JP4249513B2 - Motorcycle headlamp device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a headlamp device for a motorcycle capable of suitably adjusting irradiation range of a headlamp for always securing wide visual field in cornering during night travel by accurately measuring real vehicle body bank angles corresponding to riding attitude of a rider. <P>SOLUTION: This device is provided with the headlamp 12 irradiating front of the vehicle body 2, a luminous intensity distribution adjusting mechanism 16 changing the irradiation range A of the headlamp 12, a bank angle detecting means 19 detecting bank angles &theta; of the vehicle body 2 from rotation angler velocity &omega; around a vertical axis of the vehicle body 12 , vehicle speed v and lateral acceleration a2 of the vehicle body 2, and a luminous intensity distribution control means 20 adjusting the irradiation range A to irradiate distance of inside of a cornering direction during cornering travel by controlling the luminous intensity distribution adjusting mechanism 16 based on detected bank angles &theta;. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a motorcycle headlamp device that provides a wide front field of view even during cornering during night driving.
[0002]
[Prior art]
When a motorcycle is traveling at a certain speed, the traveling direction is changed by banking the vehicle body and cornering. However, the headlamps of conventional motorcycles are fixed to the vehicle body, and when the vehicle body is banked, the optical axis of the headlamps is also tilted accordingly. The light distribution of the headlight to the inside of the direction is reduced, and the field of view ahead of the traveling direction is narrowed.
[0003]
That is, when the motorcycle goes straight, the headlamp illumination range (light distribution) A is an illumination range that extends in the left-right direction parallel to the horizontal line H, as shown in FIG. For example, as shown in FIG. 18, when the traveling direction is changed to the left side indicated by the arrow P along the curved lane 50 of the motorcycle, the vehicle body is banked on the left side and cornering is performed. Compared to the case, it tilts to the left. As a result, the irradiation range A of the headlamp to the inner side of the turning direction in which the rider's line of sight faces (the portion B surrounded by a broken circle in the figure), that is, the area to be the traveling destination is reduced. The field of view is narrowed.
[0004]
Therefore, the present applicant has previously proposed a headlamp device that can solve the above-described problems (see Patent Document 1).
[0005]
[Patent Document 1]
JP 2001-347777 A
[0006]
In this headlamp device, the rotation control means controls the drive unit based on the bank angle of the vehicle body detected by the bank angle detection means, and the lens and the light emitter of the headlamp body are arranged around the central axis of the bank lamp. The direction is rotated by an angle corresponding to the size of the bank angle in the opposite direction. In this headlamp device, the cornering during night driving increases the light distribution of the headlamp to the inside in the turning direction where the rider's line of sight faces, thereby ensuring a wide field of view.
[0007]
[Problems to be solved by the invention]
In the headlamp device, the bank angle detection means calculates the bank angle based on the rotational angular velocity in the horizontal plane of the vehicle body and the vehicle speed, and this bank angle balances gravity and centrifugal force by the rider and the vehicle body. It is estimated based on that. Therefore, as shown in FIG. 16B, the calculated bank angle is a riding posture called lean with which the rider 51 is maneuvered by being positioned on the vertical axis VC of the vehicle body 2 of the motorcycle 1. That is, it is a precondition that gravity by the rider 51 is not applied in the left-right direction of the vehicle body 2.
[0008]
However, when cornering with the vehicle body 2 being banked, the rider 51 is maneuvering in any of the leaning positions shown in FIG. 16 (a), lean-in (c), or hang-on (d). In any of these riding postures, the rider 51 is shifted to the left or right with respect to the vertical axis VC of the vehicle body 2. As a result, the overall center of gravity G of the vehicle body 2 and the rider 51 is deviated from the vertical axis VC of the vehicle body 2. Accordingly, the bank angle calculated from the balance between gravity and centrifugal force acting on the overall center of gravity G by the rider 51 and the vehicle body 2 is a value deviated from the true bank angle of the vehicle body 2 itself. On the other hand, since the irradiation range of the headlamp is preferably rotated in the opposite direction to the bank angle by an angle corresponding to the true bank angle of the vehicle body 2, the bank angle calculated as described above includes an error. If so, the irradiation range of the headlamp may not be suitable for obtaining a wide field of view.
[0009]
The present invention has been made in view of the above circumstances, and is capable of accurately obtaining the true bank angle of the vehicle body regardless of the rider's riding posture, and always ensuring a wide field of view when cornering during night driving. An object of the present invention is to provide a motorcycle headlamp device capable of appropriately changing the irradiation range of the motorcycle.
