This patent application claims priority under 35 U.S.C. § 119 to Japanese Patent Application No. 2007-241056, filed on Sep. 18, 2007, Japanese Patent Application No. 2007-333496, filed on Dec. 26, 2007, and Japanese Patent Application No. 2008-111467, filed on Apr. 22, 2008, the entire contents of which are hereby expressly incorporated by reference.
The present invention relates to a straddle type vehicle.
Conventionally, in a straddle type vehicle, such as a two-wheel motor vehicle, an electronic throttle valve system that controls a throttle valve automatically has been known for some time. See, for example, Japanese patent publication JP WO2005/047671 A1 of May 26, 2005.
The electronic throttle valve system enables control of the throttle valve regardless of the operation of the acceleration grip and the like by a rider. This allows for advanced throttle control compared to conventional systems.
The present invention was made in consideration of the above points. An object of the present invention is to provide a straddle type vehicle with an electronic throttle valve that is capable of providing advanced throttle control compared to the conventional vehicles. A straddle type vehicle according to one aspect of the present invention comprises a throttle valve for adjusting the amount of air intake of an engine; an acceleration controller operated by a rider for opening and closing the throttle valve; an electric motor for actuating the throttle valve; a first member displaced together with the throttle valve, the first member having a first original position when the throttle valve is fully closed; a second member displaced in accordance with the acceleration controller, the second member having a second original position when the acceleration controller is fully closed; an elastic body interposed between the first member and the second member when at least the first member and the second member are in the first original position and the second original position, respectively, the elastic body generating a restoring force to return the first member to the first original position when the second member is in the second original position, and maintaining the second member in the second original position by being elastically deformed until the first member reaches a predetermined position when the first member is displaced from the first original position in a direction in which the throttle valve opens in a state in which the second member is in the second original position; and a control device responsive to a predetermined control signal for opening the throttle valve by driving the electric motor and displacing the first member until the first member reaches at most the predetermined position.
The straddle type vehicle may further include a multistage transmission; an input device for receiving a gear shift change command from the rider; and a gear shift actuator for driving the transmission to perform a gear shift change when the gear shift change command is input in the input device, and the predetermined control signal may be a signal generated when a gear shift change is performed by the shift actuator when the acceleration controller is fully closed.
According to the straddle type vehicle as described above, even when the second member is in the second original position, since the acceleration controller is fully closed, the throttle valve may be opened without displacing the second member. This allows for so-called blipping in which the rotational speed of an engine is temporarily increased by opening the throttle valve sharply and temporarily even without a special blipper. Thus, a quick gear shift change is achieved by performing the blipping at gear shift changes.
In addition, according to the straddle type vehicle as described above, blipping may be performed using the first member, the second member, and the elastic body each of which is used for functions other than blipping. This allows for blipping without providing a special blipper for blipping.
The straddle type vehicle may further include a vehicle speed sensor for detecting the vehicle speed, and the predetermined control signal may be a control signal for adjusting the opening of the throttle valve so that the vehicle speed becomes a predetermined value in a range in which the first member is positioned between the first original position and the predetermined position.
According to this straddle type vehicle, the vehicle speed can be maintained at a predetermined setting regardless of the opening of the acceleration controller. This allows for a so-called cruise control.
The straddle type vehicle may further include a multistage transmission; a drive wheel; a driven wheel; a first sensor for detecting a rotational speed of the drive wheel; and a second sensor for detecting a rotational speed of the driven wheel, whereby the predetermined control signal may be a control signal for adjusting the opening of the throttle valve so that the difference between the rotational speed of the drive wheel and the rotational speed of the driven wheel is not greater than a predetermined value during a down gear shift of the transmission.
According to the above-described straddle type vehicle, when the difference between the rotational speed of the drive wheel and the rotational speed of the driven wheel exceeds a predetermined setting during a down gear shift, the opening of the throttle valve is adjusted so that the speed difference is not greater than the predetermined setting. In other words, the throttle valve is opened so that the speed difference is not increased. This prevents excessive engine braking.
