Patent Application
20080178840
The present invention relates to an electronic control throttle system having an automated cruise mode in which an actuator is controlled by a controller to open and close a throttle valve so that a vehicle speed of a vehicle is maintained automatically, and a vehicle equipped with the electronic control throttle system.
For motorcycles, there has been proposed a control system having an automated cruise mode in which a motor controlled by an ECU controls an opening degree of a throttle valve for changing an amount of air taken in from outside and supplied to an engine, and a vehicle speed of the motorcycle is maintained without depending on a throttle grip operation performed by a driver (e.g., see Japanese Laid-Open Patent Application Publication No. 2001-246960). The automated cruise mode makes it possible to reduce an operation burden on a driver and to inhibit reduction of fuel efficiency caused by a change in the vehicle speed of the motorcycle, in contrast to a normal mode in which the driver operates the throttle grip with a hand.
In the control system disclosed in Japanese Laid-Open Patent Application Publication No. 2001-246960, a throttle shaft of the throttle valve is mechanically coupled to the throttle grip and the motor. In this construction, since the throttle grip operation performed by the driver is directly transmitted to the throttle shaft in the normal mode, an air-intake amount does not fluctuate smoothly, making the driver feel discomfort in driving the motorcycle. Also, when the driver quickly operates the throttle grip to close the throttle valve, an optimal combustion balance cannot be kept because of deficiency of the air-intake amount, degrading gas exhausting performance.
Accordingly, Japanese Laid-Open Patent Application Publication No. 2003-328784 discloses an electronic control throttle system in which a throttle grip is not mechanically coupled to a throttle shaft, and, in the normal mode, a throttle valve is driven to open and close by a motor under control of an ECU, based on an amount of rotation of the throttle grip, which is detected by a grip position sensor. In accordance with this electronic control throttle system, an optimal target opening degree of the throttle valve is calculated depending on a driving state of the motorcycle, and an electronic control is executed so that a deviation between a throttle valve opening degree resulting from the hand operation performed by the driver and the target opening degree is reduced. As a result, an optimal air-intake state can be maintained.
Assuming that the automated cruise mode is incorporated into the electronic control throttle system, the throttle grip is returned to a fully closed position by a force applied by a spring in a direction to close the throttle valve in the automated cruise mode, because the throttle grip is coupled to the throttle shaft electrically rather than mechanically. In the automated cruise mode, if the driver operates the throttle grip to open the throttle valve when the throttle grip is in the fully closed position, the automated cruise mode is maintained until a resulting grip opening degree reaches a grip opening degree corresponding to the cruising speed of the automated cruise. When the driver operates the throttle grip to open the throttle valve beyond the grip opening degree corresponding to the cruising speed in the automated cruise mode, the automated cruise mode returns to the normal mode, in which state, acceleration for reaching or surpassing the cruising speed can be carried out by the driver's hand operation.
Since there is a significant difference (dead zone or band) between the grip opening degree (fully closed position) at which the driver starts rotating the throttle grip and the grip opening degree at which acceleration actually occurs, the acceleration starts with a large time lag after the driver has operated the throttle grip to open the throttle valve. As a result, the driver feels discomfort in driving the motorcycle.
The present invention addresses the above described conditions, and an object of the present invention is to provide an electronic control throttle system for a vehicle which is capable of reducing discomfort associated with acceleration resulting from a driver's operation in an automated cruise mode, and a vehicle equipped with the electronic control throttle system.
According to an aspect of the present invention, there is provided an electronic control throttle system for a vehicle, comprising a throttle shaft configured to rotate a throttle valve for substantially opening and closing an air-intake passage connected to an engine; a hand-operated shaft configured to rotate in association with a rotation of an input member configured to be operated by a driver driving the vehicle; a biasing mechanism configured to apply a force to rotate the hand-operated shaft in a direction to close the throttle valve; a hand-operated-shaft-side driven member configured to operate in association with the rotation of the hand-operated shaft, the hand-operated-shaft-side driven member having a supported portion; a throttle-shaft-side driven member which is provided to operate in association with the rotation of the throttle shaft, the throttle-shaft-side driven member having a support portion positioned in a direction to close the throttle valve relative to the supported portion on an operation track of the supported portion; an actuator configured to cause the throttle shaft to rotate to open and close the throttle valve; and a controller having an automated cruise mode for controlling the actuator to control an engine speed of the engine so that a travel speed of the vehicle becomes a preset cruising speed; wherein in the automated cruise mode, the hand-operated shaft is subjected to a force in the direction to close the throttle valve and the supported portion is supported in contact with the support portion to cause the hand-operated shaft to operate according to the rotation of the throttle shaft.
