JP5440299B2 - vehicle - Google Patents

Description

  The present invention relates to a vehicle having at least a pair of left and right wheels.

  In recent years, in view of the problem of depletion of energy resources, there has been a strong demand for fuel saving of vehicles. On the other hand, the number of vehicle owners is increasing due to the low price of vehicles, and one person tends to own one vehicle. Therefore, for example, there is a problem that energy is wasted when only one driver drives a four-seater vehicle. The most efficient way to save fuel consumption by reducing the size of the vehicle is to configure the vehicle as a one-seater tricycle or four-wheel vehicle.

  However, depending on the running state, the stability of the vehicle may decrease. Therefore, a technique for improving the stability of the vehicle during turning by tilting the vehicle body in the lateral direction has been proposed (for example, see Patent Document 1).

JP 2008-155671 A

  However, in the conventional vehicle, in order to improve the turning performance, the vehicle body can be tilted inward in the turning direction, but the operation of tilting the vehicle body is difficult and the turning performance is low. , Passengers may feel uncomfortable or anxious.

  The present invention solves the problems of the conventional vehicle, and calculates the value of the lateral acceleration component at the virtual lateral acceleration detection position from the detection values of a plurality of lateral acceleration sensors disposed at different positions in the front-rear direction. By calculating and controlling the tilt angle of the vehicle body so that the centrifugal force to the outside of the turn and gravity are balanced, the stability of the vehicle body can be maintained even during turning, and control stability can be improved. It is an object of the present invention to provide a highly safe vehicle that can be improved and that passengers do not feel uncomfortable, has a comfortable ride, and can realize a stable running state.

Therefore, in the vehicle according to the present invention, a vehicle body including a steering unit and a drive unit coupled to each other, and a wheel rotatably attached to the steering unit, the steering wheel steering the vehicle body, A wheel rotatably attached to the drive unit, and a drive wheel for driving the vehicle body, a tilting actuator device for tilting the steering unit or the drive unit in a turning direction, and a different position with respect to the front-rear direction. A plurality of lateral acceleration sensors that detect lateral acceleration acting on the vehicle body, and a control device that controls the tilt of the vehicle body by controlling the tilt actuator device. from the lateral acceleration a lateral acceleration sensor detects, the estimated lateral acceleration in the virtual lateral acceleration detection position than the vehicle body center or on the vehicle body center at the pivot is in the range of the side opposite to the steering wheel Out, the estimated lateral acceleration so that zero, to control the tilting of the vehicle body.

According to the first aspect, even in the initial turning, since there is no Rukoto affected acceleration of the turning direction and the reverse direction, the control stability is improved. Therefore, the occupant does not feel uncomfortable, has a good riding comfort, and can realize a stable traveling state.

According to the configuration of the second aspect , since the tilt of the vehicle body can be appropriately controlled even when the steered wheel turns in the traveling state where the steering wheel is on the rear side in the traveling direction, the occupant feels uncomfortable or feels uneasy. It wo n’t happen.

According to the configuration of the third aspect , since the accuracy of the detected value of the lateral acceleration is improved and the accuracy of the estimated lateral acceleration is also improved, the accuracy of the vehicle body control can be improved.

It is a figure which shows the structure of the vehicle in the 1st Embodiment of this invention. It is a figure which shows the structure of the link mechanism of the vehicle in the 1st Embodiment of this invention. It is a figure explaining the inclination operation | movement of the vehicle body at the time of turning driving | running | working in the 1st Embodiment of this invention. It is a block diagram which shows the structure of the vehicle body tilt control system in the 1st Embodiment of this invention. It is a figure explaining the locus | trajectory of each part of the vehicle body at the time of reverse turning in the 1st Embodiment of this invention. It is a figure which shows the model explaining the distance from the vehicle body center to a lateral acceleration sensor in the turning in the 1st Embodiment of this invention. It is a figure explaining the locus | trajectory of the virtual lateral acceleration sensor at the time of reverse turning in the 1st Embodiment of this invention. It is a flowchart which shows the operation | movement of the estimated acceleration calculation process in the 1st Embodiment of this invention. It is a flowchart which shows the operation | movement of the vehicle body control process in the 1st Embodiment of this invention. It is a figure which shows the back surface of the vehicle in the state in which the vehicle body in the 2nd Embodiment of this invention inclines. It is a figure explaining the locus | trajectory of the virtual lateral acceleration sensor at the time of the forward turn in the 3rd Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a diagram showing a configuration of a vehicle according to a first embodiment of the present invention, FIG. 2 is a diagram showing a configuration of a vehicle link mechanism according to the first embodiment of the present invention, and FIG. FIG. 4 is a block diagram showing a configuration of a vehicle body tilt control system according to the first embodiment of the present invention. In FIG. 1, (a) is a right side view and (b) is a rear view.

  In the figure, reference numeral 10 denotes a vehicle according to the present embodiment, which includes a main body 20 as a vehicle body drive unit, a riding unit 11 as a steering unit on which an occupant gets on and steer, and a center in the width direction in front of the vehicle body. The wheel 12F is a front wheel disposed as a steering wheel, and the left wheel 12L and the right wheel 12R are drive wheels disposed rearward as rear wheels. Further, the lean mechanism for leaning the vehicle body from side to side, that is, the lean mechanism, that is, the vehicle body tilt mechanism, the link mechanism 30 that supports the left and right wheels 12L and 12R, and the tilt that is the actuator that operates the link mechanism 30 And a link motor 25 as an actuator device. The vehicle 10 may be a three-wheeled vehicle with two front wheels on the left and right and one wheel on the rear, or may be a four-wheeled vehicle with two wheels on the left and right. As shown in the figure, a case will be described in which the front wheel is a single wheel and the rear wheel is a left and right tricycle.

