The disclosure of Japanese Patent Application No. 2007-335566 filed on Dec. 27, 2007 including the specification, drawings and abstract is incorporated herein by reference in its entirety.
1. Field of the Invention
The invention relates to a ball screw device, and in particular, to a ball screw device that is used in a form in which a screw shaft rectilinearly moves in the axial direction without rotation.
2. Description of the Related Art
A ball screw device that includes a screw shaft and a ball screw nut engaged with the screw shaft with balls interposed therebetween is often used as an electric actuator or in a damper. Japanese Patent Application Publication No. 2006-67649 (JP-A-2006-67649), for example, includes a description in which a ball screw device is used in a damper in which a screw shaft is connected to a motor, so that the screw shaft is rotated to cause a ball screw nut to rectilinearly move in the axial direction.
On the other hand, the ball screw device is also used in a form in which a motor is connected to a ball screw nut and the screw shaft rectilinearly moves without rotation. In this form, in general, a stopper is provided to prevent the screw shaft from moving more than a predetermined distance when a strong force is applied from the outside. Immediately before the screw shaft is stopped by the stopper, the screw shaft is moving fast, and the ball screw nut is rotating at a high speed. Thus, a sudden stop of the screw shaft causes the ball screw nut to exert a large rotational inertial force, and this rotational inertial force can result in the occurrence of brinelling in a raceway of the ball screw.
The invention provides a ball screw device that is suitable for use in a form in which a screw shaft rectilinearly moves in the axial direction without rotation.
A ball screw device according to the invention includes: a screw shaft; a ball screw nut engaged with the screw shaft with balls interposed between the ball screw nut and the screw shaft; a stopper that determines a limit of movement of the screw shaft in a forward direction when the ball screw nut is rotated to cause the screw shaft to move rectilinearly in the forward direction along an axial direction; and a braking portion that reduces a speed of the forward movement of the screw shaft before the screw shaft reaches the limit.
The ball screw device is, in some cases, used in the form of an actuator, in which a ball screw nut is rotated by a motor, which causes a screw shaft to move rectilinearly. The ball screw device is, in other cases, used in the form of a damper, in which a screw shaft is rectilinearly moved by a force exerted from the outside, which causes a ball screw nut to rotate, and the electromagnetic force generated by a motor is used as the damping force.
In either case, the screw shaft reciprocates, and in general, a stopper is provided that prevents the screw shaft from moving more than a predetermined distance in a predetermined direction, which is herein referred to as the “forward direction,” which means the direction in which an impact of the stopper occurs, and which may be any of the vertical direction, the longitudinal direction, the lateral direction, etc. The stopper can be formed by providing the screw shaft with a flange portion that contacts a housing when the screw shaft moves beyond a predetermined distance. Alternatively, the stopper may be formed on a member that moves rectilinearly together with the screw shaft, or may be provided on a member (a housing, a hollow shaft, etc.) that does not move rectilinearly. The stopper may be provided not only for one direction of the reciprocation but also for the opposite direction. In this case, a braking portion that is associated with the stopper of the opposite direction may be further provided. When the limit of the movement of the screw shaft in the forward direction is determined by the stopper, the screw shaft is forcibly stopped when the limit is reached. When this occurs, if the speed of the screw shaft is fast, the rotational inertial force of the nut is large at the time of sudden stop of the screw shaft, and therefore, brinelling in a raceway of the ball screw can occur.
The braking portion is not for stopping the screw shaft, but for reducing the impact load at the time of the impact of the stopper. The range of travel in the braking portion is shorter than the range of travel of the stopper so that the impact of the stopper occurs after the screw shaft travels over the range of travel in the braking portion. Although the screw shaft rectilinearly moves fast when a large force is applied to the screw shaft in the axial direction, the screw shaft that is moving forward fast receives a force, of which the direction is opposite to the moving direction, from the braking portion. Thus, the speed of the rectilinear movement (forward movement speed) of the screw shaft is reduced, so that the rotational speed of the ball screw nut is reduced and the rotational inertial force of the ball screw nut is reduced. Then, the screw shaft is forcibly stopped by the stopper. At this time, the rotational inertial force of the ball screw nut has already been reduced, and the occurrence of brinelling in a raceway of the ball screw is prevented. After the screw shaft is forcibly stopped by the stopper, the screw shaft is returned to the original state.