In accordance with such a configuration, when the hand-operated shaft is subjected to the force in the direction to close the throttle valve in the automated cruise mode, the supported portion of the hand-operated-shaft-side driven member is supported in contact with the support portion of the throttle-shaft-side driven member. Thereby, the rotation of the throttle shaft driven by the actuator is transmitted to the hand-operated shaft via the throttle-shaft-side driven member and the hand-operated-shaft-side driven member. So, the input member operable in association with the hand-operated shaft rotates according to the rotation of the throttle shaft. Thereby, when the driver operates the input member in the automated cruise mode, the driver need not start operating the input member from a fully closed position. That is, the difference in opening degree between the position at which the driver starts operating the input member and the position at which acceleration actually starts is significantly reduced. This makes it possible to reduce or avoid a large time lag during acceleration when the input member has been operated to open the throttle valve in the automated cruise mode. As a result, responsiveness of the vehicle to the operation of the input member is improved, improving the driver's comfort.
The electronic control throttle system may further comprise a position sensor configured to detect a rotational angle of the hand-operated shaft; and an opening detector configured to detect that the input member has been operated in a direction to open the throttle valve from a position corresponding to the cruising speed in the automated cruise mode. The controller has a normal mode for controlling the actuator based on a detected value of the position sensor, and is configured to, in the automated cruise mode, switch the automated cruise mode to the normal mode when the opening detector detects that the input member has been operated in the direction to open the throttle valve from the position corresponding to the cruising speed in the automated cruise mode.
In such a configuration, the opening detector is provided to detect that the input member has been operated in the direction to open the throttle valve from the position corresponding to the cruising speed in the automated cruise mode, and the controller switches the automated cruise mode to the normal mode based on a detection signal from the opening detector, and controls acceleration. This makes it possible to improve the responsiveness of the vehicle to the operation of the input member operable according to the cruising speed in the automated cruise mode.
The electronic control throttle system may further comprise a throttle opening degree detector configured to detect a rotational angle of the throttle shaft. The controller may include the opening detector. The opening detector may be configured to, in the automated cruise mode, determine that the input member has been operated in the direction to open the throttle valve from the position corresponding to the cruising speed, based on the rotational angle detected by the position sensor and the rotational angle detected by the throttle opening degree detector.
In such a configuration, the controller is able to easily detect that the input member has been operated in the direction to open the throttle valve from the position corresponding to the cruising speed, without additionally providing an opening sensor for exclusive use.
The opening detector may be configured to, in the automated cruise mode, determine that the input member has been operated in the direction to open the throttle valve from the position corresponding to the cruising speed, when the rotational angle detected by the position sensor is a predetermined value or greater than the rotational angle detected by the throttle opening degree detector.
In such a configuration, the controller is able to easily detect that the input member has been operated in the direction to open the throttle valve from the position corresponding to the cruising speed.
The electronic control throttle system may further comprise a position sensor configured to detect a rotational angle of the hand-operated shaft. The controller may have a normal mode for controlling the actuator based on a detected value of the position sensor. In the normal mode, the supported portion of the hand-operated-shaft-side driven member may be provided to form a clearance in the direction to close the throttle valve relative to the support portion of the throttle-shaft-side driven member, between the supported portion and the support portion.
In such a configuration, in the normal mode, the supported portion of the hand-operated-shaft-side driven member is not in contact with the support portion of the throttle-shaft-side driven member, but there is a clearance between them. So, if the input member is quickly operated in the direction to close the throttle valve in the normal mode, the operation of hand-operated-shaft-side driven member in the direction to close the throttle valve is not impeded by the throttle-shaft-side driven member. Therefore, if the throttle shaft rotates after a slight time lag after the hand-operated shaft has been rotated in a case where the throttle shaft is controlled to be rotated according to the amount of the rotation of the hand-operated shaft in the normal mode, the hand-operated-shaft-side driven member does not interfere with the throttle-shaft-side driven member. This makes it possible to reduce or avoid driver discomfort while operating the input member.
