or more, step S32 is subsequently executed. Executed.

  That is, in step S32, when the TH opening change amount of the motorcycle 12 is less than a predetermined change amount, for example, less than 5% / s, step S33 is subsequently executed, and the instantaneous value on the fuel consumption indicator 11 is displayed. Assuming that the fuel efficiency is updated every 5 seconds, for example, step S37 is executed next. On the other hand, when the TH opening change amount of the motorcycle 12 is not less than a predetermined change amount, for example, not less than 5% / s in step S32, step S34 is subsequently executed.

  In step S34, if the TH opening change amount of the motorcycle 12 is less than a predetermined change amount, for example, less than 10% / s, step S35 is subsequently executed, and the instantaneous fuel consumption on the fuel consumption indicator 11 is determined. Assuming that the update is performed every 3 seconds, for example, step S37 is executed next. On the other hand, when the TH opening change amount of the motorcycle 12 is not less than a predetermined change amount, for example, 10% / s or more in step S34, step S36 is subsequently executed. In this step S36, the instantaneous fuel consumption INST on the fuel consumption display meter 11 is updated, for example, every second, and then step S37 is executed.

  As described above, in the second control method relating to the display of the instantaneous fuel consumption on the fuel consumption display meter 11 in the fuel consumption display system 10 of the present embodiment, the step is based on the update timing of the fuel consumption display meter 11 set in each step. In S37, the instantaneous fuel consumption display on the fuel consumption indicator 11 is updated. The calculation of the instantaneous fuel consumption in step S21 may be performed immediately after the update timing is set in steps S24, S25, S29, S31, S33, S35, and S36.

  In this case, in the auto mode, in step S26 to step S36, the update timing of the instantaneous fuel consumption display on the fuel consumption indicator 11 is changed (variable) in accordance with the TH opening change amount of the motorcycle 12. Specifically, the update timing is set shorter as the TH opening change amount increases.

  Since the throttle opening operation (especially the amount of change) has a great influence on the fuel consumption of the vehicle, changing the instantaneous fuel consumption update timing in accordance with the amount of change in the TH opening makes it economical for the driver. This is preferable from the viewpoint of prompting. Since the fuel efficiency decreases when the TH opening change amount is large, updating the instantaneous fuel consumption display at a finer timing (shorter timing) in such a state is more economical to the driver. The effect of driving can be expected.

  Furthermore, in this case, the update timing of the instantaneous fuel consumption is 0.5 times from 20 seconds to 10 seconds when the TH opening change amount is doubled from 1% / s to 2% / s, and 2% / s When it is 2.5 times from s to 5% / s, it is 0.5 times from 10 seconds to 5 seconds, and when it is doubled from 5% / s to 10% / s, it is 0 from 5 seconds to 3 seconds. .6, that is, when the amount of change in TH opening is approximately doubled, the update timing is set to be approximately 0.5 times accordingly. This makes it possible to change the update timing in a symmetric and wide range, which is easy for the driver to grasp and handle.

  Furthermore, in such a second control method, the instantaneous fuel consumption is updated on the fuel consumption indicator 11 in step S24 corresponding to the manual mode, for example, every 0.5 seconds, and in step S25. The update may be performed every 25 seconds, for example. In this case, the update timing of the instantaneous fuel consumption is set every 0.5 seconds or every 25 seconds in the manual mode, and is set every 1 to 20 seconds in the auto mode. Then, the shortest (fast) update timing and the longest (slow) update timing are set to the manual mode, and the update timing between them is set to the auto mode, so that the current display mode (update mode) is set to the manual mode for the driver. The mode can be easily recognized.

  In the fuel consumption display system 10 according to the above-described embodiment, the first and second control methods related to the instantaneous fuel consumption display are performed by the ECU 50 mainly used for engine control. In other words, although it has been described that the fuel consumption display means is mounted in the ECU 50, as shown in FIG. 7, it can be changed to a fuel consumption display system 10a including a fuel consumption display ECU 102 separately from the ECU 50. . The fuel efficiency display ECU 102 may be disposed, for example, close to the meter unit 62 or close to the ECU 50.

  In this case, instead of the ECU 50, the fuel consumption display ECU 102 includes the distance information calculation unit, the fuel consumption calculation unit, the instantaneous fuel consumption calculation unit, the average fuel consumption calculation unit, and the update timing in the fuel consumption display system 10a. It has each function as a change part and the said fuel consumption display process part.