According to the present invention, a straddle type vehicle having an electronic throttle valve and capable of an advanced control compared to conventional vehicles can be achieved.
For the purpose of eliminating the burden on riders during gear shifting, an Automated Manual Transmission (AMT) which automatically performs the gear shift change by using an actuator has been known. Moreover, in order to improve fuel efficiency and the like, an electronic throttle valve system for automatically controlling a throttle valve has also been known.
In a straddle type vehicle having a multistage transmission, a method for performing a quick gear shift change by performing so-called blipping without disengaging the clutch has been known. Moreover, a method for conducting a smooth gear shift change by performing blipping after disengagement of a clutch at gear shift changes in order to mitigate a shock in the following clutch engagement has also been known. It should be noted that in this specification, the term “blipping” means increasing the rotational speed of an engine temporarily by sharply opening the throttle valve temporarily.
For example, Japanese patent publication JP-A-2002-067741 of Mar. 8, 2002 discloses providing a blipper for idling an engine in a two-wheel motor vehicle having an AMT and an electronic throttle valve.
As described in Japanese patent publication JP-A-2002-067741, blipping can be performed at gear shift changes in a two-wheel motor vehicle provided with an AMT and an electronic throttle valve. However, in these motor vehicles, there has been a problem that a special blipper (for blipping) has to be additionally provided.
The straddle type vehicle according to the present embodiment advantageously overcomes this problem without providing a special blipper in a straddle type vehicle having an AMT and an electronic throttle valve.
Hereinafter, a straddle type vehicle according to the present embodiment will be described in detail with reference to the appended drawings. More particularly, a two-wheel motor vehicle 1 of a motorcycle type, as shown in
The two-wheel motor vehicle 1 includes a body frame 2 which has a head pipe 2a. A handle bar 3 is mounted on an upper end of the head pipe 2a, and a front wheel 5 is mounted to a lower end of the head pipe 2a through front forks 4 in a freely rotatable manner. A swing arm 6 capable of oscillating is attached to a rear end of the body frame 2. A rear wheel 7 is mounted in a rotatable manner to the rear end of the swing arm 6.
A fuel tank 8 is mounted to the body frame behind the head pipe 2a. A seat 9 is provided at the rear side of the fuel tank 8.
A power unit 10 including an engine 12 as a driving source is suspended from the body frame 2. The power unit 10 is operatively connected to the rear wheel 7 through a power transmission means 11 such as a chain, a belt and a drive shaft. This allows the power transmission means 11 to transmit driving force to the rear wheel 7, the driving force being generated in the power unit 10 by the engine 12.
Next, referring mainly to
Engine 12 is disposed in a manner such that a cylinder shaft (not shown) extends slightly obliquely upward toward the front of the body. Referring to
Transmission 13 is a multistage transmission and includes a main shaft 22, a drive shaft 23 and a gear selection mechanism 24. The main shaft 22 is connected to the crankshaft 21 through the clutch 14. The main shaft 22 and the drive shaft 23 are each disposed substantially parallel to the crankshaft 21. In addition, a main shaft rotational speed sensor S31 is provided adjacent the main shaft 22.
A plurality of gears 25 are mounted on the main shaft 22. Moreover, a plurality of corresponding gears 26 are mounted on the drive shaft 23. Engagement between the plural gears 25 and the plural gears 26 is achieved only through a pair of selected gears 25 and 26, respectively. Among the plural gears 25 and 26, at least either the gears 25, with the exception of selected gear 25, or the gears 26, with the exception of selected gear 26, are rotatable with respect to the main shaft 22 or the drive shaft 23, respectively. In other words, at least either the unselected gears 25 or the unselected gears 26 idle with respect to the main shaft 22 or the drive shaft 23. Thus, rotational transmission between the main shaft 22 and the drive shaft 23 is achieved only through the selected gears 25 and 26 which engage with each other.
