JPWO2020202270A1 - Transmission device and steering device for vehicles using it - Google Patents

Abstract

The transmission device (1) is positioned so as to be able to roll on a screw shaft (20) housed in a tubular housing (2) and a screw portion (22) of the screw shaft (20). A plurality of balls (30), a nut (40) connected to the screw portion (22) by the plurality of balls (30), and the nut (40) can be rotated inside the housing (2). Includes supporting bearings (50). The nut (40) has a large diameter portion (44) and a small diameter portion (45) that is connected to the large diameter portion (44) in the axial direction of the screw shaft (20). The large diameter portion (44) has a circulation portion (70) on the outer peripheral surface (44a). The circulation portion (70) circulates the plurality of balls (30) rolling around the screw portion (22). The small diameter portion (45) has a smaller diameter than the large diameter portion (44). The bearing (50) supports the small diameter portion (45) in the nut (40).

Description

The present invention relates to a transmission device including a ball screw that converts a rotary motion into a linear motion and / or a linear motion into a rotary motion, and an improved technique of a steering device for a vehicle using the transmission device.

The ball screw is composed of a screw shaft, a plurality of balls, and a nut connected to the screw portion by the plurality of balls. A plurality of balls rolling on the screw portion circulate through a circulation passage (circulation portion) provided in the nut. A vehicle steering device using such a transmission device including a ball screw is known, for example, according to Reference 1.

In the transmission device of the vehicle steering device known in Patent Document 1, the screw shaft of the ball screw is housed in a tubular housing extending in the vehicle width direction, and is movable along the housing. .. The steering driving force generated by the electric motor is transmitted to the nut by the pulley, and further transmitted from the nut to the screw shaft via a plurality of balls. The screw shaft slides in the housing to steer the steering wheels of the vehicle.

One end of the ball screw nut has a positioning flange on the outer peripheral surface. The pulley and the bearing are fitted on the outer peripheral surface of the nut. This bearing rotatably supports the nut inside the housing. The pulley and the bearing are located in this order with respect to the flange, and are positioned with respect to the nut by a bearing locknut screwed into the other end of the nut.

Japanese Unexamined Patent Publication No. 2015-168371

The nut has a relatively large diameter because it has a threaded portion on the inner peripheral surface and a circulation passage for circulating a plurality of balls. Therefore, the bearing and housing that support the nut also have to have a large diameter. There is room for improvement in order to reduce the size of the entire transmission device including the housing.

An object of the present invention is to provide a technique capable of reducing the size of a transmission device.

According to the present invention, the transmission device is
With a tubular housing
A screw shaft that is movably housed in the housing along the housing and has a threaded portion on the outer peripheral surface,
A plurality of balls located so as to be able to roll on the threaded portion,
A cylindrical member connected to the threaded portion by the plurality of balls, and a large-diameter portion having a circulating portion for circulating the plurality of balls rolling on the threaded portion on an outer peripheral surface. A nut having a small diameter portion connected to the large diameter portion in the axial direction of the screw shaft and having a smaller diameter than the large diameter portion.
Includes a bearing that rotatably supports the small diameter portion inside the housing.

In the present invention, the nut of the ball screw has a small diameter portion having a circulation portion on the outer peripheral surface and a small diameter portion having a smaller diameter than the large diameter portion. The bearing supports the small diameter portion of the nut inside the housing. Therefore, the bearing can have a small diameter. Since the bearing has a small diameter, the diameter of the housing can also be small.

The length of the nut is longer because the small diameter part is connected in the axial direction of the screw shaft with respect to the large diameter part. However, the tubular housing that houses the nut is inevitably long because it also houses the screw shaft that can be moved along this housing. Therefore, the transmission device can be arranged within the range of the length of the housing. The housing does not need to be longer. In other words, the length of the tubular housing is skillfully utilized to reduce the diameter of this housing.

In this way, by reducing the diameter of the bearing and the housing while maintaining the length of the housing, it is possible to reduce the size of the entire transmission device including the housing.

It is sectional drawing of the transmission device by this invention. FIG. 5 is a cross-sectional view of a configuration in which a nut, a transmission member, a guide member, and an end deflector shown in FIG. 1 are combined. It is an exploded view of the nut shown in FIG. 1, a transmission member, a rolling bearing, and a locknut for a rolling bearing. It is sectional drawing which follows the 4-4 arrow line of sight of FIG. It is an exploded view of the nut, the guide member, and the end deflector shown in FIG. It is an exploded view of the sub-assembly which combined the nut, the guide member, and the end deflector shown in FIG. 2, and the transmission member. It is explanatory drawing explaining the concept of the circulation part shown in FIG. It is a schematic diagram of the steering device for a vehicle using the transmission device shown in FIG. It is sectional drawing around the guide member of the ball screw apparatus according to Example 2 of this invention. It is sectional drawing around the guide member of the ball screw apparatus according to Example 3 of this invention. It is sectional drawing which shows the threaded part of the nut of the ball screw device according to Example 4 of this invention, and the threaded part of a screw shaft. It is an external view of the ball screw device according to Example 4 of this invention, and shows the state which the end deflector was assembled to a nut (screw shaft is not shown). It is an external view of the ball screw device by Example 4 of this invention, and shows the state before assembling the end deflector to a nut (screw shaft is not shown). It is a block diagram of the end deflector of the ball screw apparatus according to Example 4 of this invention. It is a plane explanatory view of the nut and the end deflector seen from the axial direction of the screw shaft of the ball screw device according to Example 4 of this invention. It is sectional drawing of the screw part and the end deflector of the screw shaft of the ball screw device according to Example 4 of this invention. It is a working sectional view which shows the mode that the ball is lifted by the ball lifting part of the ball screw device according to Example 4 of this invention. FIG. 5 is an explanatory view of a screw portion of a screw shaft of a ball screw device according to a fourth embodiment of the present invention, which is developed in a plane when viewed from the outside diameter direction.

A mode for carrying out the present invention will be described below with reference to the accompanying drawings.
<Example 1>

The transmission device 1 of the first embodiment will be described with reference to FIGS. 1 to 7. As shown in FIG. 1, the transmission device 1 includes a housing 2, a ball screw 10, a bearing 50, and a transmission member 60. The housing 2 has, for example, a tubular structure extending in the vehicle width direction of the vehicle, and includes a first housing 3 and a second housing 4 connected in a straight line.

The ball screw 10 is a conversion mechanism capable of converting a rotary motion into a linear motion and / or converting a linear motion into a rotary motion. The ball screw 10 includes a screw shaft 20, a plurality of balls 30, and a nut 40.

The screw shaft 20 is housed in the housing 2 and can move along the longitudinal direction of the housing 2. The screw shaft 20 includes a configuration in which both ends are exposed from the housing 2. The screw shaft 20 has a screw portion 22 on the outer peripheral surface 21.

The plurality of balls 30 are positioned so as to be able to roll on the screw portion 22.

The nut 40 is a cylindrical member connected to the screw portion 22 of the screw shaft 20 by a plurality of balls 30. That is, a screw-like shape in which a plurality of balls 30 roll depending on a portion where the screw portion 42 on the inner peripheral surface 41 of the nut 40 and the screw portion 22 on the screw shaft 20 face each other. A space 43, that is, a thread groove 43 is formed. The nut 40 is connected to the threaded portion 22 by a plurality of balls 30 that roll in the threaded groove 43.

As shown in FIGS. 1 and 2, the nut 40 has a large diameter portion 44, a small diameter portion 45, and a stepped surface 46, which are located concentrically with each other. The large diameter portion 44 has a relatively large diameter because the circulation portion 70 is provided on the outer peripheral surface 44a of the large diameter portion 44. That is, the outer diameter D1 of the large diameter portion 44 is larger than the outer diameter D2 of the small diameter portion 45. The circulation portion 70 circulates a plurality of balls 30 that are rolling around the screw portions 22 and 42. The detailed configuration of the circulation unit 70 will be described later.