  When turning, the angle of the left and right wheels 12L and 12R with respect to the road surface 18, that is, the camber angle is changed, and the vehicle body including the riding portion 11 and the main body portion 20 is inclined toward the turning inner wheel, thereby improving turning performance and the occupant. It is possible to ensure the comfort of the car. That is, the vehicle 10 can tilt the vehicle body in the lateral direction (left and right direction). In the example shown in FIGS. 1B and 2, the left and right wheels 12 </ b> L and 12 </ b> R are upright with respect to the road surface 18, that is, the camber angle is 0 degree. In the example shown in FIG. 3, the left and right wheels 12L and 12R are inclined rightward with respect to the road surface 18, that is, a camber angle is given.

  The link mechanism 30 includes a left vertical link unit 33L that supports a left wheel 12L and a left rotation driving device 51L including an electric motor that applies driving force to the wheel 12L, a right wheel 12R, and the wheel 12R. A right vertical link unit 33R that supports a right rotation drive device 51R composed of an electric motor or the like that applies a driving force to an upper side, and an upper horizontal link unit 31U that connects the upper ends of the left and right vertical link units 33L and 33R; The lower horizontal link unit 31D that connects the lower ends of the left and right vertical link units 33L and 33R, and the central vertical member 21 that has an upper end fixed to the main body 20 and extends vertically. The left and right vertical link units 33L and 33R and the upper and lower horizontal link units 31U and 31D are rotatably connected. Further, the upper and lower horizontal link units 31U and 31D are rotatably connected to the central vertical member 21 at the center thereof. When the left and right wheels 12L and 12R, the left and right rotational drive devices 51L and 51R, the left and right vertical link units 33L and 33R, and the upper and lower horizontal link units 31U and 31D are described in an integrated manner, The rotation drive device 51, the vertical link unit 33, and the horizontal link unit 31 will be described.

  The rotary drive device 51 as a drive actuator device is a so-called in-wheel motor, and a body as a stator is fixed to the vertical link unit 33 and is a rotor attached to the body so as to be rotatable. A rotating shaft is connected to the shaft of the wheel 12, and the wheel 12 is rotated by the rotation of the rotating shaft. The rotational drive device 51 may be a motor other than an in-wheel motor.

  The link motor 25 is a rotary electric actuator including an electric motor or the like, and includes a cylindrical body as a stator and a rotating shaft as a rotor rotatably attached to the body. The body is fixed to the main body portion 20 via the mounting flange 22, and the rotating shaft is fixed to the lateral link unit 31 </ b> U on the upper side of the link mechanism 30. The rotation axis of the link motor 25 functions as an inclination axis for inclining the main body 20 and is coaxial with the rotation axis of the connecting portion between the central vertical member 21 and the upper horizontal link unit 31U. When the link motor 25 is driven to rotate the rotation shaft with respect to the body, the upper horizontal link unit 31U rotates with respect to the main body 20 and the central vertical member 21 fixed to the main body 20, The link mechanism 30 operates, that is, bends and stretches. Thereby, the main-body part 20 can be inclined. Note that the rotation axis of the link motor 25 may be fixed to the main body 20 and the central vertical member 21, and the body may be fixed to the upper horizontal link unit 31U.

  The link motor 25 includes a lock mechanism (not shown) that fixes the rotation shaft to the body so as not to rotate. The lock mechanism is a mechanical mechanism, and preferably does not consume electric power while the rotation shaft is fixed to the body so as not to rotate. The lock mechanism can fix the rotation shaft so as not to rotate at a predetermined angle with respect to the body.

  The riding part 11 is connected to the front end of the main body part 20 via a connecting part (not shown). The connecting part may have a function of connecting the riding part 11 and the main body part 20 so as to be relatively displaceable in a predetermined direction.

  The boarding part 11 includes a seat 11a, a footrest 11b, and a windbreak part 11c. The seat 11 a is a part for a passenger to sit while the vehicle 10 is traveling. The footrest 11b is a part for supporting the occupant's foot, and is disposed on the front side (right side in FIG. 1A) and below the seat 11a.

  Further, a battery device (not shown) is disposed behind or below the riding section 11 or on the main body section 20. The battery device is an energy supply source for the rotation drive device 51 and the link motor 25. In addition, a control device, an inverter device, various sensors, and the like (not shown) are accommodated in the rear portion or the lower portion of the riding portion 11 or the main body portion 20.

  A steering device 41 is disposed in front of the seat 11a. The steering device 41 is provided with members necessary for steering such as a handle bar 41a as a steering device, a meter such as a speed meter, an indicator, and a switch. The occupant operates the handle bar 41a and other members to instruct the traveling state of the vehicle 10 (for example, traveling direction, traveling speed, turning direction, turning radius, etc.). As a steering device that is a means for detecting the required turning amount of the vehicle body requested by the occupant, other devices such as a steering wheel, a jog dial, a touch panel, and a push button are used instead of the handle bar 41a. It can also be used as

  The wheel 12F is connected to the riding section 11 via a front wheel fork 17 that is a part of a suspension device (suspension device). The suspension device is a device similar to a suspension device for front wheels used in, for example, general motorcycles, bicycles, and the like, and the front wheel fork 17 is, for example, a telescopic type fork with a built-in spring. As in the case of a general motorcycle, bicycle, etc., the wheel 12F as the steered wheel changes the steering angle in accordance with the operation of the handlebar 41a by the occupant, thereby changing the traveling direction of the vehicle 10.