Selection of the gears 25 and 26 is performed by gear selection mechanism 24. More specifically, a shift cam 27 of the gear selection mechanism 24 performs the selection of the gears 25 and 26. A plurality of cam grooves 27a are formed on the outer peripheral surface of the shift cam 27. A shift fork 28 is mounted to each cam groove 27a. Each shift fork 28 engages with a predetermined gear 25 of the main shaft 22 and a predetermined gear 26 of the drive shaft 23, respectively. When the shift cam 27 is rotated, each of the plural the shift forks 28 is guided (by means of cam groove 27a) to move in the axial direction of the main shaft 22. This allows for selection of the gears to engage with each other among the plural gears 25 and 26. More specifically, from the plural gears 25 and 26, only a pair of gears 25 and 26 positioned in accordance with a rotational angle of the shift cam 27 is fixed by a spline with respect to the main shaft 22 and the drive shaft 23. This determines the position of the gears, and, through the gears 25 and 26, rotational transmission of power from engine 12 with a predetermined change gear ratio is performed between the main shaft 22 and the drive shaft 23. This results in power transmission to the rear wheel 7 through the power transmission means 11 shown in
The gear selection mechanism 24 is operatively connected to a shift actuator 16 through a shift power transmission means 15. This allows the shift actuator 16 to drive the gear selection mechanism 24.
In this embodiment, the clutch 14 is a multi-plate friction clutch which includes a cylindrical clutch housing 31, a cylindrical clutch boss 32, a plurality of friction discs 33 and clutch plates 34 serving as friction plates and a pressure plate 35. Moreover, the clutch 14 includes a gear 29 to mesh with a gear 21 a formed on the crankshaft 21.
The clutch housing 31 is formed in the shape of a cylinder and mounted on the main shaft 22 in a relatively rotatable manner. On an inner peripheral surface of the clutch housing 31, a plurality of grooves extending in the axial direction of the main shaft 22 are formed.
Each friction disc 33 is formed in the shape of a thin-plate ring. A plurality of teeth are formed on the outer periphery of each friction disc 33. Engagement between the plural teeth formed on the outer periphery of the friction disc 33 and the plural grooves formed on the inner peripheral surface of the clutch housing 31 enables each friction disc 33 to be mounted to the clutch housing 31 in a relatively unrotatable manner. Additionally, each friction disc 33 is mounted in a slidable manner in the axial direction of the main shaft 22 with respect to the clutch housing 31.
The clutch boss 32 is formed in the shape of a cylinder and is disposed radially inward of the inner side of clutch housing 31 on the main shaft 22. Moreover, the clutch boss 32 is mounted to the main shaft 22 in a relatively unrotatable manner. On an outer peripheral surface of the clutch boss 32, a plurality of grooves extending in the axial direction of the main shaft 22 are formed.
Each clutch plate 34 is formed in the shape of a thin-plate ring. A plurality of teeth are formed on the inner periphery of each clutch plate 34. Engagement between the plural teeth formed on the inner periphery of the clutch plate 34 and the plural grooves formed on the outer peripheral surface of the clutch boss 32 enables each clutch plate 34 to be mounted to the clutch boss 32 in a relatively unrotatable manner. Additionally, each clutch plate 34 is mounted in a slidable manner in the axial direction of the main shaft 22 with respect to the clutch boss 32.
Each friction disc 33 is mounted to the clutch housing 31 such that its plate surface is substantially orthogonal to the axial direction of the main shaft 22. Each clutch plate 34 is mounted to the clutch boss 32 such that its plate surface is substantially orthogonal to the axial direction of the main shaft 22. Each friction disc 33 and each clutch plate 34 are alternately disposed in the axial direction of the main shaft 22.
The pressure plate 35 is formed substantially in the shape of a disc and mounted in a slidable manner in the axial direction of the main shaft 22 with respect to the clutch boss 32. The pressure plate 35 is mounted in a freely rotatable manner to one end of a push rod 37 (the right side in
In the cylindrical main shaft 22, a spherical ball 38 adjacent to the other end of the push rod 37 (the left end) is provided. On the left side of the ball 38, a push rod 39 adjacent to the ball 38 is provided.