[0010]
[Means for Solving the Problems]
  In order to achieve the above-described object, a motorcycle headlamp device according to a first configuration of the present invention includes a headlamp that irradiates the front of a vehicle body, a light distribution adjustment mechanism that changes an irradiation range of the headlamp, A rotational angular velocity and a vehicle speed around the vertical axis of the vehicle body;From the above, find the composite bank angle when the rider's center of gravity is located on the vertical axis of the vehicle body.Acceleration in the left-right direction of the vehicle bodyBased on the above, the composite bank angle was corrected to take into account the case where the rider's center of gravity deviates from the vertical axis of the vehicle bodyBank angle detection means for detecting a vehicle body bank angle, and a light distribution for controlling the light distribution adjustment mechanism based on the detected vehicle body bank angle and changing the irradiation range so as to irradiate the far side inside the turning direction when turning. Control means.
[0011]
According to the motorcycle headlamp device, the bank angle detecting means obtains the combined bank angle of the vehicle body and the rider, obtained from the rotational angular velocity around the vertical axis of the vehicle body and the vehicle speed, in the horizontal direction of the vehicle body. Therefore, the true bank angle can be accurately detected regardless of the rider's driving posture. The light distribution control means controls the light distribution adjustment mechanism based on the detected vehicle body bank angle so as to irradiate the inside of the turning direction, that is, the far side of the turning center side when turning, so that the irradiation range of the headlamp (light distribution) ). For example, the light distribution adjusting mechanism rotates the irradiation range of the headlamp around the central axis of the headlamp by an angle corresponding to the bank angle in a direction opposite to the banked direction. Thereby, the light distribution of the headlamp increases inward in the traveling direction in which the rider's line of sight faces when turning, and a wide field of view can be secured.
[0012]
  In the embodiment of the present invention, the bank angle detection means is defined by the following equation, where the rotational angular velocity is ω, the vehicle speed is v, the lateral acceleration is a2, the combined bank angle is δ, and the gravitational acceleration is g. The vehicle body bank angle θ can be obtained in consideration of the case where the center of gravity deviates from the vertical axis of the vehicle body.
  θ = δ + Sin ^-1 (A2 · Cos (δ / g))
  Where δ = Sin ^-1 (V · ω / g)
[0013]
  The bank angle detection device for a motorcycle according to the present invention acquires the rotational angular velocity ω around the vertical axis of the vehicle body and the vehicle speed v, and the rider's center of gravity is located on the vertical axis of the vehicle body from the rotational angular velocity ω and the vehicle speed v. Bank angle calculation means for outputting a composite bank angle δ when positioned, bank angle composite acceleration calculation means for outputting a composite acceleration a1 applied in the composite bank angle direction based on the composite bank angle δ, and a lateral direction of the vehicle body And when the rider's center of gravity deviates from the vertical axis of the vehicle body based on the combined acceleration a1 and acceleration a2, a deviation angle η between the combined bank angle δ and the vehicle body bank angle θ is output. Angle calculating means, and bank angle correcting means for outputting the vehicle body bank angle θ based on the composite bank angle δ and the deviation angle η.
[0014]
  A motorcycle headlamp device according to a second configuration of the present invention includes a headlamp that irradiates the front of a vehicle body, a light distribution adjusting mechanism that changes an irradiation range of the headlamp, and a rotation of the vehicle body about a vertical axis. Based on the angular velocity, the vehicle speed, and the lateral acceleration of the vehicle body, bank angle detection means for detecting the vehicle body bank angle, and the light distribution adjustment mechanism are controlled based on the detected vehicle body bank angle. A light distribution control means for changing the irradiation range so as to irradiate far away. The light distribution control means includes, in addition to the vehicle body bank angle, (1) a relative relationship between the vehicle speed and the vehicle body bank angle, (2 ) Relative relationship between turning radius and vehicle speed, or ( 3 ) The light distribution adjusting mechanism is controlled based on the relative relationship between the turning radius and the vehicle body bank angle.
[0015]
  When configured in this way, it is possible to determine whether the travel mode of the vehicle body is, for example, normal travel, sport travel, or slow travel, by any of the three relative relationships. The irradiation range can be automatically and appropriately corrected according to the driving mode. For example, during sports running where the rider tends to gaze ahead farther than normal travel, the irradiation range is rotated more than normal travel, and during slow travel, the irradiation range is rotated smaller than during normal travel.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a side view showing a motorcycle equipped with a headlamp device according to a first embodiment of the present invention. The motorcycle 1 has a front wheel 5 attached to a front fork 4 pivotally supported by a head pipe 3 at the front end of a body frame 2, and a swing arm 7 pivotally supported by a swing arm bracket 6 at the lower center of the body frame 2. The rear wheel 8 is driven by the engine 9 attached to the wheel 8 and attached to the lower center of the body frame 2, and is steered by the handle 10 fixed to the upper end of the front fork 4.
[0017]
A headlamp 12 constituting the headlamp device 11 is attached to the front fork 4 via a bracket 13. As shown in a block diagram in FIG. 3, the headlamp device 11 includes the headlamp 12, a driving machine 18 and an encoder (rotational position detecting means) 29 provided on the headlamp 12, a bank angle detecting means 19, an arrangement. The light control means 20 and the like are included.