As shown in FIGS. 1 and 3, the small diameter portion 45 is connected (integrally continuous) with respect to the large diameter portion 44 in the axial direction of the screw shaft 20, that is, in the direction along the center line CL of the screw shaft 20. ) And a portion having a diameter smaller than that of the large diameter portion 44. The center line CL of the screw shaft 20 coincides with the center line of the nut 40. Hereinafter, the center line CL of the screw shaft 20 is appropriately rephrased as “the center line CL of the nut 40”. The outer peripheral surface 44a of the large diameter portion 44 and the outer peripheral surface 45a of the small diameter portion 45 are surfaces formed by concentric circles with reference to the center line CL of the nut 40. The stepped surface 46 is a flat surface located at the boundary between the large diameter portion 44 and the small diameter portion 45 and orthogonal to the center line CL of the nut 40.

Here, the small diameter portion 45 will be described in detail. On the outer peripheral surface 45a of the small diameter portion 45, a male serration 45b, a bearing fitting portion 45c, and a male screw 45d are formed from the stepped surface 46 to one end 40a (one end 40a of the nut 40) in the direction opposite to the large diameter portion 44. They are provided in this order.

As shown in FIG. 1, the bearing 50 can rotate the small diameter portion 45 of the nut 40 inside the housing 2 (inner peripheral surface 2a of the housing 2) and moves in the axial direction with respect to the housing 2. Is regulated and supported. The bearing 50 is composed of rolling bearings.

As shown in FIGS. 1 and 2, the transmission member 60 can transmit rotational force to each other with the small diameter portion 45 of the nut 40, for example, a pulley, a gear, a sprocket, and a shaft joint. , It can be configured by various rotating bodies such as a rotating shaft. In this embodiment, a pulley will be illustrated and described.

As shown in FIGS. 2 and 3, the transmission member 60 has a hub 61 at a central portion. The hub 61 is fitted to the small diameter portion 45 of the nut 40, and is connected to the small diameter portion 45 so that the rotational force can be transmitted to each other. The hub 61 includes a first hub portion 62 and a second hub portion 63. The first hub portion 62 and the second hub portion 63 are located concentrically with each other, and are continuous and integrated in the axial direction of the hub 61. The diameter of the inner peripheral surface 62a of the first hub portion 62 is smaller than the diameter of the inner peripheral surface 63a of the second hub portion 63. The boundary between the inner peripheral surface 62a of the first hub portion 62 and the inner peripheral surface 63a of the second hub portion 63 is connected by a hub step surface 64. The hub step surface 64 is a flat surface orthogonal to the center line CL of the nut 40.

The first hub portion 62 is a cylindrical fitting portion that can be fitted and connected to the outer peripheral surface 45a of the small diameter portion 45. For example, the first hub portion 62 can be connected to the small diameter portion 45 of the nut 40 by serrations, splines, keys, bolts or pins while restricting relative rotation to each other. As an example, the first hub portion 62 is serrated-coupled to the small diameter portion 45. More specifically, the inner peripheral surface 62a of the first hub portion 62 is configured with a female serration 62b that can be connected to the male serration 45b of the nut 40.

The second hub portion 63 is a cylindrical fitting portion that can be fitted to the outer peripheral surface 44a of the large diameter portion 44. That is, the inner peripheral surface 63a of the second hub portion 63 is detachably fitted to the outer peripheral surface 44a of the large diameter portion 44. A transmission portion 65 (belt hanging portion 65 of the pulley) having a transmission function with the outside is provided on the outer peripheral surface of the second hub portion 63.

With reference to FIG. 1, the first hub portion 62 and the bearing 50 of the transmission member 60 are located in this order in the axial direction with respect to the stepped surface 46 of the nut 40, and the stop member 51 provided on the small diameter portion 45. The stepped surface 46 regulates the axial movement of the nut 40. The stop member 51 is composed of a lock nut for rolling bearings that can be screwed into the male screw 45d of the small diameter portion 45.

As shown in FIG. 3, the procedure for assembling the transmission member 60 and the bearing 50 to the nut 40 is as follows.
First, the hub 61 of the transmission member 60 is inserted from one end 40a of the nut 40 (transmission member assembly step). Then, while fitting the inner peripheral surface 63a of the second hub portion 63 into the outer peripheral surface 44a of the large diameter portion 44, the inner peripheral surface 62a of the first hub portion 62 is fitted into the outer peripheral surface 45a of the small diameter portion 45. While the inner peripheral surface 62a of the first hub portion 62 is being fitted to the outer peripheral surface 45a of the small diameter portion 45, the female serration 62b of the first hub portion 62 is fitted into the male serration 45b of the nut 40 to be connected. As a result, the relative rotation of the transmission member 60 with respect to the nut 40 is restricted. After that, the hub stepped surface 64 comes into contact with the stepped surface 46 of the nut 40, so that the axial position of the transmission member 60 with respect to the nut 40 is determined.

Next, the bearing 50 is inserted from one end 40a of the nut 40 into the bearing fitting portion 45c (bearing assembly step).
Next, the stop member 51 (lock nut 51 for rolling bearing) is screwed from one end 40a of the nut 40 into the male screw 45d (stop member assembly step). Then, the first hub portion 62 and the bearing 50 are sandwiched in the axial direction of the nut 40 by the stepped surface 46 of the nut 40 and the stopping member 51. As a result, the axial positions of the transmission member 60 and the bearing 50 are determined and attached to the nut 40.
This completes the assembling work of the transmission member 60 and the bearing 50 with respect to the nut 40.

As is clear from the above description, since the transmission member 60, the bearing 50, and the stop member 51 are only assembled to the nut 40 in this order from one direction, the assembly workability is good and the assembly man-hours can be reduced.

Next, the circulation portion 70 will be described with reference to FIGS. 2, 4 and 5. The circulation portion 70 includes a large diameter portion 44 of the nut 40, a second hub portion 63, a pair of guide members 80, 80, and a pair of end deflectors 90, 90.

The large-diameter portion 44 of the nut 40 has an annular recess 47 recessed from the outer peripheral surface 44a of the large-diameter portion 44 over the entire circumference in the central portion in the axial direction (direction along the center line CL of the nut 40). Hereinafter, the annular recess 47 will be appropriately referred to as an “annular recess 47”. The annular recess 47 is located concentrically with respect to the large diameter portion 44. The bottom surface 47a of the annular recess 47 is a perfect circular surface centered on the center line CL of the nut 40. The diameter D3 of the bottom surface 47a of the annular recess 47 is smaller than the outer diameter D1 of the large diameter portion 44. As described above, the portion of the nut 40 where the annular recess 47 is located is thin because the diameter is smaller than that of the large diameter portion 44. As a result, the nut 40 becomes lightweight.

The pair of guide members 80, 80 are detachable in the radial direction with respect to the bottom surface 47a of the annular recess 47, and are preferably resin molded products. The pair of guide members 80, 80 can be produced of resin separately from the nut 40, and the weight can be reduced. As a result, the ball screw 10 can be made even lighter. The pair of guide members 80, 80 are located at regular intervals Le (see FIG. 4) in the circumferential direction of the annular recess 47, and extend between both end surfaces 47b, 47b of the annular recess 47 in the axial direction. ..

Further, the pair of guide members 80, 80 has a bar-shaped structure having a quadrangular cross section when viewed from the direction along the center line CL of the nut 40. More specifically, in a configuration in which the pair of guide members 80, 80 are located at intervals Le in the circumferential direction of the annular recess 47, the breakdown of each of the four surfaces 81 to 84 having a quadrangular cross section is the annular recess 47. The first surfaces 81 and 81 capable of contacting the bottom surface 47a over the entire surface and the second surfaces 82 and 82 capable of contacting the inner peripheral surface 63a of the second hub portion 63 over the entire surface have a distance Le from each other. The third surface 83, 83 facing each other and the fourth surface 84, 84 on the opposite side of the third surface 83, 83. The first surfaces 81 and 81 are formed on the same curved surface as the bottom surface 47a of the annular recess 47. The second surfaces 82 and 82 are formed on the same curved surface as the inner peripheral surface 63a of the second hub portion 63. The third surfaces 83, 83 and the fourth surfaces 84, 84 are parallel to each other.

