JP2004175336A - Steering device for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a steering device for a vehicle requiring no spiral flat cable and including a small and highly reliable transmission ratio variable mechanism. <P>SOLUTION: The steering device 1 for the vehicle is provided with the transmission ratio variable mechanism 10 varying a transmission ratio of rotational movements between a first steering shaft 110 and a second steering shaft 120. The transmission ratio variable mechanism 10 has a wave motion gear reducer 130 for changing the transmission ratio between the first steering shaft 110 and the second steering shaft 120 in accordance with the number of rotation of a motor shaft 152. The motor shaft 152 and the second steering shaft 120 form a dual structure being arranged almost on the same axis. An output shaft 151 is connected with the motor shaft 152 with a driving motor 150 fixedly installed. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
【Technical field】
The present invention relates to a vehicle steering system that transmits a steering angle of a steering wheel to steered wheels.
[0002]
[Prior art]
An ordinary vehicle steering system transmits a steering angle of a steering wheel with a substantially constant transmission ratio to give a steered wheel a predetermined steering angle. For example, in a general rack-and-pinion type vehicle steering system, a steering gear and a pinion gear extending to a steered wheel mesh with a rack gear that rotates integrally with a steering wheel, so that a steering angle between the steering angle and the steering angle is increased. Has been determined.
[0003]
However, if the transmission ratio of the vehicle steering system is constant, it is difficult to achieve a good driving feeling particularly during low-speed running and high-speed running. That is, during low-speed running, it is desirable to set a high transmission ratio at which a large steering angle can be obtained with a small steering angle. Conversely, when traveling at high speeds, it is better that the transmission ratio between the steering angle and the turning angle is low in order to ensure safe traveling stability.
[0004]
Therefore, conventionally, a vehicle steering device having a variable transmission ratio mechanism configured to be able to change the transmission ratio between the steering angle and the turning angle in accordance with the driving situation has been proposed.
As such a transmission ratio variable mechanism, there is a mechanism mainly configured with a reduction gear that changes a reduction ratio by rotation input from the outside. As this speed reducer, a planetary gear speed reducer, a wave gear speed reducer, or the like is used (for example, see Patent Document 1).
[0005]
Here, as shown in FIG. 9, a conventional vehicle steering system 9 including a variable transmission ratio mechanism using a wave gear reducer will be described. The vehicle steering system transmits the operation of the steering wheel 910 to the gearbox 970 via the steering shaft 920, the intermediate shafts 930 and 940, and the rear end shaft 960 interconnected by the universal joints 921 and 951. It is composed. The gearbox 970 is configured so that the rotational motion of the rear end shaft 960 can be converted into the linear motion of the steering rod 980 in the axial direction.
Further, between the intermediate shaft 930 and the intermediate shaft 940, a transmission ratio variable mechanism 950 for changing the transmission ratio between the two is inserted.
[0006]
The transmission ratio variable mechanism 950 is configured to change the transmission ratio between the intermediate shaft 930 and the intermediate shaft 940 by the wave gear reducer 90 as shown in FIG. Here, the operation of the wave gear reducer 90 will be briefly described.
The wave gear reducer 90 is a reducer including a circular spline 91, a flex spline 93, and a wave generator 92, as shown in FIG. The wave gear reducer 90 is configured so that the transmission ratio between the circular spline 91 and the flexspline 93 can be changed by the rotation of the wave generator 92.
[0007]
In the variable transmission ratio mechanism 950, as shown in the figure, the circular spline 91 is connected to an intermediate shaft 930 that rotates integrally with the steering handle 910 (FIG. 9), and the intermediate shaft 940 rotates integrally with the rear end shaft 960. And a flexspline 93 is connected to it. The output shaft 952 of the drive motor 951 disposed inside the housing 965 that rotates integrally with the intermediate shaft 940 is press-fitted into the wave generator 92.
[0008]
The drive motor 951 has a stator 953 fixed inside the cylindrical surface of the housing 965, a rotor 954 disposed inside the stator 953, and an output shaft 952 that outputs the rotation of the rotor 954. The transmission ratio between the circular spline 91 and the flexspline 93 can be changed by rotating the wave generator 92 that rotates integrally with the output shaft 952. That is, the transmission ratio variable mechanism 950 is configured to change the transmission ratio between the intermediate shaft 930 and the intermediate shaft 940 by the rotation of the drive motor 951.
[0009]
[Patent Document 1]
Japanese Patent Application Laid-Open No. 2000-23241 (paragraph numbers “0013” to “0017” of the specification, FIG. 2 and FIG. 3)
[0010]
[Problem to be solved]
However, the conventional vehicle steering system 9 has the following problems. That is, as described above, the drive motor 951 is fixed inside the housing 965 that rotates integrally with the intermediate shaft 940. On the other hand, it is necessary to connect a lead wire for supplying power, a lead wire for transmitting a control signal and the like to the drive motor 951.
[0011]
Therefore, it is necessary to arrange the plurality of lead wires so as to be able to absorb the rotation of the drive motor 951 accompanying the rotation of the intermediate shaft 940. Therefore, in this transmission ratio variable mechanism 950, as shown in FIG. 11, a plurality of lead wires are arranged in parallel to form one flat cable 957. The flat cable 957 is loosely spirally wound around the outer periphery of the inserted portion 967 of the housing 965 into which the intermediate shaft 940 is inserted.
[0012]
Further, as shown in FIG. 11, a cover 958 for protecting the spirally wound flat cable 957 is provided on the outer periphery of the inserted portion 967. The cover 958 is fixed to the vehicle body (not shown) so as not to be affected by the rotation of the intermediate shaft 940 and the housing 965.
Each lead wire of the flat cable 957 is electrically connected to an input / output terminal 959 disposed outside the cover 958. The drive motor 951 can be controlled by an external device such as an ECU via the input / output terminal 959.
[0013]
In the variable transmission ratio mechanism 950, as shown in FIG. 11, the flat cable 957 is arranged in a spiral shape inside the fixed cover 958. The flat cable 957 is configured so as to absorb the relative rotation between the intermediate shaft 940 that rotates in the winding direction and the cover 958 due to the reduced diameter of the spiral of the flat cable 957. Therefore, the flat cable 957 needs to be sufficiently long in consideration of the case where the intermediate shaft 940 has completely rotated in the winding direction of the flat cable 957.
