JP2006232049A - Electric steering device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric steering device capable of certainly maintaining engagement with a belt with helical teeth and efficiently manufactured by facilitating processing and assembling work of a tooth part of a driven pulley. <P>SOLUTION: A ball nut 21 is externally inserted into a ball screw stem 19 to be furnished on a steering member 6 reciprocating by turning of a steering wheel through a ball 20. A driving pulley 12 with helical teeth is provided on a drive shaft of an electric motor 10, and a driven pulley 13 with helical teeth is provided on the ball nut 21. The driving pulley 12 and the driven pulley 13 are connected to each other through the belt 14 with the helical teeth. The driving pulley 12 regulates a position of the belt 14 within specified width in the axial direction by both flanges 25 on both ends in the axial direction. Widened parts 13a, 13b of width dimensions (b) larger than regulated width (a) of the belt 14 by the both flanges 25 of the driving pulley 12 are provided on the driven pulley 13 without providing a flange. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an electric steering apparatus that applies auxiliary torque by an electric motor to steering torque from a steering wheel.

  Conventionally, as this type of electric steering device, a steering member that reciprocates in the longitudinal direction according to the rotation of a steering wheel, and a ball that is extrapolated via a plurality of balls to a ball screw shaft formed on the steering member There are known ones including a nut, a drive pulley provided on a drive shaft of an electric motor, and a driven pulley connected to the drive pulley via a belt and rotating integrally with the ball nut (for example, Patent Document 1). According to this, since the belt is interposed in the power transmission path between the electric motor and the steering member, vibration from the steering member is not transmitted to the electric motor, and the rotation accuracy of the electric motor is maintained. Can do.

  Further, in this type of electric steering apparatus, both pulleys and belts are formed by adopting toothed pulleys for both pulleys of the drive pulley and the driven pulley, and making the belts spanned between the pulleys be toothed belts. It has been done to prevent slipping. Furthermore, in order to reduce vibration and noise due to meshing between the teeth of the belt and the teeth of each pulley, a belt with a helical tooth is adopted, and a pulley with a helical tooth corresponding to the helical tooth of the belt is used as a driving pulley. And a driven pulley are known (see, for example, Patent Document 2).

By the way, when the helical belt is wound around the helical driving pulley and the helical driven pulley, the helical belt receives an axial thrust force due to the meshing of the helical teeth. As a result, the belt passing position with respect to the pulley is easily shifted in the axial direction (width direction), and there is a possibility that the meshing state at the time of rotation cannot be maintained. For this reason, each pulley is provided with flanges that project in the form of flanges at both ends in the axial direction, and the position of the belt is regulated within a predetermined axial width by this flange.
JP 2003-291830 A JP 2004-314770 A

  However, since each pulley must form a tooth portion between both flanges, there is an inconvenience that the flange becomes an obstacle when forming the tooth portion, and it is difficult to process the tooth portion. Moreover, even in the assembly work when the belt is passed, there is an inconvenience that the flange becomes an obstacle and the work efficiency is lowered.

  In order to facilitate the processing of the teeth on the pulley and the belt passing work, it may be possible to detachably attach the flange from the pulley body, but the number of parts increases and the number of assembly steps increases. However, there is a disadvantage that the manufacturing efficiency is lowered.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an electric steering apparatus that can reliably maintain meshing with a toothed belt, and that can be easily and efficiently manufactured by easily processing and assembling a tooth portion of a driven pulley. There is.

  The present invention is an electric steering device that applies an auxiliary torque by an electric motor to a steering torque from a steering wheel, a rod-like steering member that reciprocates in the longitudinal direction in accordance with the rotation of the steering wheel, and the steering member A ball nut externally inserted through a plurality of balls to the formed ball screw shaft, a helical drive pulley provided on the drive shaft of the electric motor, and a helical belt attached to the drive pulley And a driven pulley with a helical tooth that rotates integrally with the ball nut, and the drive pulley restricts the position of the belt at both ends in the axial direction within a predetermined axial width. A pair of flanges, the driven pulley does not have flanges at both ends in the axial direction, and is larger than the regulation width of the belt by both flanges of the drive pulley. Characterized as having an axial width.

  In the present invention, the auxiliary torque of the electric motor is transmitted to the steering member via a belt that spans the drive pulley and the driven pulley. That is, the driven pulley rotates the ball nut and reciprocates the steering member in the longitudinal direction via a ball screw shaft formed on the steering member.

  A belt with a helical tooth is adopted as the belt, and a helical tooth corresponding to a helical tooth formed on the belt is formed on the driving pulley and the driven pulley. As a result, the belt and both pulleys are smoothly engaged to reduce vibration and noise.