The depth from the outer peripheral surface 44a of the large diameter portion 44 to the bottom surface 47a of the annular recess 47, that is, the depth of the annular recess 47 with respect to the large diameter portion 44 is Dp. In the configuration in which the guide member 80 is fitted into the annular recess 47, the first surface 81 has no step with respect to the outer peripheral surface 44a of the large diameter portion 44 and is connected extremely smoothly on the outer peripheral surface 44a of the large diameter portion 44 (surface flush). Will be). The distance Le between the pair of guide members 80, 80 and the depth of the annular recess 47 with respect to the large diameter portion 44 are such that the Dp is a size that allows the ball 30 to roll (for example, the diameter of the ball 30). It is set to a slightly larger value).

The pair of guide members 80, 80 have a pair of first positioning portions 86, 86 at both ends 85, 85 (both end surfaces 85, 85) in a direction along the axial direction of the nut 40. These first positioning portions 86 have an arc-shaped protrusion when viewed from the first surface 81 side.

On the other hand, a plurality of (for example, four) second positioning portions 44b are formed on the outer peripheral surface 44a of the large diameter portion 44. The plurality of second positioning portions 44b have a concave structure in which each of the first positioning portions 86 can be fitted from outside the diameter of the large diameter portion 44, and are recessed from the outer peripheral surface 44a of the large diameter portion 44. The shape of the second positioning portion 44b is the same arc shape as the first positioning portions 86, 86 when viewed from the outside of the diameter of the large diameter portion 44.

As shown in FIG. 5, the pair of guide members 80, 80 are positioned on the nut 40 by the fitting relationship between the respective first positioning portions 86 and the respective second positioning portions 44b.

As described above, the pair of guide members 80, 80 have a pair of first positioning portions 86, 86 at both ends 55, 55 in the direction along the axial direction of the nut 40. The large-diameter portion 44 has a plurality of second positioning portions 44b into which a pair of first positioning portions 86, 86 can be fitted from outside the diameter on the outer peripheral surface 44a. Therefore, the pair of guide members 80, 80 can be accurately and easily positioned on the nut 40 by simply fitting each of the first positioning portions 86 into the plurality of second positioning portions 44b from the outside of the diameter. Can be done. Moreover, the positions of the pair of guide members 80, 80 with respect to the nut 40 can be reliably held.

The second hub portion 63 covers the pair of guide members 80, 80 while restricting the displacement to the outer diameter in a configuration fitted to the large diameter portion 44. In this way, the transmission member 60 acts as a so-called cover capable of covering the nut 40 with the pair of guide members 80, 80 while restricting the displacement to the outside of the diameter.

As shown in FIGS. 2 and 4, the circulation portion 70 includes a bottom surface 47a of the annular recess 47, a pair of guide members 80 and 80 assembled to the nut 40, and an inner peripheral surface of the second hub portion 63. 63a and the (enclosed) circulation passage, or space, defined by.

The concept of the circulation unit 70 will be described with reference to FIGS. 7 (a) to 7 (c). FIG. 7A reprints the relationship between the bottom surface 47a of the annular recess 47 shown in FIG. 4 and the pair of guide members 80, 80. FIG. 7B schematically represents the space 71 shown in FIG. 7A. FIG. 7 (c) schematically represents the concept of forming the annular recess 47 by surrounding the space 71 shown in FIG. 7 (b) with the second hub portion 63.

As shown in FIG. 7A, the space 71 surrounded by the bottom surface 47a of the annular recess 47 and the third surfaces 83, 83 of the pair of guide members 80, 80 is referred to as the “recess 71”. .. The recess 71 is recessed from the outer peripheral surface 44a of the large diameter portion 44 toward the center of the nut 40, and is along the center line CL (see FIG. 3) of the nut 40. The pair of side surfaces 72, 72 of the recess 71 is composed of the third surfaces 83, 83 of the pair of guide members 80, 80. The bottom surface 73 of the recess 71 is composed of a part of the bottom surface 47a of the annular recess 47. That is, as shown in FIG. 7B, the large-diameter portion 44 constitutes a recess 71 that is recessed from the outer peripheral surface 44a of the large-diameter portion 44 toward the center of the nut 40. it can.

As shown in FIG. 7 (c), by fitting the inner peripheral surface 63a of the second hub portion 63 to the outer peripheral surface 44a of the large diameter portion 44, the inner peripheral surface 63a becomes the recess 71 (FIG. 7 (b). ) Will be enclosed. The closed space 70 formed by surrounding the recess 71 with the inner peripheral surface 63a is referred to as a circulation portion 70. The circulation portion 70 is a circulation passage defined by a pair of side surfaces 72 and 72, a bottom surface 73, and an inner peripheral surface 63a of the second hub portion 63. Hereinafter, the circulation portion 70 is appropriately referred to as a “circulation passage 62”. The plurality of balls 30 rolling in the thread groove 43 can circulate through the circulation passage 70.

As shown in FIGS. 1 and 2, the pair of end deflectors 90, 90 is a member that communicates between the thread groove 43 and both ends of the circulation passage 70, and is composed of, for example, a resin molded product. .. Each end deflector 90, 90 has a communication hole 91, 91 that communicates between the thread groove 43 and the circulation passage 70. The plurality of balls 30 rolling in the thread groove 43 can circulate through the communication passages 91 and 91 through the circulation passage 70.

As shown in FIG. 5, the large diameter portion 44 has a pair of recesses 48, 48 on the outer peripheral surface 44a. These pairs of recesses 48, 48 are recessed from the outer peripheral surface 44a of the large diameter portion 44. The pair of end deflectors 90, 90 can be individually fitted into the recesses 48, 48 from outside the diameter of the large diameter portion 44.

As shown in FIGS. 2 and 5, in the configuration in which the pair of end deflectors 90, 90 are fitted into the recesses 48, 48, the outer surface of each end deflector 90, 90 is relative to the outer peripheral surface 44a of the large diameter portion 44. There is no step, and the large diameter portion 44 is connected (equal to the same surface) extremely smoothly on the outer peripheral surface 44a. The second hub portion 63 of the transmission member 60, together with the pair of guide members 80 and 80, covers the pair of end deflectors 90 and 90 while restricting the outward displacement.

Therefore, the pair of end deflectors 90, 90 can be individually fitted into the recesses 48, 48 provided on the outer peripheral surface 44a of the large diameter portion 44 from the outside of the diameter. Moreover, the pair of end deflectors 90, 90 can be covered together with the pair of guide members 80, 80 by effectively utilizing the transmission member 60. Therefore, there is no need for a "separate member" to cover the pair of end deflectors 90, 90. Further, since the pair of guide members 80 and 80 are separate from the pair of end deflectors 90 and 90, the shape can be simplified.

As is clear from the above description, the transmission member 60 has all the following four configurations.
First, as shown in FIG. 1, the transmission member 60 has a configuration capable of transmitting rotational forces to each other with respect to the nut 40.

Secondly, as shown in FIGS. 4 and 7, the transmission member 60 has a configuration capable of defining the circulation passage 70 in cooperation with the annular recess 47 and the pair of guide members 80, 80.

Thirdly, as shown in FIGS. 2 and 4, the transmission member 60 can cover the nut 40 with the pair of guide members 80, 80 while restricting the displacement outward. (See FIG. 4).