[0014]
Further, when the intermediate shaft 940 rotates in a direction in which the flat cable 957 is further slackened, the spiral formed by the flat cable 957 has a larger diameter. For this reason, the cover 958 needs to have a sufficiently large diameter on the assumption that the intermediate shaft 940 has completely rotated in the direction in which the flat cable 957 is slackened.
Further, as shown in FIG. 10, the cover 958 needs to have a sufficient axial length so as to accommodate the flat cable 957 which is widened by arranging a plurality of lead wires in parallel.
[0015]
Thus, as shown in FIG. 10, in the conventional transmission ratio variable mechanism 950, it is necessary to secure a large arrangement space for accommodating the long flat cable 957 connected to the drive motor 951.
In addition, due to the rotation of the intermediate shaft 940, the spiral winding composed of the flat cable 957 repeatedly reduces in diameter and increases in diameter. Therefore, in order to prevent metal fatigue of the flat cable 957 and deterioration of the coating due to friction between the flat cables 957, a flexible lead wire is used, and the coating is improved in abrasion resistance. Measures were needed.
[0016]
As described above, when the structure including the spiral flat cable is adopted, various problems due to the structure may occur. Therefore, it has been desired to develop a vehicle steering system having a simple structure that does not require the spiral flat cable.
[0017]
SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned conventional problems, and an object of the present invention is to provide a steering apparatus for a vehicle including a small and highly reliable transmission ratio variable mechanism that does not require a spiral flat cable. is there.
[0018]
[Means for solving the problem]
A first aspect of the present invention changes a transmission ratio of a rotational operation between a first steering shaft that rotates integrally with a steering wheel and a second steering shaft that is connected to a steering rod for steering a steered wheel. In a vehicle steering system with a variable transmission ratio mechanism
The transmission ratio variable mechanism includes a drive motor, a motor shaft for transmitting rotation of an output shaft of the drive motor, and a rotation speed input from the first steering shaft according to the rotation speed of the motor shaft. And a speed reducer configured to change a transmission ratio between the rotation speed outputted to the second steering shaft and the rotation speed.
The motor shaft and the second steering shaft have a double structure arranged substantially coaxially, and the drive motor rotates either the first steering shaft or the second steering shaft. The vehicle steering apparatus according to claim 1, wherein the output shaft is connected to the motor shaft while being fixedly installed so as not to be affected by the motor.
[0019]
In the steering apparatus for a vehicle according to the first aspect of the invention, the drive motor is fixedly installed so as not to be affected by the rotation operation of either the first steering shaft or the second steering shaft. The motor shaft is arranged so as to have a double structure on the inner peripheral side or the outer peripheral side substantially coaxially with the second steering shaft, and the rotation of the drive motor is transmitted to the reduction gear via the motor shaft. Has been entered.
[0020]
Therefore, in this vehicle steering system, the entire drive motor does not rotate following the first steering shaft and the second steering shaft.
Therefore, the drive motor does not need to connect a spiral flat cable as in the related art. Therefore, various problems caused by the spiral flat cable can be surely solved, and a small and highly reliable structure can be realized.
[0021]
According to a second aspect of the present invention, a transmission ratio of a rotational operation between a first steering shaft that rotates integrally with a steering wheel and a second steering shaft that is connected to a steering rod for steering a steered wheel is changed. In a vehicle steering system with a variable transmission ratio mechanism
The transmission ratio variable mechanism includes a drive motor, a motor shaft for transmitting rotation of an output shaft of the drive motor, and a rotation speed input from the first steering shaft according to the rotation speed of the motor shaft. And a speed reducer configured to change a transmission ratio between the rotation speed outputted to the second steering shaft and the rotation speed.
The motor shaft and the first steering shaft have a double structure arranged substantially coaxially, and the drive motor rotates either the first steering shaft or the second steering shaft. The output shaft is connected to the motor shaft in a state where the output shaft is fixed and installed so as not to be affected by the vehicle steering.
[0022]
In the steering apparatus for a vehicle according to the second aspect of the invention, the drive motor is fixedly installed so as not to be affected by the rotation operation of either the first steering shaft or the second steering shaft. The motor shaft is arranged so as to have a double structure on the inner peripheral side or the outer peripheral side substantially coaxially with respect to the first steering shaft, and the rotation of the drive motor is controlled via the motor shaft. Input to the reducer.
[0023]
Therefore, in this vehicle steering system, the entire drive motor does not rotate following the first steering shaft or the second steering shaft.
Therefore, the drive motor does not need to connect a spiral flat cable as in the related art. Therefore, various problems caused by the spiral flat cable can be surely solved, and a small and highly reliable structure can be realized.
[0024]
BEST MODE FOR CARRYING OUT THE INVENTION
In the first invention, it is preferable that the speed reducer is a wave gear speed reducer (claim 2).
In this case, the variable transmission ratio mechanism can be reduced in size and the variable width of the transmission ratio can be set large by using a wave gear reducer that is small and can obtain a large transmission ratio. be able to.
[0025]
Preferably, the speed reducer is a planetary gear speed reducer.
In this case, the planetary gear reducer can be designed with a high degree of freedom to realize a vehicle steering system that satisfies various design specifications required for the variable transmission ratio mechanism.
[0026]
Further, it is preferable that the second steering shaft has a hollow through hole, and the motor shaft penetrates the hollow through hole.
In this case, in the speed reducer, the rotating member disposed further inside the rotating member that rotates integrally with the second steering shaft and the motor shaft can be connected by a relatively simple structure. it can.
[0027]
In particular, in a wave gear reducer having a coaxial triple structure including a circular spline, a flex spline disposed on the inner peripheral side of the circular spline, and a wave generator disposed on the inner peripheral side of the flex spline, The connection structure between the generator and the motor shaft can be simplified.
[0028]
A rack gear is formed on the steering rod, and a pinion gear is formed on the second steering shaft.
It is preferable that the rack gear and the pinion gear are engaged in a steering gear box accommodating at least a part of the steering rod and the second steering shaft.