  As described above, when the fuel efficiency display ECU 102 is provided separately from the ECU 50 as in the fuel efficiency display system 10a, the fuel efficiency display ECU 102 can be easily retrofitted as an option. For this reason, in the vehicle type etc. which do not require the display of the instantaneous fuel consumption, the control of the ECU 50 is not complicated, and as a result, versatility can be improved. Further, by adopting such a configuration, it is not necessary to add an unnecessary fuel consumption display ECU function to the ECU 50 even in a vehicle type that does not require the display of instantaneous fuel consumption, so that the production cost can be reduced.

  In the above embodiment, the setting of the update timing according to the vehicle speed and the TH opening change amount in the auto mode is set in five stages (not displayed or 1 second, 3 seconds, 5 seconds, 10 seconds, 20 seconds). Needless to say, however, it can be appropriately changed to, for example, 4 levels or 6 levels. Needless to say, the update timing (3 seconds, 5 seconds, etc.) at each stage can be changed as appropriate.

  Further, the display of the odometer 76, the trip meter 80, etc. in the meter unit 62 may be displayed on the liquid crystal display 85 together with the fuel consumption indicator 11, etc., and the configuration of the selector switch 94 in the meter unit 62 can be changed as appropriate. is there.

  Furthermore, in the fuel consumption display system, the display of the fuel consumption indicator 11 may be updated every time the constant fuel F is consumed. At that time, a time t required for consumption of the constant fuel F may be obtained by a predetermined timer or the like, and the instantaneous fuel consumption may be calculated as F / t and displayed.

  It should be noted that the present invention is not limited to the above-described embodiment, and it is naturally possible to adopt various configurations without departing from the gist of the present invention.

1 is a schematic side view of a motorcycle as a vehicle incorporating a vehicle fuel consumption display system according to an embodiment of the present invention. Fig. 2 is a schematic front view of a meter unit mounted on the motorcycle shown in Fig. 1. FIG. 3 is an enlarged view around the fuel meter shown in FIG. 2. It is a flowchart which shows the 1st control method which concerns on the display of the instantaneous fuel consumption with the fuel consumption indicator in the fuel consumption display system shown in FIG. FIG. 2 is a block configuration diagram showing a fuel consumption calculation system in the motorcycle shown in FIG. 1. It is a flowchart which shows the 2nd control method which concerns on the display of the instantaneous fuel consumption with the fuel consumption indicator in the fuel consumption display system shown in FIG. FIG. 6 is a block configuration diagram showing a modification of the fuel consumption calculation system in the motorcycle shown in FIG. 1.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10, 10a ... Vehicle fuel consumption display system 11 ... Fuel consumption indicator 12 ... Motorcycle 13 ... Body frame 20 ... Seat 26 ... Head pipe 31 ... Vehicle speed sensor 36 ... Fuel tank 38 ... Engine 50 ... ECU
62 ... Meter unit 82 ... Fuel gauge 84 ... Fuel meter 94 ... Changeover switch 100 ... Scale 101 ... Throttle opening detection means 102 ... ECU for fuel consumption display

Claims (1)

A distance information calculation unit for calculating a moving distance of the vehicle;
A fuel consumption calculation unit for calculating the fuel consumption of the vehicle;
An instantaneous fuel consumption calculation unit that calculates an instantaneous fuel consumption of the vehicle based on calculation results from the distance information calculation unit and the fuel consumption calculation unit;
A display unit (11) for displaying the instantaneous fuel consumption calculated by the instantaneous fuel consumption calculation unit;
A control unit (50, 102) for performing fuel consumption display processing on the display unit (11) based on calculation results from the distance information calculation unit, the fuel consumption calculation unit, and the instantaneous fuel consumption calculation unit;
A fuel consumption display system (10, 10a) for a vehicle comprising:
The control unit (50, 102) changes the update timing of the instantaneous fuel consumption display on the display unit (11) according to a predetermined condition,
The update timing of the instantaneous fuel consumption display is changed according to an auto mode automatically set according to a predetermined condition and a manual mode arbitrarily set by an operator,
The manual mode has a first timing and a second timing having an update timing shorter than the first timing,
In the auto mode, the fuel consumption display system (10, 10a) for a vehicle is set to an update timing between the first timing and the second timing.

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