Fourth, as shown in FIGS. 2 and 4, the transmission member 60 displaces the pair of end deflectors 90, 90 with respect to the nut 40, together with the pair of guide members 80, 80, outward in diameter. It is a configuration that can cover while regulating.

As is clear from the third configuration and the fourth configuration, the transmission member 60 assembled to the nut 40 is effectively utilized. The second hub portion 63 of the transmission member 60 covers the pair of guide members 80, 80 and the pair of end deflectors 90, 90 while restricting the outward displacement of the nut 40. Therefore, the pair of guide members 80, 80 and the pair of end deflectors 90, 90 do not come off from the nut 40.

Next, with reference to FIG. 8, a vehicle steering device 100 using the transmission device 1 will be illustrated and described.

The vehicle steering device 100 is composed of both the steering system 110 and the steering power transmission mechanism 130, or only the steering power transmission mechanism 130. The steering system 110 is a system from the steering wheel 111 of the vehicle to the wheels 121, 121 (steering wheels 121, 121). The steering power transmission mechanism 130 has a configuration in which steering power is applied to the wheels 121 and 121.

In this embodiment, the steering power transmission mechanism 130 will be described by exemplifying an auxiliary torque mechanism that applies an auxiliary torque to the steering system 110. Hereinafter, the steering power transmission mechanism 130 will be appropriately referred to as an “auxiliary torque mechanism 130”.

The steering system 110 includes a steering wheel 111, a steering shaft 112 connected to the steering wheel 111, an input shaft 114 connected to the steering shaft 112 by a universal shaft joint 113, and a first transmission mechanism to the input shaft 114. The steering shaft 116 connected by 115, and the left and right (both sides in the vehicle width direction) wheels connected to both ends of the steering shaft 116 via ball joints 117, 117, tie rods 118, 118, and knuckles 119, 119. It consists of 121 and 121. The first transmission mechanism 115 is composed of, for example, a rack and pinion mechanism.

According to the steering system 110, when the driver steers the steering wheel 111, the steering torque causes the left and right wheels 121 and 121 to pass through the first transmission mechanism 115, the steering shaft 116 and the left and right tie rods 118 and 118. Can be steered.

The auxiliary torque mechanism 130 (steering power transmission mechanism 130) includes a steering torque sensor 131, a control unit 132, an electric motor 133, and a second transmission mechanism 134. The steering torque sensor 131 detects the steering torque of the steering system 110 applied to the steering wheel 111. The control unit 132 generates a control signal based on the torque detection signal of the steering torque sensor 131. The electric motor 133 generates a motor torque (auxiliary torque) corresponding to the steering torque, that is, a steering driving force, based on the control signal of the control unit 132. The second transmission mechanism 134 transmits the auxiliary torque generated by the electric motor 133 to the steering shaft 116.

According to the vehicle steering device 100, the wheels 121 and 121 can be steered by the steering shaft 116 by the combined torque obtained by adding the auxiliary torque of the electric motor 133 to the steering torque of the driver.

The steering shaft 116 is composed of the screw shaft 20 and is housed in the housing 2 so as to be movable in the vehicle width direction (axial direction). The first transmission mechanism 115 and the second transmission mechanism 134 are also housed in the housing 2.

As shown in FIGS. 1 and 7, the second transmission mechanism 134 includes, for example, a belt transmission mechanism 150 and the ball screw 10.

The belt transmission mechanism 150 includes a drive pulley 151 provided on the output shaft 133a of the electric motor 133, a driven pulley 152 provided on the nut 40 of the ball screw 10, and a belt hung on the drive pulley 151 and the driven pulley 152. It consists of 153. The driven pulley 152 is a kind of transmission member 60 of the ball screw 10. Hereinafter, the driven pulley 152 will be appropriately referred to as a “transmission member 60”.

The ball screw 10 transmits the steering driving force generated by the electric motor 133 (see FIG. 7), that is, the auxiliary torque to the steering shaft 116.

The above explanation can be summarized as follows.
As shown in FIGS. 1 to 3, the transmission device 1 is
Cylindrical housing 2 and
A screw shaft 20 which is housed in the housing 2 so as to be movable along the housing 2 and has a screw portion 22 on the outer peripheral surface 21 and a screw shaft 20.
A plurality of balls 30 located so as to be able to roll on the screw portion 22 and
The outer peripheral surface 44a has a circulation portion 70 that is a cylindrical member connected to the screw portion 22 by the plurality of balls 30 and circulates the plurality of balls 30 that are rolling the screw portion 22. A nut 40 having a large-diameter portion 44, and a small-diameter portion 45 that is connected to the large-diameter portion 44 in the axial direction of the screw shaft 20 and has a smaller diameter than the large-diameter portion 44.
A bearing 50 that rotatably supports the small diameter portion 45 inside the housing 2 is included.

As described above, the nut 40 of the ball screw 10 has a small diameter portion 45 having a smaller diameter than the large diameter portion 44 in addition to the large diameter portion 44 having the circulation portion 70 on the outer peripheral surface 44a. .. The bearing 50 supports a small diameter portion 45 in the nut 40 inside the housing 2. Therefore, the bearing 50 can have a small diameter. Since the bearing 50 has a small diameter, the diameter of the housing 2 can also be small.

The length of the nut 40 is longer than that of the large diameter portion 44 because the small diameter portion 45 is connected in the axial direction of the screw shaft 20. However, the tubular housing 2 that houses the nut 40 is inevitably long because it also houses the screw shaft 20 that can move along the housing 2. Therefore, the transmission device 1 can be arranged within the range of the length of the housing 2. The housing 2 does not need to be longer. That is, the length of the tubular housing 2 is skillfully utilized to reduce the diameter of the housing 2.

By reducing the diameter of the bearing 50 and the housing 2 while maintaining the length of the housing 2 in this way, it is possible to reduce the size of the entire transmission device 1 including the housing 2.

Further, as shown in FIGS. 1 to 3, a hub 61 that is fitted to the small diameter portion 45 of the nut 40 and is connected to the small diameter portion 45 so that rotational force can be transmitted to each other. Further includes the transmission member 60, which is possessed.
The nut 40 has a stepped surface 46 located at the boundary between the large diameter portion 44 and the small diameter portion 45 and orthogonal to the center line CL of the nut 40.
The hub 61 and the bearing 50 are located in this order in the axial direction with respect to the stepped surface 46, and the shaft of the nut 40 is formed by the stopping member 51 provided on the small diameter portion 45 and the stepped surface 46. Movement in the direction is restricted.

In this way, the movement of the hub 61, the bearing 50, and the stopper 51 in the axial direction with respect to the nut 40 can be easily regulated by a simple operation of assembling the hub 61, the bearing 50, and the stopper 51 from one direction to the nut 40.

Further, as shown in FIGS. 1 and 3, the bearing 50 is composed of rolling bearings 50.
The fixing member 51 is composed of a rolling bearing locknut 51 that can be screwed into the small diameter portion 45.

Therefore, by simply screwing the rolling bearing locknut 51 into the small diameter portion 45, the axial positions of the hub 61 and the rolling bearing 50 with respect to the nut 40 can be set accurately regardless of the manufacturing tolerance.

Further, as shown in FIG. 3, the hub 61 has a first hub portion 62 fitted and connected to the small diameter portion 45 and a second hub portion 63 fitted to the large diameter portion 44. And have
The first hub portion 62 and the second hub portion 63 are continuous and integrated in the axial direction of the hub 61.

By connecting the first hub portion 62 and the second hub portion 63 in the axial direction of the hub 61 and integrating them, the inner peripheral surface 62a of the first hub portion 62 and the inner peripheral surface of the second hub portion 63 A stepped surface 64 (hub stepped surface 64) can be provided at the boundary between the 63a and the 63a. Despite being a single hub 61, a hub step surface 64 can be provided. The number of parts is small.