[0029]
In this case, the steering angle of the steered wheels with respect to the steering angle of the steering wheel can be made accurate by the engagement of the rack gear and the pinion gear, and the operational feeling of the vehicle can be improved.
[0030]
Further, it is preferable that the transmission gear variable mechanism including the drive motor and the speed reducer is incorporated in the steering gear box.
In this case, the steering gear box and the miniaturized transmission ratio variable mechanism are integrated, so that the steering device can be made more compact. In addition, by integrating the steering gear box, which is usually installed outside the vehicle compartment, with the variable transmission ratio mechanism, the influence of the operation noise of the drive motor on the vehicle compartment can be reduced.
[0031]
It is preferable that the output shaft and the motor shaft are indirectly connected via a gear train.
In this case, the drive motor and the motor shaft can be arranged without being arranged coaxially. Therefore, the length of the variable transmission mechanism in the axial direction can be reduced.
The output shaft and the motor shaft may be arranged coaxially so as to directly connect them.
[0032]
In the second aspect of the invention, the first steering shaft has a transmission shaft portion that transmits a rotational driving force of the first steering shaft, and the rotational driving force of the first steering shaft is It is configured to be input to the reduction gear through a transmission shaft portion,
It is preferable that the transmission shaft portion and the motor shaft are arranged substantially coaxially and configured to have a double structure.
In this case, by arranging the transmission shaft portion and the motor shaft connected to the speed reducer in a double structure, a coaxial arrangement structure of both can be efficiently realized.
[0033]
Preferably, the speed reducer is a wave gear speed reducer.
In this case, the variable transmission ratio mechanism can be reduced in size and the variable width of the transmission ratio can be set large by using a wave gear reducer that is small and can obtain a large transmission ratio. be able to.
[0034]
Preferably, the speed reducer is a planetary gear speed reducer.
In this case, the planetary gear reducer can be designed with a high degree of freedom to realize a vehicle steering system that satisfies various design specifications required for the variable transmission ratio mechanism.
[0035]
Further, it is preferable that the motor shaft has a hollow through hole, and the first steering shaft penetrates the hollow through hole.
In this case, the rotational driving force of the first steering shaft can be taken out via the inner peripheral side of the rotating member disposed on the outer peripheral side of the motor shaft in the speed reducer.
[0036]
In particular, in a wave gear reducer having a coaxial triple structure including a circular spline, a flex spline disposed on the inner peripheral side of the circular spline, and a wave generator disposed on the inner peripheral side of the flex spline, The connection structure for extracting the rotational driving force of the first steering shaft via the inner peripheral side of the motor shaft connected to the generator and inputting the rotational driving force to the circular spline can be simplified.
[0037]
A rack gear is formed on the steering rod, and a pinion gear is formed on the second steering shaft.
It is preferable that the rack gear and the pinion gear are engaged in a steering gear box accommodating at least a part of the steering rod and the second steering shaft.
In this case, the steering angle of the steered wheels with respect to the steering angle of the steering wheel can be made accurate by the engagement of the rack gear and the pinion gear, and the operational feeling of the vehicle can be improved.
[0038]
Further, it is preferable that the transmission gear variable mechanism including the drive motor and the speed reducer is incorporated in the steering gear box.
In this case, the steering gear box and the miniaturized transmission ratio variable mechanism are integrated, so that the steering device can be made more compact. In addition, by integrating the steering gear box, which is usually installed outside the vehicle interior, with the variable transmission ratio mechanism, the influence of the operating noise of the drive motor on the vehicle interior can be reduced.
[0039]
The vehicle steering system includes an oil pump that generates a hydraulic pressure, and a power cylinder that drives the steering rod with the hydraulic pressure.
The first steering shaft has a torsion bar configured to generate a torsion in accordance with a rotational torque acting on the first steering shaft.
The steering gear box preferably includes a servo valve configured to switch an oil path from the oil pump to the power cylinder in response to the torsion of the torsion bar portion.
In this case, the steering gear box in the hydraulic vehicle steering system can be compactly and integrally formed. According to the integrated steering gear box, the assembling property to the vehicle is good.
[0040]
Preferably, the motor shaft is formed integrally with the output shaft of the drive motor.
In this case, by integrating the output shaft and the motor shaft, the transmission mechanism between them can be omitted, the number of parts can be reduced, and the structure of the transmission ratio variable mechanism can be simplified.
[0041]
【Example】
(Example 1)
The vehicle steering system according to the present embodiment will be described with reference to FIGS.
In this example, as shown in FIG. 1, a first steering shaft 110 that rotates integrally with a steering handle 300 (FIG. 2) and a second steering rod 190 that is used to steer a steered wheel (not shown). The present invention relates to a vehicle steering system 1 having a transmission ratio variable mechanism 10 that changes a transmission ratio of a rotational operation with a steering shaft 120.
[0042]
The variable transmission ratio mechanism 10 includes a drive motor 150, a motor shaft 152 for transmitting rotation of an output shaft 151 of the drive motor 150, and a wave gear reducer 130.
The wave gear reducer 130 changes the transmission ratio between the rotation speed input from the first steering shaft 110 and the rotation speed output to the second steering shaft 120 according to the rotation speed of the motor shaft 152. It is configured as follows.
[0043]
The motor shaft 152 and the second steering shaft 120 have a double structure arranged substantially coaxially, and the drive motor 150 operates to rotate either the first steering shaft 110 or the second steering shaft 120. The output shaft 151 is connected to the motor shaft 152 in a state where the output shaft 151 is fixed and installed so as not to be affected by the motor shaft 152.
The details will be described below.
[0044]
As shown in FIG. 2, the vehicle steering system 1 includes a steering wheel 300, a steering gear box 11 including a transmission ratio variable mechanism 10 (FIG. 1), and steered wheels (not shown). The rotation of the steering shaft 310 integrated with the steering handle 300 is transmitted to the steering gear box 11 via the universal joints 320 and 340 and the intermediate shaft 330 provided between the two universal joints 320 and 340. It is configured to be transmitted to the first steering shaft 110 inserted.