One end of the push rod 39 (the left end) protrudes from the other end of the cylindrical main shaft 22 (the left end). The protruding one end of the push rod 39 is connected to a clutch actuator 18 through a clutch power transmission means 17.
The shift actuator 16 and the clutch actuator 18 are each connected to a control device 100 and are driven by the control device 100. In
Specifically, when a rider inputs a shift change command into an input device (a shift up switch 61a or a shift down switch 61b which will be described later), the control device 100 starts shift control. Initially, the control device 100 drives the clutch actuator 18 and disengages the clutch 14 to achieve a disengaged state. Next, the control device 100 drives the shift actuator 16 to cause the gear selection mechanism 24 to select the desired gears 25 and 26. Thereafter, the control device 100 drives the clutch actuator 18 again to engage the clutch 14.
The two-wheel motor vehicle 1 includes an electronic throttle valve system 70 for adjusting the amount of air intake of the engine 12. Hereinafter, with reference to
As shown in
As shown in
As shown in
The valve shaft 73 is also provided with a throttle opening sensor S40 for detecting the opening of the throttle valve 71. In this embodiment, the throttle opening sensor S40 is located on the right end 73a of the valve shaft 73. The throttle opening sensor S40 is in electrical connection with the control device 100.
The valve shaft 73 is also provided with a mechanical throttle valve actuating mechanism 50 (hereinafter, it is referred to as “mechanical actuating mechanism 50” for convenience). In this embodiment, the mechanical actuating mechanism 50 is located on the left end 73b of the valve shaft 73. The mechanical actuating mechanism 50 is designed to actuate the throttle valve 71 in conjunction with the operation of a throttle grip 60 which is an acceleration controller in the event that the electric motor 72 stops actuating the throttle valve 71.
As shown in
A grip 61 is provided on a left end of the handle bar 3. On a right end of the grip 61, a switch box 63 is provided. In this embodiment, the switch box 63 has the shift up switch 61a and the shift down switch 61b, which are input devices for receiving a shift change command from the rider. It should be noted that the input devices are not limited to the shift up switch 61a and the shift down switch 61b, and other embodiments in various forms are possible.
As shown in
The pulley 52 and the lever pulley 54 are each formed substantially in the shape of a disc in which a part has been notched. Moreover, a center portion of the pulley 52 and a center portion of the lever pulley 54 are connected by the shaft portion 53 in a relatively unrotatable manner. This means that the lever pulley 54 rotates in conjunction with rotation of the pulley 52. The aforementioned throttle cable 62 engages with the pulley 52. In addition, the pulley 52 is provided with a return spring 80. The pulley 52 and the lever pulley 54 are housed in a cover 59 of the mechanical actuating mechanism 50 (see
In the illustrative configuration shown in
As shown in
In the following description, a position of the protrusion 77 (the first member) when the throttle valve 71 is fully closed (the throttle opening is 0°) is determined as a first original position P1, and a position of the lever pulley 54 (the second member) when the throttle grip 60 (the acceleration controller) is fully closed (the acceleration opening is 0°) is determined as a second original position P2.
The lever pulley 54 is provided with a spring 51 as an elastic body. The spring 51 is designed to be interposed between the protrusion 77 and the lever pulley 54 at least when the lever pulley 54 is located in the second original position P2 (a position when the throttle grip 60 is fully closed). The spring 51 is designed so as to generate a restoring force to return the protrusion 77 to the first original position PI when the lever pulley 54 is located in the second original position P2.
Next, with reference to
In the state shown in
When the protrusion 77 has the opening of 0°, a distal end of the spring 51, which protrudes from the edge face of the notched portion 55 of the lever pulley 54, generally comes into contact with the protrusion 77. The spring 51 is located so as to generally come into contact with the protrusion 77 when the throttle valve 71 is closed.