Further, as shown in FIGS. 2, 4 and 7, the large-diameter portion 44 constitutes a recess 71 that is recessed from the outer peripheral surface 44a of the large-diameter portion 44 toward the center of the nut 40. Has a pair of side surfaces 72, 72 and a bottom surface 73,
The circulation portion 70 is a circulation passage 70 defined by the pair of side surfaces 72 and 72, the bottom surface 73, and the inner peripheral surface 63a of the second hub portion 63.
Therefore, the circulation passage 70 can be provided with a simple configuration.

More specifically, as shown in FIGS. 1 to 7, the transmission device 1 is
Cylindrical housing 2 and
A screw shaft 20 which is housed in the housing 2 so as to be movable along the housing 2 and has a screw portion 22 on the outer peripheral surface 21 and a screw shaft 20.
A plurality of balls 30 located so as to be able to roll on the screw portion 22 and
The outer peripheral surface 44a has a circulation portion 70 that is a cylindrical member connected to the screw portion 22 by the plurality of balls 30 and circulates the plurality of balls 30 that are rolling the screw portion 22. A nut 40 having a large-diameter portion 44, and a small-diameter portion 45 that is connected to the large-diameter portion 44 in the axial direction of the screw shaft 20 and has a smaller diameter than the large-diameter portion 44.
A rolling bearing 50 that rotatably supports the small diameter portion 45 inside the housing 2.
A transmission member transmission member 60 composed of a pulley 152 (driven pulley 152) having a hub 61 serrated-coupled to the small diameter portion 45 of the nut 40 is included.
The nut 40 has a stepped surface 46 located at the boundary between the large diameter portion 44 and the small diameter portion 45 and orthogonal to the center line CL of the nut 40.
The hub 61 and the rolling bearing 50 are located in this order in the axial direction with respect to the step surface 46, and the bearing locknut 51 screwed into the small diameter portion 45 and the step surface 46 (that is, the step surface 46). The movement of the nut 40 in the axial direction is restricted by the regulation that the hub step surface 64 hits the step surface 46).
The hub 61 includes a first hub portion 62 that is serrated-coupled to the small-diameter portion 45 (a female serration 62b is connected to a male serration 45b) and a second hub portion 63 that is fitted to the large-diameter portion 44. Have,
The first hub portion 62 and the second hub portion 63 are continuous and integrated in the axial direction of the hub 61.
The large-diameter portion 44 has a pair of side surfaces 72, 72 and a bottom surface 73 that form a recess 71 that is recessed from the outer peripheral surface 44a of the large-diameter portion 44 toward the center of the nut 40.
The circulation portion 70 is a circulation passage defined by the pair of side surfaces 72 and 72, the bottom surface 73, and the inner peripheral surface 63a of the second hub portion 63.

As shown in FIGS. 1 and 8, the vehicle steering device 100 is
The transmission device 1 and
The electric motor 133 and the electric motor 133 that generate the steering driving force transmitted from the transmission member 60 to the nut 40.
It is composed of the screw shaft 20 and has a steering shaft 116 for steering the steering wheels 121 and 121.

Therefore, by transmitting the steering driving force generated by the electric motor 133 from the transmission member 60 to the nut 40, the rotational motion of the nut 40 is converted into the linear motion of the steering shaft 116, and the steering wheel 121. , 121 can be steered efficiently.

<Example 2>
The ball screw device 200 of the second embodiment will be described with reference to FIG. FIG. 9 is shown corresponding to FIG. 4 above. In the ball screw device 200 of the second embodiment, the pair of guide members 80 and 80 of the ball screw device 10 of the first embodiment shown in FIGS. 1 to 8 are attached to the pair of guide members 280 and 280 shown in FIG. Since the configuration is the same as that of the first embodiment, the description will be omitted.

The first surfaces 81, 81 of the pair of guide members 280, 280 of the second embodiment are separated from each other without being in contact with the outer peripheral surface 45a of the small diameter portion 45. That is, there is a gap between the first surfaces 81 and 81 and the outer peripheral surfaces 45a. Therefore, it is not necessary to strictly control the dimensions from the first surfaces 81, 81 to the second surfaces 82, 82. The management man-hours of the ball screw device 200 can be reduced. Other actions and effects are the same as in Example 1.

<Example 3>
The ball screw device 300 of the third embodiment will be described with reference to FIG. FIG. 10 is shown corresponding to FIG. 4 above. In the ball screw device 300 of the third embodiment, the pair of guide members 80, 80 of the ball screw device 10 of the first embodiment shown in FIGS. 1 to 8 are attached to the pair of guide members 380, 380 shown in FIG. Since the configuration is the same as that of the first embodiment, the description will be omitted.

The first surfaces 81, 81 and the second surfaces 82, 82 of the pair of guide members 380, 380 of the third embodiment have a curved surface configuration that is convex outward. More specifically, the first surfaces 81 and 81 have a curved cross section that is convex toward the outer peripheral surface 45a of the small diameter portion 45. Therefore, in the third embodiment, only the convex tip of the curved first surface 81, 81 can be in contact with the outer peripheral surface 45a of the small diameter portion 45. The second surfaces 82 and 82 have a curved cross section that is convex toward the inner peripheral surface 61a of the fitting portion 61. Therefore, in the third embodiment, only the convex tip of the curved second surface 82, 82 can be in contact with the inner peripheral surface 61a of the fitting portion 61. Therefore, it is not necessary to strictly control the shapes and dimensions of the first surfaces 81, 81 and the second surfaces 82, 82. The management man-hours of the ball screw device 300 can be reduced. Other actions and effects are the same as in Example 1.

<Example 4>
The ball screw device 400 of the fourth embodiment will be described with reference to FIGS. 11 to 18. The ball screw device 400 of the fourth embodiment has a pair of end deflectors 90 and 90 of the ball screw device 10 of the first embodiment shown in FIGS. 1 to 8 and a pair of end deflectors 470 shown in FIGS. 11 to 18. , 470, and the other configurations are the same as those in the first embodiment, so the description thereof will be omitted.

Hereinafter, the ball screw device 400 will be described in detail.
As shown in FIGS. 1 and 11 to 13, the ball screw device 400 inserts a nut 40 having a spiral groove 42 (screw portion 42) formed in an inner peripheral surface 41 and a nut 40, and inserts the nut 40 into an outer peripheral surface 21. A screw shaft 20 having a spiral groove 22 (screw portion 22) formed therein, a plurality of balls 30 rolling along the spiral groove 22, and a pair of end deflectors 470 and 470 attached to a nut 40 (only one of them is shown). ) And. In the following description, the traveling direction of the ball 30 means the direction in which the ball 30 enters the end deflector 470 from the spiral grooves 22 and 42.

"Nut 40"
The nut 40 is a cylindrical member and, as shown in FIG. 11, includes a spiral groove 42 for accommodating the ball 30 with the spiral groove 22 of the screw shaft 20. The cross-sectional shape of the spiral grooves 22 and 42 has, for example, a Gothic arc shape having groove bottoms 22a and 42a at the tips, respectively. The groove ridge 22b of the spiral groove 22 and the groove ridge 42b of the spiral groove 42 are separated from each other with a distance s.

FIG. 13A shows a state before the end deflector 470 is assembled to the nut 40. FIG. 13B shows a configuration in which the end deflector 470 shown in FIG. 13A is viewed from the outside of the diameter.

As shown in FIGS. 13A and 13B, the outer Au in the axis CL direction (axis CL direction) refers to the direction away from the central portion of the nut 40 in the axis CL direction along the axis CL direction, and refers to the direction away from the center of the nut 40 in the axis CL direction. The direction inner In is the direction of the nut 40 approaching the center of the axis CL direction.