[0045]
Further, as shown in FIG. 3, the vehicle steering system 1 of the present embodiment is based on an electric power steering system in which an EPS actuator 60 is incorporated in a steering gear box 11. The vehicle steering system 1 of this embodiment based on this electric power steering system is configured so that the operation force of the steering wheel 300 can be reduced by the action of the EPS actuator 60. It should be noted that a hydraulic actuator may be incorporated in place of the EPS actuator 60, and the operating force of the steering wheel 300 may be reduced by the action of hydraulic pressure.
[0046]
Further, as shown in FIG. 3, the vehicle control device 1 of the present embodiment controls a first ECU (EPS ECU) 601 for controlling the EPS actuator 60 and a variable gear ratio system (VGRS) 10 for controlling a variable transmission ratio mechanism (VGRS) 10. The variable transmission ratio mechanism 10 and the EPS actuator 60 can be controlled by a 2ECU (VGRS ECU) 101. Here, the vehicle speed signal output from the vehicle speed sensor 70, and the rotational torque value and the steering angle of the steering wheel 300 output from the torque sensor 40 are configured to be input to the first ECU 601 and the second ECU 101. Control according to steering conditions such as steering torque and steering wheel torque is possible.
[0047]
As shown in FIG. 3, the first ECU 601 is configured to control the EPS actuator 60 by inputting a rotational torque value given to the first steering shaft 110 by the steering wheel 300 and a vehicle speed signal. The second ECU 101 is configured to control the transmission ratio variable mechanism 10 by inputting the steering angle of the steering wheel 300 and the vehicle speed signal.
[0048]
As shown in FIG. 1 showing a cross-sectional shape including the rotation axis of the first steering shaft 110 and orthogonal to the steering rod 190, the steering gear box 11 is a rack-and-pinion type gear box. The steering gear box 11 has a steering rod 190 penetrated therein and a first steering shaft 110 inserted from a direction substantially orthogonal to the steering rod 190.
[0049]
In the steering gear box 11, as shown in FIG. 1, the rotary motion of the first steering shaft 110 can be converted into a linear motion of the steering rod 190 in the axial direction. Note that steered wheels (not shown) are connected to both ends of the steered rod 190 so that the steered angle of the steered wheels can be changed by the linear motion of the steered rod 190 in the axial direction.
[0050]
Further, as shown in FIG. 1, a variable transmission ratio mechanism 10 including a wave gear reducer 130 is built in the steering gear box 11. The variable transmission ratio mechanism 10 is configured to output the rotational motion input from the first steering shaft 110 as the rotational motion of a second steering shaft 120 disposed coaxially and opposed to the first steering shaft 110. I have.
The transmission ratio between the first steering shaft 110 and the second steering shaft 120 can be changed by rotation of a drive motor 150 fixedly installed in the steering gear box 11.
[0051]
As shown in FIG. 1, the steering gear box 11 combines a shaft housing 210 that houses the end of the first steering shaft 110 and a gear housing 220 that houses the steering rod 190, the second steering shaft 120, and the like. It is something.
The shaft housing 210 that houses the first steering shaft 110 has a tubular shape having a hollow through structure. A substantially cylindrical spool 170 that accommodates the first steering shaft 110 coaxially and a flange 180 that engages with a spline tooth at the tip of the first steering shaft 110 include a bearing 211 installed on the inner peripheral surface of the shaft housing 210. , 212 so as to be rotatable.
[0052]
The flange 180 is a substantially cylindrical member having a substantially circular cross section as shown in FIG. The end surface on the first steering shaft 110 side has a concave portion 182 having a substantially circular cross section coaxially with the first steering shaft 110 and the spool 170. The recess 182 includes a first recess 183 that accommodates the spool 170 and a second recess 184 that has a smaller diameter than the first recess 183 that accommodates the first steering shaft 110 protruding from the spool 170.
[0053]
As shown in FIG. 1, a needle bearing 185 is provided on the inner periphery of the first concave portion 183 to rotatably support the spool 170 and allow relative rotation between the spool 170 and the flange 180. It is configured as follows. Further, spline teeth that engage with spline teeth 113 formed on the outer peripheral surface of the distal end of the first steering shaft 110 are formed on the inner peripheral surface of the second concave portion 184.
In the other end surface of the flange 180, a concave portion 188 for fitting a ring-shaped circular spline 132 of a wave gear reducer to be described later is formed. In the concave portion 188, the inserted circular spline 132 can be fixed by a key (not shown).
[0054]
As shown in FIG. 1, the spline teeth 111 formed on the outer peripheral surface of the body portion of the first steering shaft 110 that is not inserted into the steering gear box 11 and the inner peripheral surface of the end of the spool 170 are formed. The spool 170 is arranged on the outer periphery of the first steering shaft 110 on the same axis with the spline teeth 171 being engaged.
[0055]
As shown in FIG. 1, a small-diameter portion 112 having a smaller diameter than the inner diameter of the spool 170 is formed in a portion of the first steering shaft 110 housed in the spool 170. When the flange 180 is rotated by the engagement of spline teeth formed at the tip of the first steering shaft 110, the small diameter portion 112 can be slightly twisted.
[0056]
On the other hand, as shown in FIG. 1, the spool 170 is engaged with the first steering shaft 110 by the spline teeth 111 of the first steering shaft 110 located closer to the steering handle 300 than the small diameter portion 112. Therefore, the twist generated in the small-diameter portion 112 can be manifested as a rotational deviation between the flange 180 and the spool 170.
[0057]
In the vehicle steering system 1 of the present embodiment, as shown in FIG. 1, a torque sensor 215 including a resolver for measuring the rotational position of the flange 180 and a resolver for measuring the rotational position of the spool is provided on the inner peripheral surface of the shaft housing 210. It is located in. The torque sensor 215 is configured to measure the amount of twist generated in the small-diameter portion 112 by comparing the measurement results obtained by the two resolvers, and to further calculate a rotational torque value acting on the first steering shaft 110. It is. Further, the torque sensor 215 is configured to output the rotational position of the spool 170 as the steering angle of the steering handle 300 in parallel with the rotational torque value.
[0058]
As shown in FIG. 1, the gear housing 220 includes an entirety of the second steering shaft 120 facing substantially the same axis as the first steering shaft 110 and a steering rod 190 substantially orthogonal to the second steering shaft 120. Department and housed. Then, by engaging a pinion gear 125 formed on the outer peripheral surface of the second steering shaft 120 with a rack gear 195 formed on the outer peripheral surface of the steering rod 190, the rotational motion of the second steering shaft 120 is reduced. The steering rod 190 is configured so as to be able to convert to a linear motion in the axial direction.