  Specifically, the handle bar 41a is connected to the upper end of a steering shaft member (not shown), and the upper end of the front wheel fork 17 is connected to the lower end of the steering shaft member. The steering shaft member is rotatably attached to a frame member (not shown) included in the riding section 11 in a state where the steering shaft member is inclined obliquely so that the upper end is located behind the lower end.

  In the present embodiment, the vehicle 10 includes a first lateral acceleration sensor 44a and a second lateral acceleration sensor 44b. When the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are described in an integrated manner, they will be described as the lateral acceleration sensor 44. The lateral acceleration sensor 44 is a sensor composed of a general acceleration sensor, a gyro sensor, or the like. The lateral acceleration of the vehicle 10, that is, the lateral direction as the width direction of the vehicle body (the lateral direction in FIG. Detect acceleration.

  Since the vehicle 10 is stabilized by inclining the vehicle body toward the inside of the turn at the time of turning, the vehicle 10 is controlled so that the centrifugal force to the outside of the turn at the time of turning and the gravity are balanced by turning the vehicle body. By performing such control, for example, even if the road surface 18 is inclined in a direction perpendicular to the traveling direction (left and right direction with respect to the traveling direction), the vehicle body can always be kept horizontal. As a result, the vehicle body and the occupant are apparently always subjected to the gravity downward in the vertical direction, the uncomfortable feeling is reduced, and the stability of the vehicle 10 is improved.

  Therefore, in the present embodiment, in order to detect the lateral acceleration of the leaning vehicle body, the lateral acceleration sensor 44 is attached to the vehicle body, and feedback control is performed so that the output of the lateral acceleration sensor 44 becomes zero. As a result, the vehicle body can be tilted to an inclination angle at which the centrifugal force acting during turning and gravity are balanced. Further, even when the road surface 18 is inclined in a direction perpendicular to the traveling direction, the vehicle body can be controlled to have an inclination angle that makes the vehicle body vertical.

  The first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are disposed at different positions in the front-rear direction. In the example shown in FIG. 1A, the first lateral acceleration sensor 44 a is disposed in the windbreak portion 11 c and the second lateral acceleration sensor 44 b is disposed on the back surface of the riding portion 11. The first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are both located on the center in the width direction of the vehicle body, that is, on the vehicle center axis, from the viewpoint of accuracy of the lateral acceleration of the vehicle body to be detected. It is desirable.

  The first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are preferably disposed at the same height, that is, the distance from the road surface 18 is equal. Furthermore, it is desirable that both the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are attached to a sufficiently rigid member. Furthermore, it is desirable that both the first lateral acceleration sensor 44 a and the second lateral acceleration sensor 44 b are disposed above the link mechanism 30. Further, when the vehicle body is supported by a spring such as a suspension, it is desirable that both the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are arranged on a so-called “spring top”. Further, both the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b may be disposed between the axle of the front wheel 12F and the axles of the left and right wheels 12L and 12R as rear wheels. desirable. Furthermore, it is desirable that both the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are disposed as close to the occupant as possible.

The vehicle 10 in the present embodiment has a vehicle body tilt control system as a part of the control device. The vehicle body tilt control system is a kind of computer system and includes a tilt control ECU (Electronic Control Unit) 46 that functions as a tilt control device, as shown in FIG. The inclination control ECU 46 includes arithmetic means such as a processor, storage means such as a magnetic disk and semiconductor memory, an input / output interface, and the like, and is connected to the first lateral acceleration sensor 44a, the second lateral acceleration sensor 44b, and the link motor 25. Yes. Further, the inclination control ECU 46 determines the lateral acceleration acting on the vehicle body at an arbitrary position on the vehicle center axis based on the lateral accelerations a ₁ and a ₂ detected by the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b. An estimated acceleration calculation unit 49 that calculates an estimated value as an estimated lateral acceleration, and an inclination control unit 47 that outputs a command value for operating the link motor 25 based on the estimated lateral acceleration calculated by the estimated acceleration calculation unit 49. Including.

  The tilt control unit 47 performs feedback control during turning, so that the tilt angle of the vehicle body is such that the estimated lateral acceleration value calculated by the estimated acceleration calculation unit 49 becomes zero. The link motor 25 is operated. That is, the tilt angle of the vehicle body is controlled so that the centrifugal force to the outside of the turn and gravity are balanced and the lateral acceleration component becomes zero. As a result, a force in a direction parallel to the longitudinal axis of the vehicle body acts on the vehicle body and the occupant on the riding section 11. Therefore, the stability of the vehicle body can be maintained and the turning performance can be improved. In addition, the rider does not feel discomfort and the ride comfort is improved.

  Next, the operation of the vehicle 10 configured as described above will be described. Here, only the operation of the vehicle body tilt control process during turning is described.