[0018]
FIG. 2 is a longitudinal sectional view of the headlamp 12. In the headlamp 12, a lens 23 is disposed opposite to a front surface of a bulb 22 that is a light emitter provided in the lamp case 21, and the bulb 22 and the lens 23 are rotatable around a central axis C thereof. Thus, an irradiation range variable mechanism 17 is configured. That is, the lamp case 21 is attached to the annular rim 14 on the front side with a screw body (not shown), and a hook-like reflector 24 disposed so as to surround the bulb 22 is attached to the rim 14 with a hook and screw body (not shown). A lens 23 is rotatably supported on a rotation shaft 26 of a lens column 25 attached to the reflector 24. A rotating base 27 is disposed at the center of the reflector 24 so as to be coaxial with the lens 23. The valve 22 attaches the valve bracket 31 to the center of the rotating base 27, that is, on the central axis C. Is attached through.
[0019]
The rotary base 27 is rotatably supported by a fixed base 28 on the outer side thereof, and the fixed base 28 is supported by the reflector 24 via a bracket 58. The rotation base 27 and the outer peripheral portion of the lens 23 are connected by an arm 38. Thus, the bulb 22 and the lens 23 are rotatable relative to the lamp case 21, the rim 14 and the retractor 24. A front cover 30 is attached to the front surface of the retractor 24. A power cord 33 is connected to the valve socket 37.
[0020]
An arcuate driven gear 32 is provided on the outer peripheral portion of the rotation base 27 over an angular range of approximately 180 degrees. On the other hand, a driving machine 18 that rotates the rotation base 27 is provided on the outer peripheral portion of the fixed base 28. It is attached. This drive machine 18 consists of a DC motor, for example. In addition, an encoder 29 for detecting the rotation angle of the rotation base 27, that is, the rotation angle of the lens 23 and the valve 22, is provided on the outer periphery of the fixed base 28 at a position away from the drive unit 18 in the circumferential direction. ing. The rotation of the drive machine 18 is transmitted to the rotation base 27 via the circular drive gear 34 and the driven gear 32, whereby the lens 23 is rotationally driven together with the valve 22. Therefore, the driver 18 and the irradiation range variable mechanism 17 constitute a light distribution adjusting mechanism 16.
[0021]
The encoder 29 is connected to a circular transmission gear 35 that meshes with the driven gear 32 and rotates, thereby detecting the rotation amount (quantity) or rotation angle of the driving machine 18, and the rotation of the lens 23 and the valve 22 based on this. Detect the angle. The transmission gear 35 has the same number of teeth as that of the drive gear 34 and rotates by the same amount as the drive gear 34. The fixed base 28 is provided with a limit switch 36 for detecting excessive rotation exceeding the set angle range of the rotary base 27 and stopping the driving machine 18. The power cords or signal cords of the driving machine 18, encoder 29 and limit switch 36, and the power cord 33 of the bulb 22 are led out from a cord lead-out hole (not shown) provided in the lamp case 21.
[0022]
The lens 23 and the bulb 22 have a general irradiation range property that becomes an irradiation range (light distribution) A that spreads left and right along the horizontal line H as shown in FIG. . The irradiation range is provided by, for example, providing a light adjusting plate for adjusting the light divergence direction on the bulb 22 and integrally forming a large number of cylindrical lens elements and Fresnel lens elements on the front surface or rear surface of the lens 23. Can do. Although the lens 23 is a scattering lens, it is not particularly limited to this.
[0023]
The bank angle detection means 19 in FIG. 3 is a means for detecting the bank angle θ of the vehicle body of the motorcycle 1 (FIG. 1), that is, the inclination angle in the left-right direction with respect to the vertical line of the vehicle body. The bank angle δ obtained from the rotational angular velocity ω around the vertical axis and the vehicle speed v is corrected based on the lateral acceleration a2 of the vehicle body to calculate the true vehicle bank angle θ corresponding to the rider's riding posture. The acceleration a2 in the left-right direction is generated when the overall center of gravity of the vehicle body and the rider is shifted in the left-right direction from the vertical axis of the vehicle body due to a change in the riding posture of the rider.
[0024]
The bank angle detection means 19 of this embodiment includes a gyro 39 that measures the rotational angular velocity ω on the vehicle body, a speedometer 40 that measures the vehicle speed v, and an acceleration sensor 44 that detects acceleration a2 in the left-right direction of the vehicle body. And. Here, the installation position of the acceleration sensor 44 is preferably in the vicinity of the entire center of gravity of the vehicle body and the rider on the vertical axis of the vehicle body. The external forces acting on the acceleration sensor 44 are gravity and centrifugal force. If the entire center of gravity deviates from the installation position of the acceleration sensor 44 due to the difference in rider's weight and the riding posture, there is an error in the detection of the centrifugal force by the acceleration sensor 44. Arise. That is, because the centrifugal force is inversely proportional to the turning radius R (FIG. 5), a difference in the turning radius occurs between the acceleration sensor 44 and the entire center of gravity due to the positional deviation between the acceleration sensor 44 and the entire center of gravity. However, since the positional deviation between the acceleration sensor 44 on the vehicle body and the entire center of gravity is smaller than the turning radius, the detection error of the centrifugal force by the acceleration sensor 44 can be ignored.