When the throttle grip 60 (which is the acceleration controller) is sharply turned so that throttle valve 71 is fully opened from the state shown in
Specifically, when the throttle grip 60 is sharply turned as described above, the torque of the throttle grip 60 is transmitted to the pulley 52 by the throttle cable 62 and the pulley 52 rotates sharply. When the pulley 52 has the opening of θ1 (e.g. 80°), which is an angle for fully opening the throttle valve 71, the lever pulley 54 also rotates through the link member 56 by the angle of θ1. This allows the edge face and the spring 51 on the notched portion 55 of the lever pulley 54 to rotate by a predetermined angle in accordance with the angle of θ1.
On the other hand, as the throttle grip 60 rotates, the accelerator-opening sensor S70 (see
It should be noted that, when the throttle grip 60 is sharply rotated as described above, the response speed of the lever pulley 54, which is in mechanical connection with the throttle grip 60, is faster than that of the throttle valve 71 and the protrusion 77, which are in electrical connection with the throttle grip 60. This results in the opening θ1 of the lever pulley 54 becoming greater than the opening θ2 of the throttle valve 71. In other words, the target opening of the throttle valve 71 becomes greater than the resultant opening, so that the distal end of the spring 51 moves away from the protrusion 77.
After that (e.g. less than 0.1 second later), as shown in
Next, as shown in
Under the state that the distal end of the spring 51 and the protrusion 77 contact each other, they move until they reach the state shown in
Next, the operation of the mechanical actuating mechanism 50 in abnormal situations will be described. The mechanical actuating mechanism 50 operates as described below in such abnormal situations that the electric motor 72 stops actuating the throttle valve 71 due to the interruption of the current from the electric motor 72 and the like and that the throttle valve 71 remains open and cannot be closed.
Even when the throttle valve 71 cannot be closed due to malfunction of the electric motor 72, it can be closed by the mechanical actuating mechanism 50. More specifically, in the event that the electric motor 72 stops actuating the throttle valve 71, when the throttle grip 60 is normally turned in such a direction that the throttle valve 71 is closed, the lever pulley 54 which is in mechanical connection with the throttle grip 60, rotates. On the other hand, the protrusion 77 does not move due to stoppage of the electric motor 72. However, by means of rotation of the lever pulley 54, the protrusion 77 contacts the lever pulley 54. Then, as the spring 51 is compressed, the protrusion 77 and the lever pulley 54 are in the state shown in
As shown in
As described hereinabove, in the event that the electric motor 72 stops actuating the throttle valve 71, the normal rotating operation of the throttle grip 60 allows for compulsory closing of the throttle valve 71.
In this two-wheel motor vehicle 1, in a case where a shift control is started when the throttle valve 71 is fully closed, a quick gear shift change is achieved by performing so-called blipping without disengaging the clutch 14. The control device 100 performs the gear shift change with blipping as described below.
When the rider operates the shift up switch 61a or the shift down switch 61b, a gear shift change command is sent to the control device 100. At this point, the control device 100 determines whether or not the opening of the throttle grip 60 (opening of the accelerator) detected by the accelerator-opening sensor S70 is 0°. If the opening of the accelerator is 0°, the control device 100 performs the gear shift change with blipping.
More specifically, instead of actuating the clutch actuator 18 to disengage the clutch 14, the control device 100 performs so-called blipping in which the electric motor 72 is driven to open the throttle valve 71 sharply so that the rotational speed of the engine is increased temporarily. After the blipping, the control device 100 actuates the shift actuator 16 for the gear shift change without disengaging the clutch 14.