  FIG. 5 is a diagram for explaining the trajectory of each part of the vehicle body during reverse turning in the first embodiment of the present invention, and FIG. 6 is the distance from the vehicle body center to the lateral acceleration sensor in the turning in the first embodiment of the present invention. It is a figure which shows the model explaining these.

  In the vehicle 10 according to the present embodiment, the front wheel 12F functions as a steering wheel, and the steering angle of the wheel 12F changes during turning. Therefore, when the vehicle 10 turns while retreating, that is, during reverse turning, the direction of the vehicle 10 changes as shown in FIG.

  FIG. 5 shows an example in which the vehicle 10 turns from the first position 10-1 to the second position 10-2 as shown by the arrow A while moving backward. In other words, a state is shown in which the steered wheel turns in a traveling state on the rear side in the traveling direction. In the example shown in FIG. 5, the turning angle is 90 degrees, and the direction of the vehicle 10 is changed by 90 degrees between the first position 10-1 and the second position 10-2.

  In FIG. 5, reference numeral 19 denotes the center of the vehicle body in turning. Specifically, it is on the axles of the left and right wheels 12L and 12R as rear wheels and on the vehicle center axis, that is, in the front-rear direction. In other words, the vehicle 10 is positioned at the center in the width direction of the vehicle 10 on the longitudinal axis of the vehicle 10. Reference numeral 44A denotes a temporary position of the lateral acceleration sensor 44. Here, for convenience of explanation, it is assumed that the lateral acceleration sensor 44 is single. 44A is on the vehicle center axis and between the wheel 12F, which is a steering wheel, and the vehicle body center 19 in turning.

  In FIG. 5, a line 61 indicates the trajectory of the vehicle 10 that turns as indicated by the arrow A while moving backward, and more specifically indicates the trajectory of the vehicle body center 19 in the turn. Note that point 60 is the turning center of the turning vehicle 10, and r is the distance from the turning center 60 to the arc portion of the trajectory 61, that is, the turning radius. A line 63 indicates the locus of the lateral acceleration sensor 44. A point 62 indicates a branch point where the trajectory 63 of the lateral acceleration sensor 44 branches off from the trajectory 61 of the vehicle body center 19 in turning. The branch point 62 corresponds to the position of the lateral acceleration sensor 44 at the time when the steering angle of the wheel 12F, which is a steered wheel, starts to change. Reference numeral 61a denotes a section in which the trajectory 63 of the lateral acceleration sensor 44 coincides with the trajectory 61 of the vehicle body center 19 in turning in the trajectory 61 of the vehicle body center 19 in turning. The section 61a also includes the locus of the lateral acceleration sensor 44 before the steering angle of the wheel 12F, which is a steered wheel, starts changing, that is, when the vehicle 10 is moving straight forward while moving backward.

  As can be seen by comparing the trajectories 61 and 63, in the initial stage of the vehicle 10 turning backward, that is, in the initial turning state (range in the vicinity of the branch point 62) in the traveling state where the steered wheels are on the rear side in the traveling direction. 44 shows a state in which the vehicle 10 turns in the opposite direction (left direction in FIG. 5) to the turning direction (right direction in FIG. 5). This is because, due to yawing (yaw motion), the vehicle body rotates on a plane around the vehicle body center 19 in turning, and therefore the lateral acceleration sensor 44 positioned behind the vehicle body center 19 in turning turns the turning direction of the vehicle 10. This is because they are displaced in the opposite direction.

  For this reason, the vehicle 10 that turns as indicated by the arrow A has an acceleration caused by the turn as indicated by the arrow B, whereas the lateral acceleration sensor 44 in the vehicle 10 is positioned at the reverse position of the vehicle 10. In the early stage of turning, a reverse acceleration as indicated by an arrow C occurs. Depending on conditions such as the size of the steering angle of the wheel 12F and the distance from the vehicle body center 19 to the lateral acceleration sensor 44 in turning, the acceleration in the reverse direction as indicated by the arrow C is the acceleration caused by the turning as indicated by the arrow B. Can be larger.

  Therefore, based on the lateral acceleration detected by the lateral acceleration sensor 44, the tilt angle of the vehicle body is controlled so that the centrifugal force to the outside of the turn and gravity are balanced and the lateral acceleration component becomes zero. When the control is executed, the control becomes unstable particularly in the early stage of the backward turning of the vehicle 10, and the stability of the vehicle 10 may be lost. It should be noted that at the end of the backward turning of the vehicle 10, the acceleration due to the vehicle body rotating on the plane around the vehicle body center 19 in the turning by the yawing is in the same direction as the acceleration due to the turning, so that there is almost no control problem. It is thought that it does not become.

  Therefore, in the present embodiment, there are a plurality of lateral acceleration sensors 44, which are arranged at different positions in the front-rear direction, and preferably at different positions on the vehicle center axis. The number of the lateral acceleration sensors 44 may be any number as long as it is two or more. Here, for convenience of explanation, as shown in FIGS. It is assumed that there are two acceleration sensors 44a and a second lateral acceleration sensor 44b. The first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are arranged at the same height on the vehicle center axis. Further, it is assumed that the first lateral acceleration sensor 44 a is disposed in the windbreak portion 11 c and the second lateral acceleration sensor 44 b is disposed on the back surface of the riding portion 11. That is, the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are located between the wheel 12F, which is a steering wheel, and the vehicle body center 19 in turning.