  In the present invention, since the driven pulley is not provided with a flange, the flange does not get in the way when processing and forming the teeth on the outer peripheral surface of the driven pulley, and it is easy to process the teeth on the driven pulley. Can be done. Moreover, even in the assembly work when the belt is wound around the driven pulley, the work is facilitated by not providing the flange.

  Further, in the present invention, even if the belt is displaced in the axial direction (width direction) of the drive pulley due to the meshing of the helical teeth, the drive pulley is regulated by both flanges by providing flanges at both ends of the drive pulley. Engagement with the pulley is maintained.

  On the other hand, since the driven pulley does not include the flange, the belt stretched around the driven pulley is not restricted from the axial direction (width direction). For this reason, even if the belt stretched around the drive pulley is displaced to one end side of the drive pulley and restricted by one flange of the drive pulley, the belt stretched around the driven pulley is affected by the elongation of the belt itself. For example, a deviation larger than the belt regulation width by both flanges of the drive pulley may occur.

  Therefore, in the present invention, the driven pulley has a larger axial width than the belt regulation width by both flanges of the drive pulley, so that even if the belt stretched around the driven pulley is displaced during rotation. The meshing can be maintained well without the belt being detached from the driven pulley.

  By the way, in this kind of electric steering device, if the width dimension of the driven pulley is too large, a large space is required for mounting the driven pulley, and the device may be enlarged.

  Therefore, the driven pulley according to the present invention has widened portions on both sides in the axial direction projecting outward from the restricted width of the belt by both flanges of the drive pulley, and the width dimensions of each widened portion are the drive pulley and the driven pulley. It is preferable to select from the range of 1 mm to 5.5 mm according to the lower limit set value of the tension applied to the belt stretched over.

  A lower limit of tension is set in advance on the belt that is stretched between the driving pulley and the driven pulley in order to prevent overload and disengagement during rotation. The tension of the belt can be set, for example, by adjusting the distance between the driving pulley and the driven pulley to a dimension that gives a predetermined tension to the belt. In many cases, the lower limit of tension to be set is usually 35N to 50N, and the present inventor used a belt with a helical tooth in various tests. It was found that the tension of the belt and the belt displacement relative to the driven pulley are inversely proportional. Based on this knowledge, when the lower limit set value of the tension applied to the belt is large, the width of the widened portion of the driven pulley is set to 1 mm so that the belt does not come off the driven pulley and the meshing is good. Can be maintained. Moreover, the width of the driven pulley does not become excessively large and the driven pulley can be formed relatively compact, so that the apparatus is not enlarged. Furthermore, the present inventor has found through various tests that the amount of deviation when the belt tension is 0 N is 5.5 mm. According to this, even when the belt tension is lower than the lower limit set value for some reason, if the width dimension of the widened portion is set to 5.5 mm, the belt does not come off from the driven pulley and the engagement is good. Can be maintained. Therefore, the driven pulley can be made relatively compact to prevent the apparatus from becoming large.

  An embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is an explanatory view showing an electric steering apparatus of the present embodiment, FIG. 2 is a cross-sectional explanatory view of a main part, FIG. 3 is an explanatory view showing an attachment state of an electric motor, and FIG. FIG. 5 is a diagram showing the relationship between the belt tension and the amount of deviation.

  As shown in FIG. 1, the electric steering apparatus 1 of the present embodiment includes a steering mechanism 2 and an auxiliary torque mechanism 3 that applies an auxiliary torque to the steering mechanism 2. The steering mechanism 2 is configured to reciprocate the steering member 6 in the housing 5 in the longitudinal direction by inputting rotation of a steering wheel (not shown) of the vehicle to the input shaft 4. That is, the rotation of the steering wheel input to the input shaft 4 is converted into the reciprocating motion of the steering member 6 by the conversion mechanism 7 such as a rack and pinion mechanism. The conversion mechanism 7 is provided with a torque sensor 8. The torque sensor 8 detects the steering torque input to the input shaft 4.

  Tie rods 9 are connected to both ends of the steering member 6. Each tie rod 9 is connected to a steerable wheel (not shown) of the vehicle. A steering motion is imparted to the wheels by the steering member 6 moving linearly in the longitudinal direction.

  The auxiliary torque mechanism 3 includes an electric motor 10 attached to the housing 5 and a torque transmission mechanism 11 that transmits auxiliary torque generated by the electric motor 10 to the steering member 6. The electric motor 10 is controlled by a control means (not shown) that inputs a detection signal of the torque sensor 8, and generates an auxiliary torque corresponding to the steering torque detected by the torque sensor 8.