In the above-described blipping, the electronic throttle valve system 70 operates as described below. First, at the start of the gear shift change, the electronic throttle valve system 70 is in the state shown in
As the throttle grip 60 is fully closed at this point, the mechanical, actuating mechanism 50 is not actuated, so that the lever pulley 54 is not rotated by the mechanical, actuating mechanism 50. The spring 51 is designed so as to be elastically deformed until the protrusion 77 returns to a predetermined position (a position in which the throttle opening is θ6 (see
According to the two-wheel motor vehicle 1 described above, blipping can be performed in a vehicle having an AMT and an electronic throttle valve system 70 to open the throttle valve 71 when the throttle grip 60, which is the acceleration controller, remains in a fully closed state. Accordingly, by blipping during a shift change it is possible to omit disengagement and engagement of the clutch 14. Thus, a quick gear shift change is achieved in the two-wheel motor vehicle 1.
Although blipping is performed instead of disengagement of the clutch 14 in this embodiment, blipping may be performed after disengagement of the clutch 14. In such a case, a shock, which occurs in re-engagement of the clutch after a gear shift change, can be mitigated. This achieves a smooth gear shift change.
Moreover, in reference to two-wheel motor vehicle 1, blipping can be performed using the protrusion 77 (the first member) which is designed to improve responsivity in fully closing control of the throttle valve 71, the lever pulley 54 (the second member) and the spring 51 (the elastic body). Thus, blipping is performed without additionally providing a special blipper for blipping.
Moreover, according to this two-wheel motor vehicle 1, the spring 51 is designed to maintain the lever pulley 54 in the second original position P2 by being elastically deformed until the protrusion 77 is rotated to a predetermined position (a position in which the throttle opening is θ6 (see
Moreover, in the above-described two-wheel motor vehicle 1, the spring 51 is set to generate elastic force to return the protrusion 77 to the first original position P1 when the lever pulley 54 is in the second original position P2. Consequently, in the aforementioned abnormal situation and the like where the throttle grip 60 is closed in a state in which the throttle valve 71 has an opening which is greater than or equal to θ6, after the lever pulley 54 is displaced to the second original position P2 while pushing the protrusion 77, the protrusion 77 is pushed by the elastic force of the spring 51 to return to the first original position P1. This causes the movement of the throttle valve 71 to slow down just before a fully closed state. Thus a shock which occurs when the throttle grip 60 is returned is mitigated. According to the configuration of this embodiment, both the function of mitigating a shock when the throttle grip 60 is returned and the function of blipping can be achieved simultaneously.
Incidentally, in this embodiment the elastic body according to the present invention is constituted by the spring 51. However, the elastic body according to the present invention is not limited to the spring 51. The elastic body according to the present invention may be a rubber member, for example.
The effect of the spring 51, namely to help actuate the throttle valve 71 smoothly, can be obtained not only in the embodiment in which the pulley 52 and the lever pulley 54 are coupled through the aforementioned link member 56, but also in another embodiment in which the pulley 52 and the lever pulley 54 are coupled coaxially through the shaft portion 53 shown in
In this embodiment, the protrusion 77 rotating together with the throttle valve 71 constitutes the first member, and the lever pulley 54 rotating in accordance with the throttle grip 60 constitutes the second member of the present invention. However, components constituting the first member and the second member are not limited to these implementations. For example, the first member may be constituted by a first sliding member which slides in accordance with rotation of the throttle valve 71, and the second member may be constituted by a second sliding member which slides in accordance with rotation of the throttle grip 60.
The two-wheel motor vehicle 1 according to the present embodiment allows for a so-called cruise control in which running at a constant speed is achieved without operation of the throttle grip 60 by the rider.
The two-wheel motor vehicle 1 according to the present embodiment includes the throttle valve system 70 similar to that of the first embodiment. In the following descriptions, the same components as those of the first embodiment are assigned the same reference numerals and symbols, and their explanations are omitted.
A switch 206a input when a cruise control is started and a switch 206b input when the cruise control is stopped are disposed adjacent to the throttle grip 60. The switches 206a and 206b are connected to the ECU 100. The ECU 100 starts the cruise control when the switch 206a is input. On the other hand, the ECU stops the cruise control when the switch 206b is input during the cruise control.