Further, as shown in FIG. 6, the distance from the vehicle body center 19 to the first lateral acceleration sensor 44a in the turn is L _H1 , and the distance from the vehicle body center 19 to the second lateral acceleration sensor 44b in the turn is L _H2 . It shall be. Further, it is assumed that the virtual lateral acceleration sensor 44x is attached at an arbitrary position on the vehicle body center 19 in the turn or in a range on the opposite side of the steered wheels from the vehicle body center 19. The virtual lateral acceleration sensor 44x is preferably located on the vehicle center axis. The virtual lateral acceleration sensor mounting position as the virtual lateral acceleration detection position, that is, the distance from the vehicle body center 19 to the virtual lateral acceleration sensor 44x is L _Hx .

  Next, an operation for calculating the estimated lateral acceleration when the steered wheel turns in a traveling state on the rear side in the traveling direction will be described.

  FIG. 7 is a diagram for explaining the trajectory of the virtual lateral acceleration sensor during reverse turning in the first embodiment of the present invention, and FIG. 8 is a flowchart showing the operation of the estimated acceleration calculation processing in the first embodiment of the present invention. It is.

When the turning traveling in the traveling state where the steered wheel is on the rear side in the traveling direction, that is, the backward turning by the vehicle 10 is started, the vehicle body inclination control system starts the vehicle body inclination control process. By performing posture control, the vehicle 10 turns with the link mechanism 30 in a state where the vehicle body is tilted inward (right side in the drawing) as shown in FIG. Further, during turning, a centrifugal force to the outside of the turning acts on the vehicle body, and a lateral component of gravity is generated by tilting the vehicle body to the inside of the turn. The estimated acceleration computing unit 49 executes the estimated acceleration calculation processing, and outputs the tilt control unit 47 calculates the estimated lateral acceleration a _x. Then, the inclination control unit 47 performs feedback control, and outputs a control value such that the estimated lateral acceleration a _x becomes zero to the link motor 25.

The vehicle body tilt control process is a process that is repeatedly executed by the vehicle body tilt control system at a predetermined control cycle T _S (for example, 5 [ms]) while the vehicle 10 is turned on. This is a process for improving turning performance and ensuring passenger comfort.

  The acceleration detected by the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b and outputting the detected value is <1> centrifugal force acting on the vehicle body when turning, and <2> tilting the vehicle body toward the inside of the turn. Due to the lateral component of the generated gravity, <3> yawing, the vehicle body rotates around the vehicle body center 19 in turning, so the first lateral acceleration sensor 44a and the second lateral acceleration sensor located at a position away from the vehicle body center 19 in turning. The acceleration generated by the acceleration sensor 44b rotating in the circumferential direction about the vehicle body center 19 in the circumferential direction, and the <4> operation of the link motor 25 or the reaction thereof, the first lateral acceleration sensor 44a and the second lateral acceleration sensor. 44b is considered to be the acceleration generated by the displacement in the circumferential direction on the vertical plane.

Of these four accelerations, <1> and <2> are independent of the positions of the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b. On the other hand, <3> is an acceleration generated by displacement in the circumferential direction on the plane, and is proportional to the distance from the vehicle body center 19, that is, proportional to L _H1 and L _H2 . Further, <4> is an acceleration generated by the displacement in the circumferential direction on the vertical plane, and is proportional to the distance from the roll center. That is, if the distance (height) from the road surface 18 to the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b is L, it is approximately proportional to L.

Here, the acceleration of the <3> of the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b outputs the detected value detected by the a _r1 and a _r2, the first lateral acceleration sensor 44a and a second lateral acceleration The acceleration of <4>, which is detected by the sensor 44b and outputs the detected value, is a _M1 and a _M2 . Further, the acceleration of <1> to the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b outputs the detected value detected by the a _T, a first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b is detected Then, the acceleration of <2> that outputs the detected value is defined as a _G. Since <1> and <2> are irrelevant to the heights of the first and second lateral acceleration sensors 44a and 44b, the detection values of the first and second lateral acceleration sensors 44a and 44b are equal. .

Then, the angular velocity of the circumferential displacement due to yawing, that is, the yaw rate is ω _r , and the acceleration, that is, the yaw acceleration is ω _r ′. Further, the angular velocity of the circumferential displacement due to the operation of the link motor 25 or its reaction is ω _M , and the angular acceleration is ω _M ′. Note that the angular velocity ω _M or the angular acceleration ω _M ′ can be obtained from a detection value of a link angle sensor (not shown).

Then, a _r1 = L _H1 ω _r ′, a _r2 = L _H2 ω _r ′, a _M1 = Lω _M ′, a _M2 = Lω _M ′.

Further, when the detection value of the acceleration by the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b is detecting and outputting the a ₁ and a _2, a ₁ and a _2, four acceleration <1> to <4 It is represented by the following formulas (1) and (2).
_{a 1 = a T + a G} + L H1 ω r '+ Lω M' ··· formula (1)
_{a 2 = a T + a G} + L H2 ω r '+ Lω M' ··· formula (2)
Then, by subtracting equation (2) from equation (1), the following equation (3) can be obtained.
a ₁ −a ₂ = (L _H1 −L _H2 ) ω _r ′ Equation (3)
Furthermore, the following formula (4) can be obtained from the formula (3).
ω _r ′ = (a ₁ −a ₂ ) / (L _H1 −L _H2 ) (4)
The value of yaw angular acceleration ω _r ′ can be calculated by the equation (4).