  As shown in FIG. 2, the torque transmission mechanism 11 includes a drive pulley 12 connected to the electric motor 10, a driven pulley 13 connected to the steering member 6, and a belt 14 stretched between the pulleys 12 and 13. It is comprised by. The drive pulley 12 is supported via a rotating shaft 18 between a pair of ball bearings 16 and 17 that are fitted and held inside a support case 15 of the electric motor 10. The rotating shaft 18 of the drive pulley 12 is connected to the output shaft of the electric motor 10 and is driven by the electric motor 10. The rotation of the drive pulley 12 is transmitted to the driven pulley 13 via the belt 14, and the rotation of the driven pulley 13 is applied to the reciprocating motion of the steering member 6 as an auxiliary force.

  That is, a ball screw shaft 19 is formed on the steering member 6 corresponding to the position of the electric motor 10, and a ball nut 21 is coupled to the ball screw shaft 19 via a plurality of balls 20. The ball nut 21 is attached to the housing 5 of the steering member 6 by an angular ball bearing 22 so as to be rotatable and immovable in the axial direction. The driven pulley 13 is fastened and fixed to a ball nut 21 and rotates integrally with the ball nut 21.

  The belt 14 is a belt with a helical tooth. The driving pulley 12 and the driven pulley 13 have a plurality of teeth corresponding to the helical teeth formed on the belt 14 and inclined at a predetermined angle in the axial direction and extending at a predetermined interval in the circumferential direction. A portion 23 is formed. By meshing the teeth 23 with the teeth of the belt 14, the rotational force of the drive pulley 12 is efficiently transmitted to the belt 14, and vibration and noise during rotation are reduced by meshing with the helical teeth. .

  The drive pulley 12 includes a pulley body 24 formed integrally with the rotary shaft 18 and a pair of regulating members 25 provided on both sides of the pulley body 24 in the axial direction. The tooth portion 23 is formed on the outer periphery of the pulley body 24. By configuring the drive pulley 12 with the pulley main body 24 and the pair of restricting members 25, the tooth portion 23 can be processed on the pulley main body 24 before the restricting member 25 is attached, and the processing operation of the tooth portion 23 is extremely easy. To be able to do that. Each regulating member 25 has a peripheral portion that projects in a hook shape in the outer peripheral direction of the pulley body 24 and acts as a flange. That is, when the belt 14 moves in the axial direction of the pulley main body 24, the belt 14 is regulated within a regulation width by the interval between the two regulating members 25 to prevent the pulley 14 from coming off.

  The driven pulley 13 is not provided with a flange or the like that restricts movement of the belt 14 in the axial direction (width direction), and is formed wider than the restriction width of the belt 14 by the drive pulley 12. That is, as will be described in detail later, as shown in FIG. 4, the widening that is larger than the regulation width a of the drive pulley 12 on both axial sides of the driven pulley 13 with respect to the regulation width a of the drive pulley 12. Portions 13a and 13b are provided. And each width dimension b (henceforth expansion width b) of the wide parts 13a and 13b of the axial direction both sides of the driven pulley 13 is set to 1 mm-5.5 mm about the one side.

  As shown in FIG. 2, the electric motor 10 is attached to a motor attachment portion 26 formed in the housing 5 via the support case 15. As shown in FIG. 3, the electric motor 10 is connected to the support case 15 by a pair of bolts 28 via a connecting portion 27 that projects to the outer periphery of the front end portion. Further, the support case 15 and the motor mounting portion 26 are connected by a pair of bolts 29 so that the tension of the belt 14 spanned between the drive pulley 12 and the driven pulley 13 can be adjusted. That is, as shown in FIG. 3, a pair of bolt holes 30 and 31 are formed in the motor mounting portion 26 at positions opposed to each other in the radial direction, and one of the bolt holes 31 is formed in a long hole shape. . As a result, the electric motor 10 has the bolt 29 inserted into the other elongated hole 31 with the bolt 29 inserted into the one bolt hole 30 of the motor mounting portion 26 as a fulcrum. It swings as guided by. As a result, the distance between the shaft center of the drive pulley 12 and the shaft center of the driven pulley 13 can be separated or approached so that the tension of the belt 14 spanned between the drive pulley 12 and the driven pulley 13 can be adjusted. It has become. By applying tension to the belt 14, sagging of the belt 14 during rotation is prevented. The lower limit of the tension of the belt 14 is normally set to 35N to 50N.