[0025]
The bank angle detecting means 19 further includes a bank angle calculating means 41 for calculating a composite bank angle δ which is a bank angle of a composite system of the vehicle body and the rider from the measured rotational angular velocity ω and vehicle speed v, and the calculated composite bank. Based on the angle δ, the bank angle direction combined acceleration calculating means 45 for calculating the combined acceleration a1 applied in the bank angle δ direction, and the combined acceleration a1 applied in the combined bank angle δ direction and the left and right direction of the vehicle body detected by the acceleration sensor 44 Based on the acceleration a2, the bank angle deviation calculating means 46 for calculating the deviation angle η of the combined bank angle δ calculated from the bank angle calculating means 41 with respect to the true vehicle body bank angle θ, and the composition calculated by the bank angle calculating means 41 Bank angle correction means 47 for correcting the bank angle δ by the deviation angle η calculated by the bank angle deviation calculation means 46 to obtain the true vehicle body bank angle θ. The
[0026]
Of the bank angle detecting means 19, the bank angle calculating means 41, bank angle direction combined acceleration calculating means 45, bank angle deviation calculating means 46 and bank angle correcting means 47 are provided in a control unit 42 for controlling the operation of the motorcycle. Built in. The control unit 42 further includes a mode memory 48 in which a travel mode based on the relative relationship between the vehicle body bank angle and the vehicle speed is stored as a mode table, the obtained composite bank angle δ, the measured vehicle speed v, and the mode memory 48. The travel mode determination means 49 for comparing the mode table with the travel mode determination means 49 and the correction value α output as the determination result of the travel mode determination means 49 corrects the bank angle θ of the bank angle correction means 47. Based on the bank angle correction means 52 and the corrected bank angle θ1, the driver 18 of the light distribution adjusting mechanism 16 is controlled, and the lens 23 is moved in the opposite direction to the banked direction by an angle corresponding to the magnitude of the correction bank angle θ1. A light distribution control means 20 for rotation is incorporated. Details of these will be described later.
[0027]
As shown in FIG. 1, the gyro 39 and the acceleration sensor 44 are attached to the rear portion of the vehicle body frame 2, the speedometer 40 is disposed above the headlamp 12, and the control unit 42 is a seat 43 (FIG. 1) in the center of the vehicle body. ) Is located at the bottom.
[0028]
The bank angle θ is detected by the bank angle detecting means 19 as follows. First, the bank angle calculation means 41 calculates the composite bank angle δ as follows. That is, the vehicle speed of the motorcycle 1 (FIG. 1) during cornering measured by the speedometer 40 of FIG. 3 is v, the rotational angular velocity around the vehicle body vertical axis VC measured by the gyro 39 is ω, the turning radius is R, When the gravitational acceleration is g, as shown in FIGS. 4 and 5, the rotational angular velocity ω0 in the horizontal plane of the vehicle body is
ω = ω0 · cosδ (1)
And the centrifugal force f applied to the vehicle body is expressed as follows:
f = m · v · v / R (2)
It is. The mass is the total mass of the car body and the rider.
ω0 is
ω0 = v / R (3)
Therefore, when substituting equation (3) into equation (2), the centrifugal force f is
f = m · v · ω0 (4)
It becomes.
[0029]
Further, when the composite bank angle δ is between the centrifugal force f applied to the vehicle body and the gravity m · g,
tan δ = f / (m · g) (5)
Therefore, substituting (4) into (5),
tan δ = m · v · ω 0 / (m · g)
= V · ω0 / g (6)
It becomes. Furthermore, equation (6) substitutes ω0 of equation (1),
tan δ = v · ω / (g · cos δ) (7)
It becomes. From equation (7)
sin δ = v · ω / g (8)
From this, the composite bank angle δ is
δ = sin^-1(V · ω / g) (9)
It becomes. The bank angle calculation means 41 in FIG. 3 inputs the rotational angle speed ω measured by the gyro 39 in FIG. 3 and the vehicle speed v measured by the speedometer 40 into the equation (9), thereby obtaining the composite bank angle δ. calculate.
[0030]
The composite bank angle δ calculated by the bank angle calculation means 41 described above is for the rider 51 operating in the riding posture positioned on the vertical axis VC (FIG. 6) of the motorcycle 1. It is necessary to correct according to the difference. Next, control processing for correcting the calculated composite bank angle δ to obtain the true vehicle body bank angle θ will be described. Since the acceleration in the vertical direction is the gravitational acceleration g, as shown in FIG. 6, the combined acceleration a1 applied in the direction of the combined bank angle δ is
a1 = g / cosδ (10)
The bank angle direction combined acceleration calculating unit 45 in FIG. 3 calculates the combined bank angle δ direction inputted by the bank angle calculating unit 41 by substituting the combined bank angle δ into the equation (10). The acceleration a1 is calculated and output.