Further, when a _T + a _G is set as a control target value for the control of tilting the vehicle body so that the lateral acceleration generated in the vehicle body becomes zero, the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b detect it. The following expressions (5) and (6) can be obtained as a result of removing unnecessary accelerations <3> and <4> from the detected acceleration values a ₁ and a ₂ .
_{a T + a G = a 1} -L H1 ω r '-Lω M' ··· (5)
_{a T + a G = a 2} -L H2 ω r '-Lω M' ··· (6)
Theoretically, the same value can be obtained by both equation (5) and equation (6). However, since the acceleration caused by yawing is proportional to the distance from the vehicle body center 19, in practice, it depends on the vehicle body center 19. It is desirable to use a ₂ which is a detection value of the nearer lateral acceleration sensor 44, that is, the second lateral acceleration sensor 44b as a reference. Therefore, in the present embodiment, the estimated lateral acceleration a _x is calculated by Expression (6).

Then, the following equation (7) is derived from the equations (4) and (6).
a _T + a _G = a ₂ −L _H2 (a ₁ −a ₂ ) / (L _H1 −L _H2 ) −Lω _M ′ (7)
Here, the estimated lateral acceleration a _x detected by the virtual lateral acceleration sensor 44x as shown in FIG. 6 is four accelerations as in a ₁ and a ₂ represented by the above formulas (1) and (2). Since it is the sum of <1> to <4> and the distance from the vehicle body center 19 to the virtual lateral acceleration sensor 44x is L _Hx, it is expressed by the following equation (8).
_{a x = a T + a G} -L Hx ω r '+ Lω M' ··· formula (8)
Note that the sign of the third term on the right side of Equation (8) is negative because L _Hx is displayed as an absolute value and the virtual lateral acceleration sensor 44x is behind the vehicle body center 19 (opposite of the steering wheel). This is because it is located on the side.

Then, by substituting the equations (4) and (7) into the equation (8), the following equation (9) is derived.
a _x = a ₂ − (L _H2 + L _Hx ) (Δa / ΔL _H ) (9)
Note that Δa = a ₁ −a ₂ and ΔL _H = L _H1 −L _H2 .

Here, when the position of the virtual lateral acceleration sensor 44x is set at the vehicle body center 19, that is, when L _Hx = 0 is set, the virtual lateral acceleration sensor 44x when the vehicle 10 turns as shown by the arrow A while moving backward is set. The locus of is as shown by a line 63x in FIG. That is, it coincides with the locus 61 of the vehicle body center 19 in turning. In FIG. 7, a line 63a indicates the locus of the first lateral acceleration sensor 44a, and a line 63b indicates the locus of the second lateral acceleration sensor 44b. A point 62a indicates a branch point where the trajectory 63a of the first lateral acceleration sensor 44a branches from the trajectory 61 of the vehicle body center 19 during turning, and a point 62b indicates the vehicle center when the trajectory 63b of the second lateral acceleration sensor 44b rotates. A branch point that branches off from 19 tracks 61 is shown.

Therefore, by setting the position of the virtual lateral acceleration sensor 44x to the vehicle body center 19, estimated lateral acceleration a _x detected by the virtual lateral acceleration sensor 44x is 5, the acceleration in the opposite direction as indicated by arrow C It turns out that it is not influenced by.

  Note that the position of the virtual lateral acceleration sensor 44x can be set behind the vehicle body center 19. In this case, since the trajectory of the virtual lateral acceleration sensor 44x passes through the inside of the turn with respect to the trajectory 61 of the vehicle body center 19, the vehicle body is centered on the vehicle body center 19 in the turn by yawing at the initial stage of the backward turn of the vehicle 10. The acceleration due to rotation on the plane is in the same direction as the acceleration due to turning, so it is considered that there is almost no problem in control.

When the vehicle body tilt control system starts the vehicle body tilt control process, the estimated acceleration calculation unit 49 starts the estimated acceleration calculation process, and first acquires the first lateral acceleration sensor value a ₁ (step S1). 1 lateral acceleration sensor attachment position L _H1 , that is, a distance L _H1 from the vehicle body center 19 to the first lateral acceleration sensor 44a is called (step S2).

Subsequently, the estimated acceleration calculation unit 49 acquires the second lateral acceleration sensor value a ₂ (step S3), and from the second lateral acceleration sensor mounting position L _H2 , that is, from the vehicle body center 19 to the second lateral acceleration sensor 44b. The distance L _H2 is called (step S4).

Note that the values of the first lateral acceleration sensor mounting position L _H1 and the second lateral acceleration sensor mounting position L _H2 are stored in advance in the storage means of the vehicle body tilt control system as the dimensions of each part of the vehicle 10.

Subsequently, the estimated acceleration calculation unit 49 calls the virtual lateral acceleration sensor attachment position L _Hx , that is, the distance L _Hx from the vehicle body center 19 to the virtual lateral acceleration sensor 44x (step S5). Note that the value of the virtual lateral acceleration sensor mounting position L _Hx is set in advance and stored in the storage means included in the vehicle body tilt control system. As described above, the mounting position of the virtual lateral acceleration sensor 44x is arbitrarily set as long as it is on the vehicle center axis and on the vehicle body center 19 in a turn or in a range on the opposite side of the steered wheels from the vehicle body center 19. Here, it is assumed that the vehicle is on the vehicle body center 19 in the turn. That is, L _Hx = 0.