  Here, the relationship between the width dimension set in the driven pulley 13 and the lower tension limit of the belt 14 in this embodiment will be described. As shown in FIG. 4, when the belt 14 is stretched between the drive pulley 12 and the driven pulley 13 and the drive pulley 12 is rotated at a predetermined rotation speed in one direction, the teeth of the belt 14 and the pulleys are separated from each other. Due to the meshing, the spanning position of the belt 14 to the driven pulley 13 is biased to one side. The belt 14 is regulated by one regulating member 25 of the drive pulley 12, but in a portion stretched around the driven pulley 13, the belt 14 is displaced outward in the axial direction from the regulation position by the regulating member 25. This displacement amount c changes according to the tension applied to the belt 14, and according to the test, as shown in FIG. 5, the displacement amount c is 4 mm at a tension of 35 N, and the displacement amount c is 1 mm at a tension of 50 N. Is also small. Further, when the tension is 0 N, the shift amount c is 5.5 mm. As is clear from this, according to the tension applied to the belt 14, the shift amount c in the tension is set to the expansion width b on both sides in the axial direction of the driven pulley 13, and each of the widening portions 13a and 13b is set. By setting the enlarged width b, it is possible to prevent the belt 14 from coming off the driven pulley 13 without providing the driven pulley 13 with means for restricting the movement of the belt 14 such as a flange. The lower limit set value of the tension applied to the belt 14 is normally 35N to 50N, and even if it is considered that the lower limit set value is lowered for some reason, the expansion width b of the driven pulley 13 is increased. By providing the widened portions 13a and 13b which are set to 5.5 mm, the belt 14 is not detached from the driven pulley 13.

  Next, the operation of this embodiment will be described. When the vehicle is in a straight traveling state and the steering force of the steering wheel is not input to the input shaft 4, the torque sensor 8 does not generate an output signal, and the electric motor 10 connected to the shaft of the drive pulley 12 generates auxiliary torque. do not do. At this time, the steering member 6 also does not move, and the steering force does not act on the wheels (not shown).

  On the other hand, when the vehicle is about to turn a curve, the driver turns the steering wheel. At this time, the steering force applied to the input shaft 4 is transmitted to the steering member 6 via the conversion mechanism 7 and is transmitted to the wheels via the tie rod 9. At the same time, torque corresponding to the steering force applied to the input shaft 4 is detected by the torque sensor 8, and the rotation of the electric motor 10 driven based on the detection signal causes the drive pulley 12, the driven pulley 13, and the ball nut 21. The auxiliary force is applied to the steering member 6 through the ball screw shaft 19.

  In the present embodiment, the drive pulley 12 and the driven pulley 13 employ helical gears to efficiently transmit auxiliary torque. As described above, the drive pulley 12 and the pulley body 24 are paired with the pair of pulleys. By constituting the regulating member 25 and not providing the driven pulley 13 with a flange or the like, the workability of the tooth portion 23 with respect to the driving pulley 12 and the driven pulley 13 is good. Further, since the driven pulley 13 is not provided with a flange or the like, there is no obstacle when assembling the belt 14 and the assemblability is good. Furthermore, since the widened portions 13a and 13b of the driven pulley 13 are set to the above-described enlarged width b, the belt 14 is prevented from coming off from the driven pulley 13 without the driven pulley 13 having a flange or the like. Moreover, since the expansion width b is 5.5 mm even when the maximum width is set, the expansion of the mounting space of the driven pulley 13 inside the housing 5 can be suppressed to an extremely small size, and an increase in the size of the apparatus can be prevented. .

Explanatory drawing which shows the electric steering device of one Embodiment of this invention. Cross-sectional explanatory drawing of the principal part in the electric steering device of this embodiment. Explanatory drawing which shows the attachment state of an electric motor. Explanatory drawing which shows the deviation | shift amount of a belt. The diagram which shows the relationship between the tension | tensile_strength of a belt, and deviation | shift amount.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Electric steering device, 6 ... Steering member, 10 ... Electric motor, 12 ... Helical drive pulley, 13 ... Helical driven pulley, 13a, 13b ... Widening part, 14 ... Helical belt DESCRIPTION OF SYMBOLS 19 ... Ball screw shaft, 20 ... Ball, 21 ... Ball nut, 25 ... Restriction member (flange), a ... Restriction width, b ... Expansion width (width dimension of each widening part).

Claims (2)

An electric steering device that applies auxiliary torque by an electric motor to steering torque from a steering wheel,
A rod-like steering member that reciprocates in the longitudinal direction in accordance with the rotation of the steering wheel, a ball nut that is externally inserted via a plurality of balls on a ball screw shaft formed on the steering member, and a drive shaft of the electric motor Comprising a helically driven pulley provided on the helical pulley, and a helically driven pulley connected to the driven pulley via a helical belt and rotating integrally with the ball nut.
The drive pulley includes a pair of flanges that restrict the position of the belt within a predetermined axial width at both ends in the axial direction;
The driven pulley does not have flanges at both ends in the axial direction, and has an axial width larger than a regulation width of a belt by both flanges of the drive pulley.   The driven pulley has widened portions on both sides in the axial direction that project outward from the belt regulation width by both flanges of the driving pulley, and the width dimension of each widened portion is spanned between the driving pulley and the driven pulley. 2. The electric steering apparatus according to claim 1, wherein the electric steering apparatus is selected from a range of 1 mm to 5.5 mm in accordance with a lower limit set value of tension applied to the belt.

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