[0059]
As shown in FIG. 1, the second steering shaft 120 is rotatably supported by bearings 212 and 213 disposed on the inner periphery of the gear housing 220. Further, a joint portion 127 having a recess 128 into which a ring-shaped holding ring 138 to be described later is fitted is provided at an end of the first steering shaft 110 side. In the recess 128, the fitted holding ring 138 can be fixed by a key (not shown).
Also, the second steering shaft 120 has a hollow through structure. A bearing 122 for rotatably supporting the motor shaft 152 is provided on the inner peripheral surface of the second steering shaft 120.
[0060]
As shown in FIG. 1, the motor shaft 152 is configured to rotate by the rotational force of a drive motor 150 fixed to the gear housing 220. Here, the output shaft 151 of the drive motor 150 is connected via a drive gear 223 attached to the output shaft 151 of the drive motor 150 and a driven gear 224 attached to the end of the motor shaft 152 opposite to the wave gear reducer 130. Is transmitted to the motor shaft 152.
[0061]
The drive motor 150 is fixed inside the gear housing 220 while being housed in the motor case 156. A stator 153 is fixed to the inner peripheral surface of the substantially cylindrical motor case 156. A rotor 154 that penetrates the output shaft 151 is rotatably arranged inside the stator 153.
[0062]
As shown in FIG. 1, the motor shaft 152 is rotatably supported by a bearing 122 disposed inside the second steering shaft 120 having a hollow hollow structure and a bearing 211 disposed on the inner periphery of the gear housing 220. It is. The end of the motor shaft 152 on the side of the wave gear reducer 130 is press-fitted into a through hole 351 of a cam 131 of the wave gear reducer 130 described later, and is fixed by a key 350 (FIG. 4).
[0063]
A wave gear reducer 130 is disposed in a space formed between the concave portion 188 of the flange 180 and the concave portion 128 of the joint portion 127 of the second steering shaft 120.
The wave gear reducer 130 is a reducer including a circular spline 132, a flex spline 134, and a wave generator 136, as shown in FIG.
[0064]
As shown in FIG. 4, the circular spline 132 is a rigid body having a ring shape, and has spline teeth formed on the inner peripheral surface. In this example, the circular spline 132 fitted in the concave portion 188 of the flange 180 connected to the first steering shaft 110 is fixed to the flange 180 by a key (not shown).
[0065]
As shown in FIG. 4, the flex spline 134 is an elastic component made of a cup-shaped metal. Spline teeth having the same pitch as the spline teeth of the circular spline 132 and having two fewer teeth than the number of teeth of the circular spline 132 are formed on the outer peripheral surface near the opening end of the flexspline 134. It is.
The circular spline 132 and the flexspline 134 engage the spline teeth on the inner peripheral surface of the circular spline 132 with the spline teeth on the outer peripheral surface of the flexspline 134.
[0066]
In the present embodiment, a holding ring 138 having a ring shape having substantially the same outer diameter as the circular spline 132 is coaxially arranged on the outer periphery of the flexspline 134 as shown in FIG. On the inner peripheral surface of the retaining ring 138, spline teeth having the same pitch and the same number of teeth as the spline teeth of the flex spline 134 are formed. The retaining ring 138 and the flex spline 134 are engaged by the spline teeth. In this example, the holding ring 138 fitted in the recess 128 of the joint 127 of the second steering shaft 120 is fixed to the second steering shaft 120 by a key (not shown).
[0067]
As shown in FIG. 4, the wave generator 136 is a component in which a ball bearing 135 is fitted on the outer periphery of a cam 131 having an elliptical shape. The inner ring portion 137 of the ball bearing 135 fixed to the cam 131 is configured to rotate integrally with the cam 131. The outer ring portion 133 of the ball bearing 135 is configured to elastically deform as the cam 131 rotates.
[0068]
Further, as shown in FIG. 4, the wave generator 136 is fitted inside a flexspline 134 having a cup shape, and an inner peripheral surface of a portion of the flexspline 134 where spline teeth are formed, and an outer ring of the wave generator 136. The outer surface of the portion 133 is in contact with the outer surface. Here, the flexspline 134 whose opening is bent into an elliptical shape by fitting of the wave generator 136 is configured to be in contact with the outer ring 133 without any gap.
[0069]
Here, an outline of the operation of the wave gear reducer 130 configured as described above will be described. As shown in FIG. 4, the wave gear reducer 130 is configured so that the transmission ratio between the flexspline 134 and the circular spline 132 can be changed by the rotation of the cam 131 of the wave generator 136.
[0070]
That is, when the cam 131 is rotated inside the flexspline 134, the openings of the flexspline 134 are sequentially elastically deformed, and the elliptical shape appears to rotate. Then, due to the elastic deformation of the flexspline 134, the meshing position between the flexspline 134 and the circular spline 132 moves in the circumferential direction.
[0071]
Here, as described above, the spline teeth of the flex spline 134 and the spline teeth of the circular spline 132 are formed with the same pitch, while the number of spline teeth of the circular spline 132 is determined by the number of the spline teeth of the flex spline 134. Are two more than the number of spline teeth. Therefore, one rotation of the cam 131 causes relative rotation between the flexspline 134 and the circular spline 132 while the meshing position between the flexspline 134 and the circular spline 132 moves by one rotation in the circumferential direction. .
[0072]
The wave gear reducer 130 is configured to change the transmission ratio between the flexspline 134 and the circular spline 132 according to the relative rotation amount, as shown in FIG.
The retaining ring 138 (FIG. 1) that engages with the flex spline 134 has the same pitch and the same number of spline teeth as the spline teeth of the flex spline 134. Therefore, even if the cam 131 rotates, no relative rotation occurs between the flexspline 134 and the retaining ring 138.
That is, the variable transmission ratio mechanism 10 of the present embodiment is configured such that the rotation of the cam 131 causes relative rotation between the holding ring 138 (FIG. 1) and the circular spline 132.