Subsequently, the estimated acceleration calculation unit 49 calculates an estimated lateral acceleration a _x (step S6). In this case, the estimated lateral acceleration a _x is calculated from the equation (9).

Finally, the estimated acceleration computing unit 49, the tilt control section 47 then sends the estimated lateral acceleration a _x (step S7), and terminates the estimated acceleration calculation processing.

  Next, an operation for controlling the inclination of the vehicle body will be described.

  FIG. 9 is a flowchart showing the operation of the vehicle body control process in the first embodiment of the present invention.

When the vehicle body control process is started, the tilt control unit 47 first receives the estimated lateral acceleration a _x from the estimated acceleration calculation unit 49 (step S11).

Subsequently, the inclination control unit 47 makes an _old call (step S12). a _old is an estimated lateral acceleration a _x stored when the vehicle body tilt control process is executed last time. In the initial setting, a _old = 0.

Subsequently, the tilt control unit 47 acquires the control cycle T _S (step S13), and calculates a differential value of the estimated lateral acceleration a _x (step S14). Here, when the differential value of a _x is da _x / dt, the da _x / dt is calculated by the following equation (10).
_{da x / dt = (a x} -a old) / T S ··· formula (10)
The tilt control unit 47 is stored as a _old = a _x (step S15). That is, the estimated lateral acceleration a _x obtained at present body tilt control processing executed as a _old, stored in the storage means.

Then, tilt control unit 47 calculates the first control value U _P (step S16). Here, if the control gain of the proportional control operation, that is, the proportional gain is C _P , the first control value _UP is calculated by the following equation (11).
U _P = C _P a _x (11)
Then, tilt control unit 47 calculates the second control value U _D (step S17). Here, the control gain of the differential control operation, i.e., when the derivative time and C _D, the second control value U _D is calculated by the following equation (12).
U _D = C _D da _x / dt (12)
Subsequently, the inclination control unit 47 calculates a third control value U (step S18). Third control value U is the sum of the first control value U _P and the second control value U _D, is calculated by the following equation (13).
U = U _P + U _D ··· formula (13)
Finally, the inclination control unit 47 outputs the third control value U as the link motor command value to the link motor 25 (step S19), and ends the process.

As described above, in the present embodiment, the first lateral acceleration sensor 44a and the second lateral acceleration sensor disposed at different positions on the vehicle center axis when the vehicle is turning in a traveling state in which the steered wheel is on the rear side in the traveling direction. From the detection value of the acceleration sensor 44b, the value of the lateral acceleration component at the virtual lateral acceleration sensor mounting position L _Hx on the vehicle center axis is calculated as the estimated lateral acceleration a _x , and the centrifugal force and the gravity to the outside of the turn are calculated. The inclination angle of the vehicle body is controlled so that the angle is balanced, that is, the value of the estimated lateral acceleration a _x is zero.

  As a result, even when turning in a traveling state where the steered wheel is on the rear side in the traveling direction, that is, during backward turning, the control wheel is less affected by acceleration in the direction opposite to the turning direction, so that the control stability is improved.

  Therefore, the stability of the vehicle body can be maintained and the turning performance can be improved. In particular, when the mounting position of the virtual lateral acceleration sensor 44x, which is the arbitrary position, is on the vehicle body center 19 in turning, the control stability is further improved because it is not affected by acceleration in the direction opposite to the turning direction. To do.

  In the present embodiment, the case where there are two lateral acceleration sensors 44 has been described. However, if there are a plurality of lateral acceleration sensors 44 arranged at different positions on the vehicle central axis, There may be three or more and any number.

  Next, a second embodiment of the present invention will be described. In addition, about the thing which has the same structure as 1st Embodiment, the description is abbreviate | omitted by providing the same code | symbol. The description of the same operation and the same effect as those of the first embodiment is also omitted.

  FIG. 10 is a view showing the back of the vehicle in a state where the vehicle body is inclined according to the second embodiment of the present invention.

  The vehicle 10 in the present embodiment does not have the link mechanism 30, and the main body 20 and the riding section 11 are connected so as to be swingable in the roll direction around the roll shaft 20 a, and an actuator device for tilting is provided. By rotating the link motor 25 as described above, as shown in the figure, the riding section 11 can be swung and rolled, that is, tilted with respect to the main body section 20. The roll shaft 20a is the center of the movement in which the riding section 11 swings and rolls with respect to the main body 20, that is, the roll center. Note that the rotation shaft of the link motor 25 extending in the traveling direction of the vehicle body may coincide with the roll shaft 20a.

  Even during turning, the angle of the left and right wheels 12L and 12R with respect to the road surface 18, that is, the camber angle does not change, and the riding part 11 is swung with respect to the main body part 20 together with the wheel 12F as the front wheel to the turning inner wheel side. By tilting, it is possible to improve the turning performance and ensure the comfort of the passenger. In the example shown in the figure, the left and right wheels 12L and 12R stand upright with respect to the road surface 18 when the vehicle is traveling straight or turning, that is, the camber angle is 0 degree.

  Since the configuration of other points is the same as that of the first embodiment, description thereof is omitted.

  As in the first embodiment, the lateral acceleration sensor 44 includes a first lateral acceleration sensor 44a and a second lateral acceleration sensor 44b, and includes the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b. Are arranged at different positions on the vehicle central axis.