The accommodating portion 48 (that is, the recess 48) accommodating the end deflector 470 extends from the inner peripheral surface 41 of the nut 40 toward the outer peripheral surface 44a side and faces the first side wall surface 628 and the second side wall surface 629. , The bottom wall surface 630 (that is, the inner circumference of the fitting portion 61) formed over the outer peripheral surface 44a side edge portion of the nut 40 on the first side wall surface 628 and the outer peripheral surface 44a side edge portion of the nut 40 on the second side wall surface 629. The first side wall surface 628, the second side wall surface 629, and the bottom wall surface 630 (corresponding to the surface 61a), the first abutting surface 631 formed over the inner edges of each axis in the CL direction, and the first side wall surface 628. The second side wall surface 629 and the bottom wall surface 630 are defined by a second abutting surface 632 formed over the outer edge of each axis in the CL direction.

The first side wall surface 628, the second side wall surface 629, and the bottom wall surface 630 are formed along the axis CL direction, and the first abutting surface 631 is formed along a surface orthogonal to the axis CL direction. The first side wall surface 628 and the second side wall surface 629 face each other, but do not have to be parallel to each other. The second side wall surface 629 is formed so as to be smoothly connected to the end portion 22c of the spiral groove 22. The opening of the circulation passage 62 (circulation passage 62) faces the first abutting surface 631. The circulation path 62 is formed in the nut 40 along the axis CL direction, and a similar opening is formed at the end on the opposite side of the nut 40.

"End deflector 470"
Also referring to FIG. 11, the end deflector 470 has a function of rectifying the spiral movement of the ball 30 in the spiral grooves 22 and 42 and the movement in the axial CL direction in the circulation passage 62, that is, the spiral grooves 22 and 42 and the circulation passage. It is a member having a function of changing the direction of the ball 30 with and to the 62.

FIG. 14 (a) is a perspective view of a state in which the first member 473 and the second member 474 constituting the end deflector 470 are assembled, and FIG. 14 (b) is a view before assembling the first member 473 and the second member 474. A perspective view of the state, FIG. 14 (c), is a plan view of the state in which the first member 473 and the second member 474 are assembled.

As described mainly with reference to FIGS. 13 and 14, a passage 518 (communication hole 518) through which the ball 30 passes is formed inside the end deflector 470. In the fourth embodiment, mainly from the viewpoint of the moldability of the passage 518, the end deflector 470 is a first member in which a semicircular passage (referred to as the first half passage 511) connected to the spiral groove 22 of the screw shaft 20 is formed. It is divided into 473 and a second member 474 in which a semicircular passage (referred to as the second half passage 517) connected to the spiral groove 22 of the nut 40 is formed. The material of the end deflector 470 is not particularly limited, and may be a metal material, a synthetic resin material, or the like. When the end deflector 470 is made of, for example, a zinc material, parts can be formed by a die casting method.

The first member 473 has a first side surface 476 formed following the first side wall surface 628, an outer surface 513A formed following the bottom wall surface 630, and a screw shaft 20 as outer surface surfaces substantially along the axis CL direction. It has an inner surface 477 facing the surface and a dividing surface 478 which is a surface in contact with the second member 474. The end surface of the first member 473 that is closer to the inside in the CL direction is formed as an abutting surface 479 that abuts on the first abutting surface 631. The end surface of the first member 473 that is closer to the outside in the CL direction is formed as an abutting surface 510 that abuts on the second abutting surface 632. A first half passage 511 forming half of the passage 518 of the ball 30 is formed on the dividing surface 478. A claw portion 475 that bulges in the radial direction of the axis CL and is located in the spiral groove 22 of the screw shaft 20 is formed on a part of the inner surface 477. The claw portion 475 has a substantially semicircular shape having a size that does not interfere with the spiral groove 22.

The second member 474 has a second side surface 512 formed following the second side wall surface 629, an outer surface 513B formed following the bottom wall surface 630, and a first member as outer surfaces substantially along the axis CL direction. It has a divided surface 514, which is a surface that comes into contact with 473. The end surface of the second member 474 inward in the CL direction is formed as an abutting surface 515 that abuts on the first abutting surface 631. The end surface of the second member 474 on the outer side in the CL direction is formed as an abutting surface 516 that abuts on the second abutting surface 632. A second half passage 517 forming half of the passage 71 of the ball 30 is formed on the dividing surface 514. A notch 540 is formed at the tip of the second half passage 517 so as to smoothly guide the ball 30 from the end 22c of the spiral groove 22.

An engaging protrusion 519 is formed on the divided surface 514 of the second member 474, and an engaging recess 520 is formed on the divided surface 478 of the first member 473. In the first member 473 and the second member 474, the divided surfaces 478 and 514 come into contact with each other by, for example, snap-engaging the engaging protrusion 519 with the engaging recess 520, and both of them are integrated into the end deflector 470. To configure. The end faces 510 and 516 are flush with each other, and the abutted surfaces 479 and 515 are also flush with each other. By combining the first half passage 511 and the second half passage 517 inside the end deflector 470, the first passage 518A communicating with the spiral grooves 22 and 42 and the first passage 518A are smoothly omitted. A second passage 518B formed along the axis CL direction by turning 90 degrees and communicating with the opening of the circulation path 62, and a passage 518 composed of the second passage 518B are formed. The structure for integrating the first member 473 and the second member 474 is not particularly limited to the engaging method of the engaging protrusion 519 and the engaging recess 520. Further, there may be no structure for integrating the first member 473 and the second member 474.

In the above configuration, when the ball 30 enters the end deflector 470 as shown in FIG. 15, the ball 30 is
(1) A state of being sandwiched between the spiral groove 42 and the spiral groove 22.
(2) A state of being sandwiched between the spiral groove 42 and the second half passage 517 of the second member 474,
(3) The first half passage 511 of the first member 473 and the second half passage 517 of the second member 474 are sandwiched in this order.
Regarding the transition from (1) to (2), the second half passage 517 of the second member 474 is notched 540 with respect to the end portion 22c of the spiral groove 22 of the nut 40 without forming a gap or a step (FIG. 14). The ball 30 can be moved smoothly by communicating smoothly with the reference). However, regarding the transition from (2) to (3), since the screw shaft 20 is a movable body with respect to the end deflector 470, the first member 473 of the end deflector 470 and the spiral groove 22 of the screw shaft 20 There is no choice but to set a gap t for avoiding contact between them. Therefore, as described above, the presence of the gap t tends to cause the ball 30 to collide with the claw portion 475 and generate a collision sound.

"Ball lifting part 571,572"
To solve this problem, the end deflector 470 of the present invention includes a pair of ball lifting portions 571, 572 (see FIGS. 16 to 18) provided across the width center of the spiral groove 22 of the screw shaft 20. The pair of ball lifting portions 571 and 572 lift the ball 30 from the spiral groove 22 by supporting the ball 30 at two positions separated from each other in the width direction of the spiral groove 22 with the center of the width of the spiral groove 22 in between.

In the fourth embodiment, the ball lifting portions 571 and 572 are formed on the first member 473. In FIGS. 14 to 16, the first member 473 extends along the ball traveling direction between the second member 474 and the groove portion 22b of the screw shaft 20 and sandwiches the width center of the spiral groove 22 of the screw shaft 20. A pair of thin plate portions 573 and 574 are provided apart from each other in the width direction of the spiral groove 22. An inclined surface 575 is formed on the side surface of the thin plate portion 573 facing the thin plate portion 574, and an inclined surface 576 is formed on the side surface of the thin plate portion 574 facing the thin plate portion 573. The inclined surfaces 575 and 576 are inclined so as to be displaced toward the center of the width of the spiral groove 22 toward the inward direction of the screw shaft 20, and can be seen from FIGS. 17 (a) to 17 (c) and 18. As described above, the distance L is formed so as to become narrower as the ball travels in the direction of travel. The inclined surfaces 575 and 576 form the ball lifting portion 571, 572. As can be seen from the above, the ball lifting portions 571 and 572 are located outside the diameter of the axis CL with respect to the groove ridge portion 22b of the spiral groove 22.