[0073]
Therefore, as shown in FIG. 1, the motor shaft 152 is integrated with the second steering shaft 120 rotating integrally with the retaining ring 138 and the first steering shaft 110 rotating integrally with the circulator spline 132. The relative rotation is generated by the rotation of the cam 131 that rotates.
As described above, the transmission ratio variable mechanism 10 can change the transmission ratio between the first steering shaft 110 and the second steering shaft by the rotation input from the drive motor 150.
[0074]
A method of controlling the variable transmission ratio mechanism 10 and the EPS actuator 60 in the vehicle steering system 1 configured as described above will be described with reference to the block diagram of FIG.
As shown in FIG. 3, the vehicle steering system 1 of the present embodiment executes two processes of a control process of the EPS actuator 60 by the first ECU 601 and a control process of the transmission ratio variable mechanism 10 by the second ECU 101 in parallel. ing. That is, the vehicle steering system 1 has a function of variably controlling the transmission ratio of the transmission ratio variable mechanism 10 by the second ECU 101 and a function of appropriately controlling the assist force of the EPS actuator 60 by the first ECU 601.
[0075]
The second ECU 101 that performs the control process of the transmission ratio variable mechanism 10 performs control of the first steering shaft 110 based on a steering angle signal output from the torque sensor 40 in parallel with the rotational torque value and a vehicle speed signal from the vehicle speed sensor 70. An appropriate transmission ratio between the first steering shaft 120 and the second steering shaft 120 is calculated.
[0076]
Further, the second ECU 101 calculates a motor voltage to be supplied to the drive motor 150 in order to realize an appropriate transmission ratio. Then, the second ECU 101 controls the transmission ratio between the first steering shaft 110 and the second steering shaft 120 appropriately by driving the drive motor 150 with the calculated motor voltage.
[0077]
In addition, the first ECU 601 that executes the assist force control process by the EPS actuator 60 receives the rotational torque value of the first steering shaft 110 output from the torque sensor 40 and the vehicle speed signal from the vehicle speed sensor 70, and Calculate assist power. Further, the first ECU 601 controls the EPS actuator 60 so that the assist force is appropriate.
[0078]
Thus, according to the vehicle steering system 1 of the present embodiment, the transmission ratio between the first steering shaft 110 as the input rotation shaft and the second steering shaft 120 as the output rotation shaft in the transmission ratio variable mechanism 10. Can be changed by the rotation of the output shaft 151 of the drive motor 150.
[0079]
In particular, in the transmission ratio variable mechanism 10 of the present embodiment, the drive motor 150 is fixedly installed so as not to be affected by the rotation operation of the first steering shaft 110 and the second steering shaft 120. The rotation of the output shaft 151 of the drive motor 150 is input to the wave gear reducer 130 via a motor shaft 152 arranged so as to have a double structure substantially coaxially with the second steering shaft 120.
[0080]
Therefore, in the vehicle steering system 1 of the present embodiment, the entire drive motor 150 does not rotate following the first steering shaft 110 and the second steering shaft 120.
Therefore, there is no need to connect a spiral flat cable to the drive motor 150 as in the related art. Therefore, the vehicle steering system 1 has a small and highly reliable transmission ratio variable mechanism 10 which eliminates various problems caused by the spiral flat cable.
[0081]
(Example 2)
This embodiment is an example in which the speed reducer constituting the transmission ratio variable mechanism in the first embodiment is changed.
As shown in FIG. 5, the variable transmission ratio mechanism 10 of this example has a planetary gear reducer 510. The planetary gear reducer 510 is associated with a sun gear 511 disposed at the center, four planet gears 512 which are configured to engage with the sun gear 511 and rotate around the sun gear 511, and a planet gear 512. It comprises a ring gear 515 that fits.
[0082]
In this example, a ring gear 515 is formed on the inner peripheral surface along the axial direction of the concave portion 188 of the flange 180 that engages with the first steering shaft 110. The sun gear 511 is fixed by a key (not shown) after the motor shaft 152 is press-fitted.
Further, at the joint portion 127 of the second steering shaft 120, four rotation shafts 513 substantially parallel to the axial direction are provided, and the planet gears 512 are rotatably held by the rotation shafts 513.
[0083]
In the transmission ratio variable mechanism 10, the transmission ratio between the first steering shaft 110 and the second steering shaft 120 can be changed by rotating the drive motor 150 and rotating the sun gear 511.
The other configuration and operation and effect are the same as in the first embodiment.
[0084]
(Example 3)
This embodiment is an example in which the speed reducer constituting the transmission ratio variable mechanism in the first embodiment is changed.
As shown in FIG. 6, the variable transmission ratio mechanism 10 of this embodiment has a differential gear reducer 520 using planetary gears. The differential reducer 520 is configured to generate relative rotation between a first steering shaft that rotates integrally with the flange 180 and a second steering shaft by rotation of the four planet gears 521. It is. In this example, the four planet gears 521 are configured to be rotatable by rotation of the output shaft 151 of the drive motor 150.
[0085]
At the end of the motor shaft 152 connected to the output shaft 151 of the drive motor 150 on the side of the differential reducer 520, a carrier portion 15 having a larger diameter than the shaft diameter of the motor shaft 152 is formed. On the end face of the carrier part 158 on the side of the differential reducer 520, four rotating shafts 159 parallel to the axial direction are provided. A planet gear 521 is rotatably attached to the rotating shaft 159.
[0086]
Each planet gear 521 engages with a first ring gear 525 formed on the inner peripheral surface of the concave portion 188 of the flange 180 and a second ring gear formed on the inner peripheral surface of the concave portion 128 of the second steering shaft 120. 524. Here, the same number of teeth are formed in a portion of the planet gear 521 that meshes with the first ring gear 525 and a portion that meshes with the second ring gear 524.
[0087]
Further, the number of teeth of the first ring gear 525 is two less than the number of teeth of the second ring gear 524. That is, the first steering shaft 110 connected to the flange 180 and the second steering shaft 120 are relatively rotated in accordance with the rotation of the planet gear 521 due to the rotation of the motor shaft 152. .
[0088]
Therefore, in the transmission ratio variable mechanism 10, the transmission ratio between the first steering shaft 110 and the second steering shaft 120 can be changed by rotating the drive motor 150 to rotate the planet gear 521. it can.