[0031]
The deviation angle η between the composite bank angle δ and the true vehicle body bank angle θ shown in FIG.
sin η = a2 / a1 (11)
From the relationship
η = sin^-1(A2 / a1) (12)
The bank angle deviation calculation means 46 in FIG. 3 substitutes the combined acceleration a1 and the lateral acceleration a2 of the vehicle body respectively input from the bank angle direction combined acceleration calculation means 45 and the acceleration sensor 44 into the equation (12). To calculate the deviation angle η.
[0032]
As is apparent from FIG. 6, the true vehicle bank angle θ is
θ = δ + η (13)
Therefore, the bank angle correction means 47 in FIG. 3 substitutes the composite bank angle δ and the deviation angle η respectively inputted from the bank angle calculation means 41 and the bank angle deviation calculation means 46 into the equation (13). By calculating, the true body bank angle θ obtained by correcting the calculated composite bank angle δ according to the rider's riding posture is obtained.
[0033]
In addition to the rider's riding posture, there are three travel modes: a normal travel mode N that travels at a normal speed, a sports travel mode S that travels at a high speed, and a slow travel mode J that travels at a low speed. It can be roughly classified, and it is preferable to change the irradiation range of the headlamp according to these three types of travel modes. Therefore, in order to correct the vehicle body bank angle θ according to the travel mode, the mode memory 48 of the control unit 42 stores the vehicle speed v for the three travel modes S, N, and J as shown in FIG. A mode table of the relative relationship with the composite bank angle δ is stored in advance. The traveling mode determination means 49 in FIG. 3 determines the traveling mode while comparing and comparing the vehicle speed v and the combined bank angle δ input from the speedometer 40 and the bank angle calculation means 41 with the mode table. As a determination result, a correction value α set in advance for each travel mode is output. As the correction values, the sport driving mode S is set to double, the normal driving mode N is set to 1.7 times, and the slow driving mode J is set to 1 to 1.5 times. The bank angle correction means 52 multiplies the true bank angle θ by the correction value α, and outputs a corrected bank angle θ · α = θ1.
[0034]
Next, the operation of the motorcycle headlamp device 11 will be described. For example, when a motorcycle running at night corners to the left, the bank angle correction means 52 corrects the true vehicle bank angle θ output from the bank angle correction means 47 based on the correction value α, and the light distribution control means 20 Controls the drive unit 18 based on the corrected composite bank angle θ1. As a result, by rotating the lens 23 and the bulb 22 in the direction opposite to the banking direction of the vehicle body, the irradiation range (light distribution) A is rotated in the reverse direction by an angle equal to the correction bank angle θ1. When the rotation amount of the driving machine 18 detected by the encoder 29 reaches a value corresponding to the magnitude of the correction bank angle θ1, the light distribution control means 20 stops the driving machine 18 in response to this. As a result, the irradiation range A rotates in an opposite direction to the banked direction by an angle corresponding to the size of the vehicle body bank angle θ.
[0035]
FIG. 8 is a graph showing the relationship between the corrected vehicle body bank angle θ1 and the rotation angle β of the irradiation range. The upper limit value of the rotation angle β of the lens 23 and the bulb 22 is preferably 55 ° or less. At angles exceeding 55 °, the left and right side portions A1 of the distribution of the irradiation range A in FIG. , The irradiation to the left front when banking to the left during cornering or to the right front when banking to the right becomes insufficient.
[0036]
Thus, when the motorcycle changes its traveling direction to the left side indicated by the arrow P along the curved lane 50, for example, as shown in FIG. 9, the irradiation range A of the headlamp device 11 is the same as when traveling straight as shown in FIG. From the state extending left and right along the horizontal line H, the state is slightly inclined upward as shown in FIG. As a result, the light distribution to the inside of the turning direction where the rider's line of sight faces (portion B surrounded by a broken-line circle in the figure) is much larger than in the conventional example shown in FIG. 18, and the field of view is widened accordingly. . Depending on the shape of the irradiation range A, the irradiation range A may be rotated by an angle corresponding to the size of the vehicle body bank angle θ in the same direction, not in the opposite direction to the banked direction, so that the rider's line of sight is turned. The light distribution inside may be increased.
[0037]
In addition, in this embodiment, the lens 23 and the valve 22 are rotated according to the true vehicle body bank angle θ obtained by correcting the combined bank angle δ obtained by the bank angle calculating means 41 of FIG. 3 according to the rider's riding posture. Therefore, regardless of the riding posture of the rider, the irradiation range of the headlamp can always be set appropriately. Further, in this embodiment, the rotation angle β of the irradiation range A is set according to the bank angle θ · α obtained by correcting the true vehicle bank angle θ with the correction value α corresponding to the travel mode. The irradiation range A of the headlamp device 11 to the portion B where the rider's line of sight faces is further increased. For example, in the sport running mode S, the rider gazes ahead further, so the irradiation range of the headlamp is changed to match the gaze range. That is, the irradiation range A can be adjusted more appropriately according to the operating state.