  In the present embodiment, the center of the tilting motion when the riding section 11 tilts, that is, the roll center coincides with the roll shaft 20a. Therefore, the height L of the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b is set as a distance from the roll shaft 20a.

  It is desirable that the first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are disposed as close to the roll shaft 20a as possible.

  Since the other points of the lateral acceleration sensor 44 are the same as those of the first embodiment, description thereof will be omitted. The vehicle body tilt control system is also the same as that in the first embodiment, and a description thereof will be omitted. Furthermore, since the operation of the vehicle 10 in the present embodiment is the same as that in the first embodiment, the description thereof is omitted.

  Next, a third embodiment of the present invention will be described. In addition, about the thing which has the same structure as 1st and 2nd embodiment, the description is abbreviate | omitted by providing the same code | symbol. Also, the description of the same operations and effects as those of the first and second embodiments is omitted.

  FIG. 11 is a diagram for explaining the trajectory of the virtual lateral acceleration sensor during forward turning in the third embodiment of the present invention.

  In the present embodiment, the vehicle 10 is a tricycle whose front wheels are two left and right wheels and whose rear wheels are one wheel, and whose rear wheels are steering wheels. In other words, in the vehicle 10 according to the present embodiment, the front wheels are the left and right wheels 12L and 12R and function as drive wheels, the rear wheels 12F function as steering wheels, and the turning angle of the wheels 12F is at the time of turning. Change. Therefore, when the vehicle 10 turns while moving forward, that is, during forward turning, the direction of the vehicle 10 changes as shown in the figure.

  The figure shows an example in which the vehicle 10 turns as indicated by an arrow A while moving forward. In other words, a state is shown in which the steered wheel turns in a traveling state on the rear side in the traveling direction. Since the vehicle body center 19 in turning is on the axles of the left and right wheels 12L and 12R, which are front wheels, the vehicle body center 19 is positioned forward of the wheels 12F. The first lateral acceleration sensor 44a and the second lateral acceleration sensor 44b are located on the vehicle center axis and between the wheel 12F that is a steered wheel and the vehicle body center 19 in turning.

  When the position of the virtual lateral acceleration sensor 44x is set at the vehicle body center 19, the trajectory of the virtual lateral acceleration sensor 44x when the vehicle 10 turns as indicated by the arrow A while moving forward is indicated by a line 63x in the drawing. It comes to be. That is, it coincides with the locus 61 of the vehicle body center 19 in turning. Similarly to FIG. 7 in the first embodiment, a line 63a indicates the locus of the first lateral acceleration sensor 44a, and a line 63b indicates the locus of the second lateral acceleration sensor 44b. A point 62a indicates a branch point where the trajectory 63a of the first lateral acceleration sensor 44a branches from the trajectory 61 of the vehicle body center 19 during turning, and a point 62b indicates the vehicle center when the trajectory 63b of the second lateral acceleration sensor 44b rotates. A branch point that branches off from 19 tracks 61 is shown.

Therefore, by setting the position of the virtual lateral acceleration sensor 44x to the vehicle body center 19, estimated lateral acceleration a _x detected by the virtual lateral acceleration sensor 44x is found to be unaffected acceleration in the opposite direction.

  Since the configuration of other points is the same as that of the first embodiment, description thereof is omitted. The vehicle body tilt control system is also the same as that in the first embodiment, and a description thereof will be omitted. Furthermore, since the operation of the vehicle 10 in the present embodiment is the same as that in the first embodiment, the description thereof is omitted.

  In addition, this invention is not limited to the said embodiment, It can change variously based on the meaning of this invention, and does not exclude them from the scope of the present invention.

  The present invention can be used for a vehicle having at least a pair of left and right wheels.

DESCRIPTION OF SYMBOLS 10 Vehicle 11 Boarding part 12F, 12L, 12R Wheel 19 Center of vehicle body 20 Main-body part 25 Link motor 44a 1st lateral acceleration sensor 44b 2nd lateral acceleration sensor

Claims (3)

A vehicle body including a steering unit and a drive unit coupled to each other;
A wheel rotatably attached to the steering unit, the steering wheel for steering the vehicle body;
A wheel rotatably attached to the drive unit, the drive wheel driving the vehicle body;
A tilting actuator device for tilting the steering unit or the driving unit in a turning direction;
A plurality of lateral acceleration sensors disposed at different positions in the front-rear direction and detecting lateral acceleration acting on the vehicle body;
A control device for controlling the tilt of the vehicle body by controlling the tilt actuator device;
The control device calculates an estimated lateral acceleration at a virtual lateral acceleration detection position on the center of the vehicle body in a turn or in a range on the opposite side of the steering wheel from the center of the vehicle body from the lateral acceleration detected by the plurality of lateral acceleration sensors. The vehicle is characterized in that the inclination of the vehicle body is controlled so that the estimated lateral acceleration becomes zero. The control device calculates the estimated lateral acceleration when turning in a traveling state in which the steered wheel is on the rear side in the traveling direction, and controls the inclination of the vehicle body so that the estimated lateral acceleration becomes zero. Item 4. The vehicle according to Item 1 . Wherein the plurality of lateral acceleration sensors are arranged at different positions on the vehicle center axis, the vehicle according to claim 1 or 2, wherein the virtual lateral acceleration detection position is set on the vehicle center axis.

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