The electronic control throttle system may further comprise a position sensor configured to detect a rotational angle of the hand-operated shaft and a closing operation detector configured to detect that the input member has been operated in the direction to close the throttle valve in the automated cruise mode. The controller may have a normal mode for controlling the actuator based on a detected value of the position sensor. The controller may be configured to switch the automated cruise mode to the normal mode when the closing operation detector detects that the input member has been operated in the direction to close the throttle valve.
In such a configuration, when the driver operates the input member to close the throttle shaft in the automated cruise mode, the automated cruise mode is forcibly terminated and switches to the normal mode. This improves response to the deceleration performed by the driver.
The closing operation detector may include a throttle cable through which the rotation of the input member is transmitted to the hand-operated shaft; a pivot lever to which the throttle cable is coupled; a detected member provided on the pivot lever; a closing sensor having a detecting portion in a position where a distance between the detecting portion and the detected member is changed according to a pivot amount of the pivot lever, the closing sensor being configured to change an output signal according to the distance between the detecting portion and the detected member. The closing operation detector is configured to detect that the input member has been operated in the direction to close the throttle valve, based on the output signal from the closing sensor. Alternatively, the electronic control throttle system may further comprise a tension sensor configured to detect a tension of a throttle cable through which the input member and the hand-operated shaft are coupled to each other. The closing operation detector may be configured to detect that the input member has been operated in the direction to close the throttle valve when the tension detected by the tension sensor is a predetermined value or more.
The hand-operated shaft and the throttle shaft may be disposed coaxially.
In such a configuration, since the hand-operated shaft and the throttle shaft are arranged along a common axis, there is a space in a direction perpendicular to the common axis. As a result, the electronic control throttle system can be made compact.
The hand-operated-shaft-side driven member may be coupled integrally with the hand-operated shaft. Also, the throttle-shaft-side driven member may be coupled integrally with the throttle shaft.
In such a configuration, components or members may be omitted between the hand-operated-shaft-side driven member and the hand-operated shaft and between the throttle-shaft-side driven member and the throttle shaft. As a result, the number of components does not substantially increase.
The hand-operated-shaft-side driven member may be provided at an end portion of the hand-operated shaft and has a disc shape which is coaxial with a rotation center of the hand-operated shaft, and the throttle-shaft-side driven member may be provided at an end portion of the throttle shaft and has a disc shape which is coaxial with rotation centers of the throttle shaft and the hand-operated-shaft-side driven member. The hand-operated-shaft-side driven member and the throttle-shaft-side driven member may be disposed to face each other to be spaced apart from each other.
In such a configuration, since the hand-operated-shaft-side driven member and the throttle-shaft-side driven member are respectively rotatable around the corresponding shafts, an operation range of the support portion and the supported portion provided at the driven members can be reduced.
The support portion may protrude from the throttle-shaft-side driven member toward the hand-operated-shaft-side driven member, and the supported portion may protrude from the hand-operated-shaft-side driven member toward the throttle-shaft-side driven member and is positioned in a space which is located in a direction to open the throttle valve relative to the support portion. In such a configuration, a simple support structure is obtained.
The hand-operated-shaft-side driven member and the throttle-shaft-side driven member may have a substantially equal diameter. The support portion and the supported portion may be provided at outer peripheral portions of the throttle-shaft-side driven member and the hand-operated-shaft-side driven member, respectively. One of the support portion and the supported portion may extend to a location opposite to an outer peripheral surface of the throttle-shaft-side driven member or the hand-operated-shaft-side driven member at which the other of the support portion and the supported portion is provided. In such a configuration, a simple support structure is obtained.
The support portion of the throttle-shaft-side driven member may be provided in a position except for a space which is located in a direction to open the throttle valve relative to the supported portion of the hand-operated-shaft-side driven member. In such a configuration, the support portion does not interfere with the supported portion even when the throttle valve is quickly opened in the normal mode.