The other configuration and operation and effect are the same as in the first embodiment.
[0089]
(Example 4)
This embodiment is an example in which the arrangement structure of the motor shaft of the first embodiment and the second steering shaft is changed.
In the transmission ratio variable mechanism 10 of the present embodiment, as shown in FIG. 7, a second steering shaft is coaxially arranged on the inner periphery of a motor shaft having a hollow through structure.
[0090]
The motor shaft 152 of this example is a member having a substantially cylindrical shape that is shorter in the axial direction than the second steering shaft 120. The end of the second steering shaft 120 on the side of the wave gear reducer 130, on which the pinion gear 125 is not formed, is housed.
[0091]
The end of the motor shaft 152 on the side of the wave gear reducer 130 is press-fitted into a through hole of a cam 131 of the wave gear reducer 130, and both are connected by a key (not shown). The other end of the motor shaft 152 has a gear portion 157 having a diameter larger than that of the end portion for press-fitting the cam 131. A driven gear 224 that engages with a drive gear 223 attached to the output shaft 151 of the drive motor 150 is formed on the outer peripheral surface of the gear portion 157.
[0092]
The second steering shaft 120 is housed inside the motor shaft 152 and protrudes from the end of the motor shaft 152 toward the first steering shaft 110. A diaphragm 139, which is the bottom of the cup-shaped flexspline 134, is joined to the end surface of the second steering shaft 120 so that the second steering shaft 120 and the flexspline 134 rotate integrally.
The other configuration and operation and effect are the same as in the first embodiment.
[0093]
(Example 5)
This embodiment is an example in which the vehicle steering system in the first embodiment is changed to a hydraulic type, and the arrangement structure of the drive motors and the like are changed.
In the steering gear box 11 of this example, as shown in FIG. 8, the transmission ratio variable mechanism 10 is assembled between the second steering shaft 120 and the servo valve 29 for hydraulic control.
[0094]
In this example, a wave motion is used in which a transmission shaft portion 280 that is a part of the first steering shaft 110 and a motor shaft 152 that is an output shaft of the drive motor 150 are used as rotation input shafts, and the second steering shaft 120 is used as a rotation output shaft. The variable transmission ratio mechanism 10 is configured using the gear reducer 130.
Here, the motor shaft 152 is coaxially arranged on the outer peripheral side of the transmission shaft portion 280. Therefore, the motor shaft 152 and the transmission shaft section 280 have a double structure arranged coaxially.
[0095]
In the wave gear reducer 130 of this embodiment, as shown in FIG. 8, the arrangement of the circular spline 132 extrapolated to the flexspline 134 and the holding ring 138 are reversed from those of the first embodiment.
That is, the circular spline 132 that rotates integrally with the first steering shaft 110 is disposed on the steering rod 190 side, and the holding ring 138 that rotates integrally with the second steering shaft 120 is disposed on the first steering shaft 110 side.
[0096]
The motor shaft 152 is fitted into the cam 131 of the wave generator 136 constituting the wave gear reducer 130, and is fixed by keying.
The transmission shaft portion 280 inserted into the motor shaft 152 has a projecting end 281 projecting from the end of the motor shaft 152 toward the steering rod 190. A transmitting member 282 is fixed to the outer periphery of the protruding end 281 by a key.
The transmission member 282 has a cylindrical portion 283 extending toward the wave gear reducer 130. A circular spline 132 of the wave gear reducer 130 is spline-coupled to the inner periphery of the cylindrical portion 283 having the spline teeth.
[0097]
Further, a concave portion 129 capable of accommodating the projecting end portion 281 of the transmission shaft portion 280 is formed on the end surface of the second steering shaft 120 on the side of the wave gear reducer 130. The transmission shaft 280 is rotatably supported via a bearing disposed on the inner peripheral surface of the recess 129.
[0098]
Further, a flange portion 121 having a larger diameter than the cylindrical portion 283 of the transmission member 282 is formed at an end of the second steering shaft 120 on the concave portion 129 side. The transmission member 270 having a substantially cylindrical shape and having a flange portion 271 which is a joining surface with the flange portion 121 is bolted to the flange portion 121.
An inner spline tooth 272 that engages with a spline tooth formed on the outer circumference of the holding ring 138 is formed on an inner circumference of an end of the transmission member 270 opposite to the flange 271 in the axial direction.
[0099]
Further, in the steering gear box 11 of the vehicle steering system of the present embodiment, a servo valve 29 for hydraulic control is provided instead of the torque sensor in the first embodiment.
As shown in FIG. 8, the first steering shaft 110 of the present embodiment has a small diameter portion 112 as a torsion bar portion, and has a structure in which the tip of the small diameter portion 112 is splined to the transmission shaft portion 280.
Then, when the rotational driving force is transmitted to the transmission shaft portion 280, the small diameter portion 112 can be slightly twisted.
[0100]
On the other hand, as shown in FIG. 8, the spool 170 is engaged with the first steering shaft 110 by the spline teeth 111 formed closer to the steering handle than the small diameter portion 112. Therefore, the twist generated in the small-diameter portion 112 is manifested as relative rotation between the spool 170 and the transmission shaft portion 280.
[0101]
In the first steering shaft 110 of the present embodiment, a rotary servo valve 29 for hydraulic control is provided using the small diameter portion 112 acting as a torsion bar portion.
The servo valve 29 of this embodiment is rotatably housed in a rotor valve member 118 formed on a spool 170 and a gap between the rotor valve member 118 and the shaft housing 210, and is provided with a transmission shaft 280 by a connecting pin 117. And a sleeve valve member 295 connected thereto. The servo valve 29 forms a rotary four-port throttle switching valve having a supply port 291, a discharge port 292, and a pair of supply and discharge ports 293 and 294.
The pair of supply / discharge ports 293 and 294 are connected to left and right chambers of a power cylinder (not shown) for assisting the operation of the steering rod 190.
[0102]
As described above, in the above-described hydraulic vehicle steering system, the steering gear box 11 is formed compact by integrating the servo valve 29 and the transmission ratio variable mechanism 10 and the like.
The integrated structure of the steering gear box 11 is realized by a characteristic configuration in which the transmission shaft portion 280 and the motor shaft 152 are arranged so as to exhibit a coaxial double structure.