[0038]
Further, in this embodiment, as shown in FIG. 8, the range where the correction bank angle θ1 is up to 3.5 ° left and right is a dead zone, and the irradiation range A is not rotated according to the correction bank angle θ1 in this angle range. ing. For this reason, even if the correction bank angle θ1 fluctuates finely when traveling straight or running on a gentle curve, the irradiation range A does not change, and it becomes a calm irradiation range state, so that the rider does not feel uncomfortable.
[0039]
3 corrects the composite bank angle δ calculated by the bank angle calculation means 41 in accordance with the ride posture of the rider, so that the bank angle θ has a simple configuration. Although it can obtain | require with high precision, you may make it measure not only this but a bank angle from the distance by calculating | requiring the distance from the fixed location of the upper part of a vehicle body to the ground, for example with an ultrasonic wave etc. . In the above-described embodiment, the true vehicle bank angle θ is automatically corrected according to the driving mode, so that the headlamp irradiation range is more appropriately corrected according to the skill level and driving state of the rider. However, the means for correcting the irradiation range of the headlamp in this traveling mode may be excluded. In that case, the irradiation range A is rotated in the direction opposite to the vehicle body bank angle θ by, for example, an angle of 1 to 3θ, preferably 1.7 to 2θ, according to the vehicle body bank angle θ.
[0040]
In the above embodiment, the lens 23 and the valve 22 in FIG. 2 are rotated by an angle corresponding to the bank angle θ. For example, when the reflector 24 has light distribution, the reflector 24 You may make it rotate.
[0041]
FIG. 10 is a block diagram showing a circuit configuration of the main part of the headlamp device according to the second embodiment of the present invention, which is a partial modification of FIG. 3 which is a block diagram of the schematic configuration of the first embodiment. is there. That is, this embodiment is different from FIG. 3 in that the mode memory 53 in the control unit 42 indicates that the turning radius R and the vehicle speed v for the three driving modes S, N, and J are as shown in FIG. The relative mode table is stored in advance, and the travel mode determination means 54 in FIG. 10 determines the travel mode by comparing the turning radius R and the vehicle speed with the mode table in the mode memory 53. Configuration only. In this embodiment, the three types of travel modes S, N, and J are determined from the relative relationship between the turning radius R and the vehicle speed v.
[0042]
The traveling mode determination means 54 obtains the turning radius R based on the input composite bank angle δ and rotational angular velocity ω. This turning radius R is
R = v / ω 0 = v · cos δ / ω (14)
Can be obtained from Further, the traveling mode determination means 54 determines the traveling modes S, N, and J from the obtained relative relationship between the turning radius R and the vehicle speed v, and the determination result is preset for each speed state. The correction value α is output. The following operations are the same as those in the first embodiment.
[0043]
Furthermore, in the third embodiment of the present invention, as shown in FIG. 12, the mode memory 53 of FIG. 10 stores a relative relationship between the turning radius R and the composite bank angle δ for the three travel modes S, N, and J. Are stored in advance, and the traveling mode determination means 54 compares the turning radius R and the combined bank angle δ with the mode table of the mode memory 53 to determine the traveling mode. That is, in this embodiment, the three types of travel modes S, N, and J are determined from the relative relationship between the turning radius R and the composite bank angle δ, and the vehicle body bank angle is the same as in the first and second embodiments. θ is automatically corrected according to the driving mode.
[0044]
FIG. 13 is a block diagram showing a circuit configuration of a headlamp device according to the fourth embodiment of the present invention. In this embodiment, bank angle / direction detecting means 59 for detecting the vehicle body bank angle and the bank direction is provided. The bank angle / direction detecting means 59 includes a speedometer 40, a sensor unit 64 including two acceleration detectors for detecting accelerations ay and az applied in the horizontal direction and vertical direction of the vehicle body, and both detected accelerations ay, Based on az and the acceleration of gravity g, a mechanical bank angle calculating means 65 for calculating a dynamic bank angle φ (FIG. 14) with respect to the wheel contact point at the installation position of the sensor unit 64, and a detected mechanical bank angle An error calculating means 66 for calculating an error Δθ (FIG. 14) between φ and a geometric bank angle θ which is a true vehicle body bank angle, and a bank direction detection for detecting the bank direction based on the detected lateral acceleration ay. Means 67 and a geometric bank angle for correcting the detected mechanical bank angle φ based on the error Δθ calculated by the error calculating means 66 to calculate the geometric bank angle θ of the vehicle body Out and a means 68.
[0045]
Here, like the acceleration sensor 44 in the first embodiment, the sensor unit 64 is on the vertical axis VC of the vehicle body shown in FIG. It is installed at the rear of the car body. Therefore, the mechanical bank angle calculating means 65 (FIG. 13) calculates the dynamic bank angle φ with respect to the ground contact point 80 of the rear wheel 8. The acceleration sensor 64 may be installed in the front part of the vehicle body. In this case, the mechanical bank angle φ with respect to the ground contact point of the front wheel 5 is calculated.