According to another aspect of the present invention, there is provided a vehicle equipped with an electronic control throttle system, the electronic control throttle system including a throttle shaft configured to rotate a throttle valve for substantially opening and closing an air-intake passage connected to an engine; a hand-operated shaft configured to rotate in association with a rotation of an input member configured to be operated by a driver driving the vehicle; a biasing mechanism configured to apply a force to rotate the hand-operated shaft in a direction to close the throttle valve; a hand-operated-shaft-side driven member configured to operate in association with the rotation of the hand-operated shaft, the hand-operated-shaft-side driven member having a supported portion; a throttle-shaft-side driven member which is provided to operate in association with the rotation of the throttle shaft, the throttle-shaft-side driven member having a support portion positioned in a direction to close the throttle valve relative to the supported portion on an operation track of the supported portion; an actuator configured to cause the throttle shaft to rotate to open and close the throttle valve; and a controller having an automated cruise mode for controlling the actuator to control an engine speed of the engine so that a travel speed of the engine becomes a preset cruising speed; wherein in the automated cruise mode, the hand-operated shaft is subjected to a force in the direction to close the throttle valve and the supported portion is supported in contact with the support portion to cause the hand-operated shaft to operate according to the rotation of the throttle shaft. In such a configuration, responsiveness of the vehicle to the operation of the input member is improved, improving the driver's comfort.
The input member may be a throttle grip or a throttle lever configured to be gripped by a driver driving the vehicle. In such a configuration, since the driver grips the input member all the time during travel of the vehicle, transition from the automated cruise mode to the normal mode is quickly accomplished.
The above and further objects and features of the invention will more fully be apparent from the following detailed description and accompanying drawings.
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. Herein, directions are generally referenced from the perspective of a driver mounting a motorcycle.
A clutch lever 8 is attached in front of a grip of the handle 6 which is configured to be gripped by a left hand of the driver. A meter device 9 which displays a travel speed, an engine speed and other vehicle operating information, and has various switches associated with an automated cruise mode, is disposed in front of the handle 6. A pair of main frame members 10 extend rearward from the head pipe 5 to be tilted slightly downward. A pair of pivot frame members 11 are coupled to rear portions of the main frame members 10. A swing arm 12 is pivotally mounted at a front end portion thereof to the pivot frame member 11 and is configured to extend in a substantially longitudinal direction of the motorcycle 1. The rear wheel 3, which is a drive wheel, is rotatably mounted to a rear end portion of the swing arm 12. A fuel tank 13 is disposed behind the handle 6. A straddle-type seat 14 configured to be straddled by the driver is mounted behind the fuel tank 13.
Between the front wheel 2 and the rear wheel 3, the engine E is mounted on the main frame members 10 and the pivot frame members 11. A throttle body 15 is disposed inward of the main frame members 10 and is coupled to intake ports (not shown) of the engine E. An ECU (electronic control unit) 16, which is a controller, is accommodated in an inner space below the seat 14 to control the throttle body 15. An air cleaner box 17 is disposed below the fuel tank 13 and is coupled to an upstream side of the throttle body 15. The air cleaner box 17 is configured to take in fresh air by utilizing a wind pressure of the wind blowing from forward. A cowling 18 is mounted to extend from a front portion of the vehicle body to both sides of the vehicle body so as to cover the engine E and other components.
A first gear 24 is mounted on the throttle shaft 22. The throttle body 15 includes the DC motor 26. A second gear 25 is mounted on a drive shaft of the DC motor 26 and is in mesh with the first gear 24. In this state, a rotational driving force of the DC motor 26 is transmitted to the throttle shaft 22 via the second gear 25 and the first gear 24, causing the throttle valve 21 to be opened and closed. A throttle-shaft-side driven member 28 is mounted to a right end portion of the throttle shaft 22 so as to protrude in a flange shape radially outward from the throttle shaft 22.
As shown in
As shown in
The automated cruise mode controller 39 is configured to execute an automatic driving mode in which the DC motor 26 is electronically controlled via the motor driving circuit 38 so that the engine E runs at a preset cruising engine speed. As used herein, the term “cruising engine speed” means an engine speed in which the motorcycle 1 is traveling at a preset cruising speed. The normal mode controller 40 is configured to execute a hand-operation driving mode in which an optimal target opening degree of the throttle valve 21 is calculated based on a detected value of the grip position sensor 35 considering a driving state of the motorcycle 1 and the like, and the DC motor 26 is electronically controlled so that a deviation between an opening degree detected by the grip position sensor 35 and a target opening degree is reduced.