17 (a), (b) and (c) are sectional views showing how the ball 30 is lifted by the ball lifting portions 571 and 572. The cross-sectional views of FIGS. 17 (a) to 17 (c) generally show the AA cross section, the BB cross section, and the CC cross section of FIGS. 15 and 18. In addition, in FIGS. 17 (a) to 17 (c) and FIG. 16, in order to make it easy to understand how the separated distance L of the inclined surfaces 575 and 576 is gradually narrowed, the inclined surfaces 575 and 576 are pointillized. Is illustrated.

The inclined surfaces 575 and 576 may have a curved surface shape that follows the spherical surface of the ball 30, or may have a flat shape. As shown in FIG. 16, the distance w between the groove portion 22b of the screw shaft 20 and the thin plate portion 573 and 574 is set to be smaller than the distance u between the groove portion 22b of the screw shaft 20 and the ball center p. The edge of the inclined surface 575,576 toward the in-diameter direction is located in the in-diameter direction with respect to the ball center p. Therefore, when the ball 30 approaches the inclined surface 575,576, the inclined surface 575,576 comes into contact with the spherical surface below the center p of the ball 30 to lift the ball 30 from both sides, and the separation distance L in the traveling direction. The ball 30 is gradually raised as the ball becomes narrower.

"Action"
When the ball 30 enters the end deflector 470 from the spiral grooves 22 and 42, the inclined surfaces 575 and 576 lift the ball 30 from both sides and move in the traveling direction as shown in FIGS. The ball 30 is gradually raised as the separation distance L of the inclined surfaces 575 and 576 becomes narrower. As a result, the ball 30 enters the passage 518 in the end deflector 470 without colliding with the tip of the claw portion 475.

If a pair of ball lifting portions 571 and 572 are provided as in the fourth embodiment, the impact when the ball is brought into contact with the lifting portions 571 and 572 is dispersed in two places. Therefore, even if a collision sound is generated when the lifted portions 571 and 572 are contacted, the collision sound is smaller than the collision sound when the conventional claw portion 475 is contacted. Since the lifting portions 571 and 572 are located substantially 180 degrees opposite to each other with the center p of the ball 30 in between, the bouncing behavior of the ball 30 when it comes into contact with the lifting portions 571 and 572 is also suppressed.

In addition, the ball lifting portions 571 and 572 of the fourth embodiment are located outside the diameter of the axis CL with respect to the groove ridge portion 22b of the spiral groove 22. In the conventional structure in which the ball 30 is scooped by the claw portion 475, a gap t for avoiding contact must be set between the claw portion 475 and the spiral groove 22, and therefore the collision angle with respect to the ball 30 (the traveling direction of the ball 30). The angle of intersection with the tangential direction at the collision portion of the ball 30) becomes large, and the collision sound tends to be loud. On the other hand, if the ball lifting portions 571 and 572 are positioned outside the diameter of the axis CL with respect to the groove ridge portion 22b of the spiral groove 22, contact with the screw shaft 20 is considered when lifting the ball 30. Instead, the collision angle of the ball lifting portions 571 and 572 with respect to the ball 30 can be set extremely shallow. That is, it is possible to position the vicinity of the tips of the ball lifting portions 571 and 572 substantially along the tangential direction of the spherical surface of the ball 30. Thereby, the generation of the collision sound can be almost eliminated.

Further, the ball lifting portions 571 and 572 are inclined so as to be displaced toward the center of the width of the spiral groove 22 as each of the screw shafts 20 is directed in the inward direction, and the distance L between them is increased as the ball travels. If the ball is composed of a pair of inclined surfaces 575 and 576 that are narrowed, the ball lifting portions 571 and 572 can have a simple structure, and the ball 30 can be lifted smoothly.

Further, as in the fourth embodiment, if the first member 473 is provided with a pair of thin plate portions 573 and 574 and the inclined surfaces 575 and 576 are formed on the thin plate portions 573 and 574, the first member 473 and the second member are second. The shape design of the end deflector 470 when it is divided into the member 474 becomes easy.

The ball screw 10 and the vehicle steering device 100 according to the present invention are not limited to the examples as long as the actions and effects of the present invention are exhibited.

For example, the transmission device 1 is not limited to the configuration used for the vehicle steering device 100, and can be used for various industrial machines such as machine tools and various devices such as transportation equipment.

Further, for example, the vehicle steering device 100 shown in FIG. 8 may be configured as a steer-by-wire type steering device or a steering device for an autonomous driving vehicle.

In the steer-by-wire type steering device, the steering wheel 111 and the steering shaft 116 are mechanically separated, and the electric motor 133 generates steering power according to the steering amount of the steering wheel 111, and the steering power is generated. Is transmitted to the steering shaft 116 by the belt transmission mechanism 150.

The steering device for an automatic driving vehicle completely eliminates the steering wheel 111, the steering shaft 112, the universal shaft joint 113, the input shaft 114, and the first transmission mechanism 115 in the steering system 110, and also includes the electric motor 133. It is configured to include a second transmission mechanism 134. The wheels 121 and 121 can be automatically steered by transmitting the steering power generated by the electric motor 133 to the steering shaft 116 by the belt transmission mechanism 150 without the driver steering.

Further, the bearing 50 shown in FIG. 1 is not limited to the rolling bearing, and may have, for example, a slide bearing configuration. The stop member 51 may have a structure that restricts the movement of the bearing 50 in the axial direction of the nut 40, and may be, for example, a structure of a retaining ring.

Further, the transmission member 60 shown in FIG. 1 may have a configuration in which rotational forces are transmitted to each other with the nut 40. For example, the hollow input shaft and output shaft of various drive sources such as an electric motor and an engine can be used as the transmission member 60.

Further, the recess 71 for forming a part of the circulation portion 70 shown in FIG. 7 includes a part of the bottom surface 47a of the annular recess 47 of the large diameter portion 44 and the third surface of the pair of guide members 80, 80. The space is not limited to the space surrounded by 83 and 83, and may be, for example, a configuration in which the outer peripheral surface 44a of the large diameter portion 44 is recessed toward the center of the nut 40.

Further, in the fourth embodiment, the ball lifting portions 571 and 572 are formed on the first member 473 side, but may be formed on the second member 474 side.
Further, the end deflector 470 is not divided into the first member 473 and the second member 474, but may be integrally molded as a whole.
Further, if the ball lifting portions 571 and 572 can smoothly guide the ball 30 to the passage 518 in the end deflector 470, the claw portion 475 protruding into the spiral groove 22 may be omitted.

The transmission device 10 and the vehicle steering device 100 of the present invention are suitable for mounting on an automobile.

1 Transmission device 2 Housing 10 Ball screw 20 Screw shaft 21 Thread shaft outer peripheral surface 22 Threaded part 30 Ball 40 Nut 41 Nut inner peripheral surface 42 Threaded part 44 Large diameter part 44a Large diameter part outer peripheral surface 45 Small diameter part 45a Small diameter part Outer peripheral surface 45b Male serration 45d Male screw 46 Step surface 50 Bearing (rolling bearing)
51 Stopping member (locknut for rolling bearing)
60 Transmission member 61 Hub 62 First hub 62b Female serration 62b
63 Second hub part 63a Inner peripheral surface of the second hub part 70 Circulation part (circulation passage)
71 Recess 72 Two sides of the recess 73 Bottom of the recess 100 Steering device for vehicles 111 Steering wheel 116 Steering wheel 121 Steering wheel 133 Electric motor 150 Belt transmission mechanism 151 Drive pulley 152 Driven pulley 153 Belt CL Center line of screw shaft (Center line of nut)
D1 Outer diameter of large diameter part D2 Outer diameter of small diameter part D3 Diameter of bottom surface of annular recess