[0046]
  The detection of the geometric bank angle (body bank angle) θ by the bank angle / direction detection means 59 of FIG. 13 is performed as follows. As shown in FIG. 14, the resultant acceleration a applied to the vehicle body by the accelerations ay and az in the vehicle left-right direction and the vertical direction detected by the sensor unit 64 as an acceleration detector
  a = √ (ay ² + Az ² ) (15)
It becomes. Since the vertical acceleration applied to the vehicle body is the acceleration of gravity g, the mechanical bank angle φ represented by the line segment connecting the ground contact point 80 of the rear wheel 8 and the total center of gravity G of the vehicle body and the rider is
  φ = | cos^-1(G / a) | (16)
13 calculates the composite acceleration a by substituting both accelerations ay and az input from the sensor unit 64 into the equation (15), and further calculates the composite acceleration a ( By calculating by substituting into the equation (16), the mechanical bank angle φ is calculated and output. The bank angle φ of + −, that is, the bank direction is determined by the direction of the acceleration ay in the left-right direction.
[0047]
The error Δθ between the mechanical bank angle φ and the geometric bank angle θ due to the deviation of the ground contact point 80 of the rear wheel 8 in FIG.
Δθ = | tan^-1(Ay / az) | (17)
13 calculates the mechanical bank angle φ and the geometric bank angle θ by substituting the two accelerations ay and az input from the sensor unit 64 into the equation (17). Is calculated and output.
[0048]
Therefore, the geometric bank angle (true body bank angle) θ is
θ = φ + Δθ (18)
It becomes. Here, the + − of the dynamic bank angle φ, that is, the bank direction, is detected by the bank direction detecting means 67 from the direction of the acceleration ay in the left-right direction. Since the wheel contact point shifts to the inside of the bank when the vehicle body is banked, the lateral acceleration ay is normally generated toward the inside of the bank. Therefore, it is determined that the direction in which the lateral acceleration ay is directed is the bank direction.
[0049]
Further, in this embodiment, in order to correct the geometric bank angle θ according to the normal running mode N, the sport running mode S, and the slow running mode J, the mode memory 55 of the control unit 42 has FIG. As shown in FIG. 5, a mode table of the relative relationship between the vehicle speed v and the dynamic bank angle φ for the three types of travel modes S, N, and J is stored. The traveling mode determination means 56 in FIG. 13 determines the traveling mode by comparing and comparing the vehicle speed v and the dynamic bank angle φ input from the speedometer 40 and the dynamic bank angle calculation means 65 with the mode table. As a result of the determination, a correction value α set in advance for each travel mode is output. Other configurations and operations are the same as those of the first embodiment shown in FIG.
[0050]
Further, in the fourth embodiment shown in FIG. 13, from the equations (2) and (5) (δ → φ), the turning radius R is calculated from the vehicle speed v and the mechanical bank angle φ as R = v · v / ( g · tanφ), the three travel modes S, N, and J can be determined based on the relative relationship between the turning radius R and the vehicle speed v, as shown in FIG. As shown in FIG. 12, the three travel modes S, N, and J can be determined based on the relative relationship between the turning radius R and the mechanical bank angle φ.
[0051]
As described above, in this embodiment, the vehicle body bank angle θ is calculated from the accelerations ay and az in the left and right directions and the vertical direction of the vehicle body detected by the sensor unit 64 that is an acceleration detector. There is no need to install a large and expensive gyro 39 for detecting the rotational angular velocity as in the case of the embodiment, and the vehicle body bank angle θ can be estimated by an inexpensive and small device.
[0052]
In each of the above embodiments, the correction of the bank angle θ according to the travel modes S, N, and J may be omitted.
[0053]
【The invention's effect】
As described above, according to the motorcycle headlamp device of the present invention, the true vehicle bank angle can be accurately detected, and the light distribution adjusting mechanism is controlled based on the detected vehicle bank angle, Since the irradiation range of the headlamp is changed so as to irradiate far away inside the turning direction during turning, the light distribution of the headlamp increases inward in the turning direction where the rider's line of sight faces when turning. It can be secured.
[Brief description of the drawings]
FIG. 1 is a side view of a motorcycle equipped with a headlamp device according to a first embodiment of the present invention.
FIG. 2 is a longitudinal sectional view of a headlamp in the headlamp device.
FIG. 3 is a block diagram showing a schematic configuration of the headlamp device.
FIG. 4 is a vector diagram showing a bank angle calculation method by a bank angle calculation means.
FIG. 5 is a plan view showing a turning radius and a vehicle speed when cornering a motorcycle.
FIG. 6 is a schematic front view showing a bank angle correcting method by bank angle correcting means.
FIG. 7 is a graph showing a relative relationship between a vehicle speed and a bank angle indicating a mode table stored in a mode memory.