The opening detector 41 is configured to detect that the throttle grip 7 has been operated in a direction to open the throttle valve 21 from a position corresponding to a cruising speed in the automated cruise mode. To be more specific, the opening detector 41 is configured to determine that the throttle grip 7 has been operated in the direction to open the throttle valve 21 from the position corresponding to the cruising speed when a difference between the opening degree detected by the grip position sensor 35 and the opening degree detected by the throttle position sensor 27 in the automated cruise mode is a predetermined value or more.
The meter device 9 (see
Subsequently, an operation of the electronic control throttle system 20 will be described.
If it is determined that the automated cruise permission condition is not met (NO in step S4), the ECU 16 returns the process to step S1. On the other hand, if it is determined that the automated cruise permission condition is met (YES in step S4), the ECU 16 determines whether or not the automated cruise mode control is being executed (step S5). If it is determined that the automated cruise mode control is being executed (YES in step S5), the ECU 16 determines whether or not the SET/INC switch 44 has been pressed (step S6). If it is determined that the SET/INC switch 44 has been pressed (YES in step S6), a set value of the cruising speed is increased according to the number of times the switch 44 has been pressed (step S7). Under this condition, the electronic control throttle system 20 is controlled by the automated cruise mode controller 39 of the ECU 16 to be in the automated cruise mode (step S14).
If it is determined that the SET/INC switch 44 has not been pressed (NO in step S6), the ECU 16 further determines whether or not the RESUME/DEC switch 45 has been pressed (step S8). If it is determined that the RESUME/DEC switch 45 has been pressed (YES in step S8), the ECU 16 decreases the set value of the cruising speed according to the number of times the switch 45 has been pressed (step S9), and the electronic control throttle system 20 is controlled by the automated cruise mode controller 39 to be in the automated cruise mode (step S14). On the other hand, if it is determined that the RESUME/DEC switch 45 has not been pressed (NO in step S8), the ECU 26 returns the process to step S2.
If it is determined that the automated cruise mode control is not being executed (NO in step S5), the ECU 16 determines whether or not the SET/SWITCH 44 has been pressed (step S10). If it is determined that the SET/INC switch 44 has been pressed (YES in step S10), the ECU 16 determines and sets a current vehicle speed as the cruising speed (step S11), and the automated cruise mode controller 39 of the ECU 16 starts the automated cruise mode control (step S14). If it is determined that the SET/INC switch 44 has not been pressed (NO in step S10), the ECU 16 further determines whether or not the RESUME/DEC switch 45 has been pressed (step S12). If it is determined that the RESUME/DEC switch 45 has been pressed (YES in step S12), the automated cruise mode control restarts at the cruising speed previously determined (steps S13 and S14). On the other hand, if it is determined that the RESUME/DEC switch 45 has not been pressed (No in step S12), the ECU 16 returns the process to step S1.
Then, the opening detector 41 of the ECU 16 determines whether or not a difference between the opening degree detected by the grip position sensor 35 and the opening degree detected by the throttle position sensor 27 is a predetermined value or more (step S15). If it is determined that the difference is the predetermined value or more (YES in step S15), the ECU 16 determines that the throttle grip 7 has been operated in the direction to open the throttle valve 21 from the position corresponding to the cruising speed, and returns the process to step S1 to execute the normal mode control. At this time, the supported portion 34a of the hand-operated-shaft-side driven member 34 is supported in contact with the support portion 28a of the throttle-shaft-side driven member 28, and in this state, the throttle grip 7 rotates according to the rotation of the throttle shaft 22. Therefore, when the driver operates the throttle grip 7 for acceleration and switches the automated cruise mode to the normal mode, the driver need not start rotating the throttle grip 7 from the fully closed position.
If it is determined that the difference in opening degree is less than the predetermined value (NO in step S15), the ECU 16 further determines whether or not the closing detecting switch 48 has been turned ON (step S16). In this case, since the supported portion 34a is supported by the support portion 28a, the pulley 31 does not move even when the throttle grip 7 is operated in the direction to close the throttle valve 21, whereas the end portion 52a of the pivot lever 52 rotates around the pivot shaft 53, and thereby the closing detecting switch 48 is turned ON. So, the ECU 16 returns the process to step S1 to execute the normal mode control. On the other hand, if it is determined that the closing detecting switch 48 is in the OFF-state (NO in step S16), the ECU 16 determines whether or not the brake switch 46 is in the ON-state (step S17).