The other configuration and operation and effect are the same as in the first embodiment.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a gearbox having a variable transmission ratio mechanism according to a first embodiment.
FIG. 2 is an explanatory diagram illustrating a configuration of a vehicle steering system according to the first embodiment.
FIG. 3 is a block diagram illustrating a configuration of a vehicle steering device according to the first embodiment.
FIG. 4 is a front view showing the wave gear drive according to the first embodiment.
FIG. 5 is a cross-sectional view illustrating a gear box having a built-in transmission ratio variable mechanism according to a second embodiment.
FIG. 6 is a cross-sectional view illustrating a gearbox having a built-in transmission ratio variable mechanism according to a third embodiment.
FIG. 7 is a cross-sectional view illustrating a gear box having a built-in transmission ratio variable mechanism according to a fourth embodiment.
FIG. 8 is a cross-sectional view illustrating a gearbox having a built-in transmission ratio variable mechanism according to a fifth embodiment.
FIG. 9 is an explanatory diagram showing a configuration of a vehicle steering system in a conventional example.
FIG. 10 is a sectional view showing a transmission ratio variable mechanism in a conventional example.
11 is a view showing a flat cable housed inside a cover in a conventional example, and is a cross-sectional view taken along line AA in FIG. 10;
[Explanation of symbols]
1. . . Vehicle steering system,
10. . . Variable transmission ratio mechanism,
11. . . Steering gear box,
110. . . First steering shaft,
118. . . Rotor valve member,
120. . . The second steering shaft,
150. . . Drive motor,
151. . . Output shaft,
152. . . Motor shaft,
190. . . Steering rod,
210. . . Shaft housing,
220. . . Gear housing,
280. . . Transmission shaft,
29. . . Servo valve
291. . . Supply port,
292. . . Discharge port,
293,294. . . Supply and discharge port,
295. . . Sleeve valve member,
300. . . Steering wheel,

Claims (16)

A variable transmission ratio mechanism for changing a transmission ratio of a rotational operation between a first steering shaft that rotates integrally with a steering wheel and a second steering shaft connected to a steering rod for steering a steered wheel. Vehicle steering system having
The transmission ratio variable mechanism includes a drive motor, a motor shaft for transmitting rotation of an output shaft of the drive motor, and a rotation speed input from the first steering shaft according to the rotation speed of the motor shaft. And a speed reducer configured to change a transmission ratio between the rotation speed outputted to the second steering shaft and the rotation speed.
The motor shaft and the second steering shaft have a double structure arranged substantially coaxially, and the drive motor rotates either the first steering shaft or the second steering shaft. A vehicle steering system wherein the output shaft is connected to the motor shaft in a state where the output shaft is fixed so as not to be affected by the motor. 2. The vehicle steering system according to claim 1, wherein the reduction gear is a wave gear reduction gear. 2. The vehicle steering system according to claim 1, wherein the speed reducer is a planetary gear speed reducer. The vehicle according to any one of claims 1 to 3, wherein the second steering shaft has a hollow through hole, and the motor shaft penetrates the hollow through hole. Steering gear. The steering wheel according to any one of claims 1 to 4, wherein a rack gear is formed on the steering rod, and a pinion gear is formed on the second steering shaft.
A steering apparatus for a vehicle, wherein the rack gear and the pinion gear are engaged in a steering gear box accommodating at least a part of the steering rod and the second steering shaft. 6. The vehicle steering system according to claim 5, wherein the variable transmission ratio mechanism including the drive motor and the speed reducer is incorporated in the steering gear box. The vehicle steering system according to any one of claims 1 to 6, wherein the output shaft and the motor shaft are indirectly connected via a gear train. A variable transmission ratio mechanism for changing a transmission ratio of a rotational operation between a first steering shaft that rotates integrally with a steering wheel and a second steering shaft connected to a steering rod for steering a steered wheel. Vehicle steering system having
The transmission ratio variable mechanism includes a drive motor, a motor shaft for transmitting rotation of an output shaft of the drive motor, and a rotation speed input from the first steering shaft according to the rotation speed of the motor shaft. And a speed reducer configured to change a transmission ratio between the rotation speed outputted to the second steering shaft and the rotation speed.
The motor shaft and the first steering shaft have a double structure arranged substantially coaxially, and the drive motor rotates either the first steering shaft or the second steering shaft. A vehicle steering system wherein the output shaft is connected to the motor shaft in a state where the output shaft is fixed so as not to be affected by the motor. 9. The device according to claim 8, wherein the first steering shaft has a transmission shaft for transmitting a rotational driving force of the first steering shaft, and the rotational driving force of the first steering shaft is controlled by the transmission shaft. And is configured to be input to the reduction gear through
The vehicle steering apparatus according to claim 1, wherein the transmission shaft and the motor shaft are arranged substantially coaxially so as to exhibit a double structure. 10. The vehicle steering system according to claim 8, wherein the speed reducer is a wave gear speed reducer. 10. The vehicle steering system according to claim 8, wherein the speed reducer is a planetary gear speed reducer. The vehicle according to any one of claims 8 to 11, wherein the motor shaft has a hollow through-hole, and the hollow through-hole passes through the first steering shaft. Steering gear. In any one of claims 8 to 12, a rack gear is formed on the steering rod, and a pinion gear is formed on the second steering shaft.
A steering apparatus for a vehicle, wherein the rack gear and the pinion gear are engaged in a steering gear box accommodating at least a part of the steering rod and the second steering shaft. 14. The vehicle steering system according to claim 13, wherein the variable transmission ratio mechanism including the drive motor and the speed reducer is incorporated in the steering gear box. The vehicle steering system according to claim 14, further comprising: an oil pump that generates a hydraulic pressure; and a power cylinder that drives the steering rod by the hydraulic pressure.
The first steering shaft has a torsion bar configured to generate a torsion in accordance with a rotational torque acting on the first steering shaft.
The steering gear box according to claim 1, wherein the steering gear box includes a servo valve configured to switch an oil path from the oil pump to the power cylinder in response to the torsion of the torsion bar. The vehicle steering system according to any one of claims 8 to 15, wherein the motor shaft is formed integrally with the output shaft of the drive motor.

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