FIG. 8 is a characteristic diagram showing a relationship between a rotation angle of an irradiation range and a bank angle.
FIG. 9 is a front view showing an irradiation range during cornering of the headlamp according to the present invention.
FIG. 10 is a block diagram showing a schematic configuration of a main part of a headlamp device according to a second embodiment of the present invention.
FIG. 11 is a graph showing a relative relationship between a turning radius and a vehicle speed indicating a mode table stored in a mode memory according to the embodiment;
FIG. 12 is a graph showing a relative relationship between a turning radius and a bank angle showing a mode table stored in a mode memory according to the third embodiment of the present invention.
FIG. 13 is a block diagram showing a schematic configuration of a headlamp device according to a fourth embodiment of the present invention.
FIG. 14 is a schematic front view showing the relationship between acceleration applied to the vehicle body, mechanical bank angle, and geometric bank angle.
FIG. 15 is a graph showing a relative relationship between a mechanical bank angle and a vehicle speed, showing a mode table stored in a mode memory in the embodiment;
FIGS. 16A to 16D are explanatory views schematically showing types of riding postures of riders' motorcycles.
FIG. 17 is a front view showing the irradiation range of the headlamp when the motorcycle goes straight.
FIG. 18 is a front view showing an irradiation range during cornering of a conventional headlamp.
[Explanation of symbols]
1 ... Motorcycle
2 ... Body frame (body)
12 ... Headlamp
16. Light distribution adjustment mechanism
19 ... Bank angle detection means
20: Light distribution control means
59 ... Bank angle / direction detection means
64 ... Sensor unit (acceleration detector)
65 ... Mechanical bank angle calculation means
68. Geometric bank angle calculation means
80 ... grounding point
A ... Irradiation range
ω ... Rotational angular velocity
v ... Vehicle speed
a2: Acceleration in the lateral direction of the vehicle body
θ ... Body bank angle
δ ... Composite bank angle
R ... turning radius
ay ... acceleration in the lateral direction of the vehicle body
az: acceleration in the vertical direction of the vehicle body
φ ... Mechanical bank angle

Claims (4)

A headlamp that illuminates the front of the car body,
A light distribution adjustment mechanism for changing the irradiation range of the headlamp;
The composite bank angle when the rider's center of gravity is located on the vertical axis of the vehicle body is obtained from the rotational angular velocity around the vertical axis of the vehicle body and the vehicle speed, and the composite bank angle is corrected based on the lateral acceleration of the vehicle body. Bank angle detection means for detecting the vehicle body bank angle in consideration of the case where the rider's center of gravity deviates from the vertical axis of the vehicle body,
A motorcycle headlamp device comprising: a light distribution control means for controlling the light distribution adjustment mechanism based on the detected vehicle body bank angle and changing the irradiation range so as to irradiate a far side inside the turning direction when turning. . In claim 1, the bank angle detection means has a rotational angular velocity as ω, a vehicle speed as v, a lateral acceleration as a2, a combined bank angle as δ, and a gravitational acceleration as g. A motorcycle headlamp device for obtaining a vehicle body bank angle θ in consideration of a case where the vehicle body is displaced from the vertical axis of the vehicle body.
θ = δ + Sin ^-1 (A2 · Cos (δ / g))
Where δ = Sin ^-1 (V · ω / g) A bank angle at which a rotational angular velocity ω around the vertical axis of the vehicle body and a vehicle speed v are acquired, and a combined bank angle δ is output when the center of gravity of the rider is positioned on the vertical axis of the vehicle body from the rotational angular velocity ω and the vehicle speed v. A calculation means;
Bank angle synthesized acceleration calculating means for outputting a synthesized acceleration a1 in the synthesized bank angle direction based on the synthesized bank angle δ;
When the lateral acceleration of the vehicle body a2 is acquired and the rider's center of gravity deviates from the vertical axis of the vehicle body based on the combined acceleration a1 and acceleration a2, the deviation angle η between the combined bank angle δ and the vehicle body bank angle θ Deviation angle calculating means for outputting
A bank angle detecting device for a motorcycle, comprising bank angle correcting means for outputting the vehicle body bank angle θ based on the composite bank angle δ and the deviation angle η. A headlamp that illuminates the front of the car body,
A light distribution adjustment mechanism for changing the irradiation range of the headlamp;
Bank angle detection means for detecting a vehicle body bank angle from a rotational angular velocity around the vertical axis of the vehicle body, a vehicle speed, and a lateral acceleration of the vehicle body;
A light distribution control means for controlling the light distribution adjustment mechanism based on the detected vehicle body bank angle and changing the irradiation range so as to irradiate the far side inside the turning direction when turning.
In addition to the vehicle body bank angle, the light distribution control means
(1) Relative relationship between vehicle speed and vehicle body bank angle, (2) Relative relationship between turning radius and vehicle speed, or ( 3 ) Control of light distribution adjusting mechanism based on relative relationship between turning radius and vehicle body bank angle. Motorcycle headlamp device.

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