According to the present invention, the transmission device is
With a tubular housing
A screw shaft that is movably housed in the housing along the housing and has a threaded portion on the outer peripheral surface,
A plurality of balls located so as to be able to roll on the threaded portion,
A cylindrical member connected to the threaded portion by the plurality of balls, and a large-diameter portion having a circulating portion for circulating the plurality of balls rolling on the threaded portion on an outer peripheral surface. A nut having a small diameter portion connected to the large diameter portion in the axial direction of the screw shaft and having a smaller diameter than the large diameter portion.
A bearing that rotatably supports the small diameter portion inside the housing,
A transmission member having a hub that is fitted to the small diameter portion of the nut and is connected to the small diameter portion so that rotational force can be transmitted to each other.
Only including,
The nut has a stepped surface located at the boundary between the large diameter portion and the small diameter portion and orthogonal to the center line of the nut.
The hub has a cylindrical first hub portion and a cylindrical second hub portion.
The first hub portion and the second hub portion are continuous and integrated in the axial direction of the hub.
The inner peripheral surface of the first hub portion is fitted to the small diameter portion and serrated to the small diameter portion.
The first hub and the bearing are located in this order in the axial direction with respect to the stepped surface, and the small diameter portion is moved in the axial direction by the stopper member provided on the small diameter portion and the stepped surface. Is regulated and
A transmission portion of the transmission member is provided on the outer peripheral surface of the second hub portion.
The inner peripheral surface of the second hub portion is fitted to the large diameter portion.
The large-diameter portion has a pair of parallel side surfaces and a bottom surface that form a recess recessed from the outer peripheral surface of the large-diameter portion toward the center of the nut.
The circulation portion is a circulation passage defined by the pair of side surfaces, the bottom surface, and the inner peripheral surface of the second hub portion.

More specifically, as shown in FIGS. 1 to 7, the transmission device 1 is
Cylindrical housing 2 and
A screw shaft 20 which is housed in the housing 2 so as to be movable along the housing 2 and has a screw portion 22 on the outer peripheral surface 21 and a screw shaft 20.
A plurality of balls 30 located so as to be able to roll on the screw portion 22 and
The outer peripheral surface 44a has a circulation portion 70 that is a cylindrical member connected to the screw portion 22 by the plurality of balls 30 and circulates the plurality of balls 30 that are rolling the screw portion 22. A nut 40 having a large-diameter portion 44, and a small-diameter portion 45 that is connected to the large-diameter portion 44 in the axial direction of the screw shaft 20 and has a smaller diameter than the large-diameter portion 44.
A rolling bearing 50 that rotatably supports the small diameter portion 45 inside the housing 2.
A transmission member 60 composed of a pulley 152 (driven pulley 152) having a hub 61 serrated on the small diameter portion 45 of the nut 40.
The nut 40 has a stepped surface 46 located at the boundary between the large diameter portion 44 and the small diameter portion 45 and orthogonal to the center line CL of the nut 40.
The hub 61 and the rolling bearing 50 are located in this order in the axial direction with respect to the step surface 46, and the bearing locknut 51 screwed into the small diameter portion 45 and the step surface 46 (that is, the step surface 46). The movement of the nut 40 in the axial direction is restricted by the regulation that the hub step surface 64 hits the step surface 46).
The hub 61 includes a first hub portion 62 that is serrated-coupled to the small-diameter portion 45 (a female serration 62b is connected to a male serration 45b) and a second hub portion 63 that is fitted to the large-diameter portion 44. Have,
The first hub portion 62 and the second hub portion 63 are continuous and integrated in the axial direction of the hub 61.
The large-diameter portion 44 has a pair of side surfaces 72, 72 and a bottom surface 73 that form a recess 71 that is recessed from the outer peripheral surface 44a of the large-diameter portion 44 toward the center of the nut 40.
The circulation portion 70 is a circulation passage defined by the pair of side surfaces 72 and 72, the bottom surface 73, and the inner peripheral surface 63a of the second hub portion 63.

Claims (8)

With a tubular housing
A screw shaft that is movably housed in the housing along the housing and has a threaded portion on the outer peripheral surface,
A plurality of balls located so as to be able to roll on the threaded portion,
A cylindrical member connected to the threaded portion by the plurality of balls, and a large-diameter portion having a circulating portion for circulating the plurality of balls rolling on the threaded portion on an outer peripheral surface. A nut having a small diameter portion connected to the large diameter portion in the axial direction of the screw shaft and having a smaller diameter than the large diameter portion.
A bearing that rotatably supports the small diameter portion inside the housing,
A transmission device characterized by including. Further comprising a transmission member having a hub that is fitted to the small diameter portion of the nut and is connected to the small diameter portion so that rotational force can be transmitted to each other.
The nut has a stepped surface located at the boundary between the large diameter portion and the small diameter portion and orthogonal to the center line of the nut.
The hub and the bearing are located in this order in the axial direction with respect to the stepped surface, and the movement of the nut in the axial direction is restricted by the stopper member provided on the small diameter portion and the stepped surface. ing,
The transmission device according to claim 1. The bearing is composed of rolling bearings.
The transmission device according to claim 2, wherein the stop member is composed of a locknut for a rolling bearing that can be screwed into the small diameter portion. The hub has a first hub portion that is fitted and connected to the small diameter portion, and a second hub portion that is fitted to the large diameter portion.
The first hub portion and the second hub portion are continuous and integrated in the axial direction of the hub.
The transmission device according to claim 2 or 3. The large-diameter portion has a pair of side surfaces and a bottom surface that form a recess recessed from the outer peripheral surface of the large-diameter portion toward the center of the nut.
The circulation portion is a circulation passage defined by the pair of side surfaces, the bottom surface, and the inner peripheral surface of the second hub portion.
The transmission device according to claim 4. The large diameter portion has a pair of recesses on the outer peripheral surface.
A pair of end deflectors that can be individually fitted into the pair of recesses from the outside of the diameter are further provided.
The pair of end deflectors communicate between a thread groove at a portion where the screw shaft and the nut face each other and both ends of the circulation passage.
The pair of end deflectors each include a pair of ball lifting portions provided across the width center of the threaded portion of the screw shaft.
Each of the pair of ball lifting portions lifts the ball from the screw portion by supporting the ball at two locations separated in the width direction with the width center of the screw portion interposed therebetween.
The transmission device according to any one of claims 1 to 5. With a tubular housing
A screw shaft that is movably housed in the housing along the housing and has a threaded portion on the outer peripheral surface,
A plurality of balls located so as to be able to roll on the threaded portion,
A cylindrical member connected to the threaded portion by the plurality of balls, and a large-diameter portion having a circulating portion for circulating the plurality of balls rolling on the threaded portion on an outer peripheral surface. A nut having a small diameter portion connected to the large diameter portion in the axial direction of the screw shaft and having a smaller diameter than the large diameter portion.
A rolling bearing that rotatably supports the small diameter portion inside the housing,
A transmission member composed of a pulley having a hub serrated on the small diameter portion of the nut.
Including
The nut has a stepped surface located at the boundary between the large diameter portion and the small diameter portion and orthogonal to the center line of the nut.
The hub and the rolling bearing are located in this order in the axial direction with respect to the stepped surface, and the locknut for bearing screwed into the small diameter portion and the stepped surface make the nut axially. Movement is restricted and
The hub has a first hub portion that is serrated to the small diameter portion and a second hub portion that is fitted to the large diameter portion.
The first hub portion and the second hub portion are continuous and integrated in the axial direction of the hub.
The large-diameter portion has a pair of side surfaces and a bottom surface that form a recess recessed from the outer peripheral surface of the large-diameter portion toward the center of the nut.
The circulation portion is a circulation passage defined by the pair of side surfaces, the bottom surface, and the inner peripheral surface of the second hub portion.
A transmission device characterized by that. The transmission device according to any one of claims 1 to 7.
An electric motor that generates a steering driving force that is transmitted from the transmission member to the nut,
A steering shaft composed of the screw shafts for steering the steering wheels,
Has a vehicle steering device.

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