The ECU 100 is connected to a brake sensor 203 that detects the input of a front brake 60B and a brake sensor 205 that detects the input of a rear brake 204. Thus, when the rider executes a brake operation, the brake sensor 203 or 205 transmits a signal to the ECU 100, so that the ECU 100 can detect that the brake is applied. The ECU 100 stops the cruise control when it receives a signal from the brake sensor 203 or 205 during the cruise control.
The two-wheel motor vehicle 1 has a display 206 that displays an execution state or a non-execution state of the cruise control.
The cruise control starts when the rider inputs the switch 206a. The cruise control is executed by the ECU 100 as follows. The ECU 100 stores in the storage device 210 the vehicle speed at the time when the switch 206a is input as a target vehicle speed. Then, the opening of the throttle valve 71 is adjusted so that the vehicle speed detected by the vehicle speed sensor 201 becomes the target vehicle speed. Specifically, the electric motor 72 is controlled so that the vehicle speed becomes the target vehicle speed. In this manner, the cruise control is enabled, and the two-wheel motor vehicle 1 may executes a constant running speed at the target vehicle speed set by the operator.
As shown in
Additionally, a lock mechanism that maintains an open state of the throttle grip 60 may be provided so that the throttle grip 60 is maintained at a predetermined opening (a fixed opening) during the cruise control. In such a case, in
As described above, according to this embodiment, cruise control can be executed.
In this embodiment, the two-wheel motor vehicle 1 is configured to prevent excessive engine braking without operation of the throttle grip 60 by the rider at a gear down shift during running.
The two-wheel motor vehicle 1 according to the present embodiment includes the throttle valve system 70 similar to that of the first embodiment. In the following descriptions, the same components as those of the first and second embodiments are assigned the same reference numerals and symbols, and their explanations are omitted.
A switch 215 is disposed adjacent to the throttle grip 60. The switch 215 is a switch that executes an ON/OFF operation of the engine brake control described later. When the switch 215 is turned ON, the engine brake control is executed, and when the switch is turned OFF, the engine brake control is not executed. Additionally, the two-wheel motor vehicle 1 according to the present embodiment includes a display 216 that displays an OFF/OFF state of the engine brake control.
The engine brake control is executed by the ECU 100 as follows. Particularly, ECU 100 compares the rotation speed of the front wheel 5 and the rotation speed of the rear wheel 7 in a case where the shift pressure increases as shown in
As described before, in the two-wheel motor vehicle 1 according to this embodiment, the spring 51 is provided between the protrusion 77 extending from the valve shaft 73 of the throttle valve 71 and the lever pulley 54 (refer to
Incidentally, there could be a case that the wheel diameter is different between the front wheel 5 and the rear wheel 7. Thus, in comparing the rotational speed of the front wheel 5 and that of the rear wheel 7, the difference of the wheel diameter between these wheels is preferably considered. For example, the rotational speed may be defined as a rotation angle per unit time (rad/s), and moreover, compensation may be made in accordance with the wheel diameter. Also, the above predetermined value, which is a standard speed difference in executing the engine brake control, may be set to a value previously determined in consideration of the difference of the wheel diameter between the front wheel 5 and the rear wheel 7.
As described above, in a straddle type vehicle having an electronic throttle valve, various advanced controls can be achieved compared to conventional vehicles as illustrated in the first to third embodiments according to the present invention.
Straddle type vehicles according to the present invention are not limited to two-wheel motor vehicles. Other than two-wheel motor vehicles, the invention is also applicable to, for example, four-wheeled buggies (ATV: All Terrain Vehicle) and snowmobiles.
While several embodiments have been described in connection with the figures hereinabove, the invention is not limited to these embodiments, but rather can be modified and adapted as appropriate. Thus, it is to be clearly understood that the above description was made only for purposes of an example and not as a limitation on the scope of the invention as claimed herein below.
Number | Date | Country | Kind |
---|---|---|---|
2007-241056 | Sep 2007 | JP | national |
2007-333496 | Dec 2007 | JP | national |
2008-111467 | Apr 2008 | JP | national |