If it is determined that the brake switch 46 is in the ON-state (YES in step S17), the ECU 16 returns the process to step S1 to execute the normal mode control. On the other hand, if it is determined that the brake switch 46 is in the OFF-state (NO in step S17), the ECU 16 further determines that the clutch switch 47 is in an ON-state (step S18). If it is determined that the clutch switch 47 is in the ON-state (YES in step S18), the ECU 16 returns the process to step S1 to execute the normal mode control. If it is determined that the clutch switch 47 is in the OFF-state (NO in step S18), the ECU 16 returns the process to step S2 to continue the automated cruise mode.
In accordance with the above described configuration, in the automated cruise mode, the throttle grip 7 operable in association with the rotation of the hand-operated hand 32 operates according to the rotation of the throttle shaft 22. Therefore, the driver need not start rotating the throttle grip 7 from the fully closed position when the driver operates the throttle grip 7 for acceleration and switches the automated cruise mode to the normal mode. Therefore, the difference in opening degree between the grip opening degree at which the driver starts rotating the throttle grip 7 and the grip opening degree at which acceleration actually starts is significantly reduced. This makes it possible to avoid acceleration that starts with a large time lag when the throttle grip 7 is operated to open the throttle valve 21 in the automated cruise mode. As a result, responsiveness of the motorcycle 1 to the operation of the throttle grip 7 is improved, improving the driver's comfort.
An electronic control throttle system according to a second embodiment will be described.
As shown in
An electromagnetic solenoid 65 is attached to a side surface of the throttle-shaft-side driven member 61. A movable iron core 66 of the electromagnetic solenoid 65 protrudes toward the first ring 63a along a side surface of the throttle-shaft-side driven member 61. A second ring 66a is mounted on a tip end of the movable iron core 66 on the first ring 63a side. A coupling ring 67 is mounted between the first ring 63a and the second ring 66a.
A tension sensor (closing operation detector) 68 is coupled to the opening cable 50 (see
The hand-operated shaft 32 is disposed coaxially with the throttle shaft 22. A hand-operated-shaft-side driven member 73 is provided at an end portion of the hand-operated shaft 32. The hand-operated-shaft-side driven member 73 is disposed to face the throttle-shaft-side driven member 70, and has an insertion hole 73b into which the rod-shaped support portion 70a is inserted. The insertion hole 73a is circular-arc shaped to allow the rod-shaped support portion 70a to be movable in the circumferential direction around the hand-operated shaft 32 within the insertion hole 73a. An end portion in the circumferential direction of the insertion hole 73a is a supported portion 73b configured to be supported by the support portion 70a in the automated cruise mode. The other configuration is substantially identical to that of the first embodiment, and will not be further described herein.
The throttle shaft 22 is placed substantially in parallel with the hand-operated shaft 32, and is provided at an end portion thereof with a throttle-shaft-side pinion gear 83. The throttle-shaft-side rack gear 84, which is a throttle-shaft-side driven member, is in mesh with the throttle-shaft-side pinion gear 83. The throttle-shaft-side rack gear 84 is substantially parallel to the hand-operated-shaft-side rack gear 81 and has a support portion 84a protruding toward the hand-operated rack gear 81. That is, the support portion 84a is positioned in the direction to close the throttle valve 21 relative to the supported portion 81a on an operation track of the supported portion 81a, and the supported portion 81a is configured to be supported by the support portion 81a in the automated cruise mode. The other configuration is substantially identical to that of the first embodiment, and will not be further described herein.
While in the above described embodiments, the motorcycle 1 has been illustrated, the electronic control throttle system 20 of the present invention is applicable to other vehicles such as all terrain vehicles (ATVs) or personal watercraft (PWC).
As this invention may be embodied in several forms without departing from the spirit of essential characteristics thereof, the present embodiments are therefore illustrative and not restrictive, since the scope of the invention is defined by the appended claims rather than by the description preceding them, and all changes that fall within metes and bounds of the claims, or equivalence of such metes and bounds thereof are therefore intended to be embraced by the claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2007-018079 | Jan 2007 | JP | national |