The braking portion can be implemented in various forms. For example, the ball screw device may further include a hollow shaft that is fixed to the ball screw nut and extends in the forward direction of the screw shaft, and the braking portion may include: a small diameter portion, formed in an end portion of the hollow shaft, that exerts a dragging force on the screw shaft; and a buffer layer formed on at least one of the small diameter portion of the hollow shaft and an outer circumferential surface of a tip portion of the screw shaft. The minimum inner diameter of the small diameter portion may be smaller than the outer diameter of the tip portion of the screw shaft. The small diameter portion may be tapered so that the inner diameter of the small diameter portion gradually decreases toward the forward direction of the screw shaft. The small diameter portion may have at least one step portion in which the inner diameter of the hollow shaft is reduced stepwise in the forward direction of the screw shaft. The step portion may include: a straight portion that has an inner diameter smaller than the outer diameter of the tip portion of the screw shaft; and a tapered portion between the straight portion and a portion of the hollow shaft that has an inner diameter larger than the inner diameter of the straight portion. The small diameter portion may have a plurality of the step portions. The plurality of step portions may include: a first straight portion of which a minimum inner diameter is substantially equal to the outer diameter of the tip portion of the screw shaft; a third straight portion that is positioned on a hollow-shaft tip side and of which a minimum inner diameter is smaller than the outer diameter of the tip portion of the screw shaft; a second straight portion that is positioned between the first and third straight portions and of which an inner diameter is intermediate between the inner diameters of the first and third straight portions; a first tapered portion between the first straight portion and a portion of the hollow shaft that has an inner diameter larger than the inner diameter of the first straight portion; a second tapered portion between the first and second straight portions; and a third tapered portion between the second and third straight portions. The buffer layer may be made of resin.
It is preferable that the hollow shaft be made of metal and double as a rotor of a motor. The small diameter portion of the hollow shaft can be formed by tapering the end portion of the hollow shaft in such a manner that the inner diameter of the hollow shaft gradually decreases toward the forward direction of the screw shaft. The tip portion of the screw shaft may either be tapered or not be tapered, that is, may be straight. The buffer layer is, for example, formed on an outer circumferential surface of the tip portion of the screw shaft, but may be provided on the inner circumferential surface of the hollow shaft. For example, the small diameter portion of the hollow shaft may be formed by applying resin, in a tapered form, to the inner surface of the cylindrical rotor of the motor, and such a resin layer may be used also as the buffer layer. When a large force is applied to the screw shaft in the axial direction, the screw shaft is fitted into the small diameter portion of the hollow shaft, and the speed of the forward movement of the screw shaft is reduced. Thus, the rotational speed of the ball screw nut is reduced, and the rotational inertial force of the ball screw nut is reduced. The buffer layer reduces the impact when the screw shaft is fitted into the small diameter portion of the hollow shaft, and facilitates returning the screw shaft into the original state. The material for the buffer layer is typically polyurethane, polyamide, or the like, for example. However, it is also possible to use, for example, a paper material for the buffer layer. The buffer layer also provides a function of preventing the ball screw nut from falling off the screw shaft.
The braking portion may include an elastic member. The braking portion may further include a support portion that is fixed so that a relative position between the ball screw nut and the support portion in the axial direction is invariable, and the elastic member may be provided on at least one of the support portion and the screw shaft. The elastic member may be provided on the support portion and may receive the screw shaft that is moving in the forward direction. When the elastic member is provided on the support portion side, the weight of the screw shaft, which is a movable portion, is not increased, and in addition, it is possible to minimize the possibility of the occurrence of a problem such as falling off. The braking portion may include an air damper that receives the screw shaft that is moving in the forward direction. Examples of the elastic member include various types of springs and an elastic body made of rubber or synthetic resin.
For example, the ball screw device may further include a hollow shaft that is fixed to the ball screw nut and extends in the forward direction of the screw shaft, and the air damper may include: a cover that closes an opening at the tip of the hollow shaft; and a seal member that is provided on a tip portion of the screw shaft and seals a gap between the screw shaft and the hollow shaft. In this case, the opening at the tip of the hollow shaft is closed by the cover to form a closed-end cylinder, and the tip portion of the screw shaft serves as a piston. The end portion of the hollow shaft may either be tapered or be straight. An orifice for slowly discharging the air in the air chamber may be provided in the hollow shaft or in the cover.
In some cases, a spline for guiding the rectilinear movement of the screw shaft is integrally provided on the screw shaft. Such a spline may be a ball spline, or a fitting type spline such as an involute spline.
For example, the ball screw device may include: a screw shaft provided with a thread groove and a spline groove; a ball screw nut engaged with the thread groove of the screw shaft with balls interposed between the ball screw nut and the screw shaft; a hollow shaft integrated with the ball screw nut; a ball spline outer cylinder that is engaged with the spline groove of the screw shaft with balls interposed therebetween and guides the axial rectilinear motion of the screw shaft; a housing that rotatably supports the hollow shaft through a bearing and fixedly supports the ball spline outer cylinder; a motor including a magnet (rotor) fixed on an outer circumferential surface of the hollow shaft and a stator fixed on the inner circumferential surface of the housing so as to face the magnet; a stopper for preventing the screw shaft from moving rectilinearly more than a predetermined distance; and the above-described braking portion.
With the ball screw device of the invention, it is possible to reduce the impact load when the screw shaft is forcibly stopped, and it is therefore possible to prevent the occurrence of brinelling in a raceway of the ball screw. Thus, a problem is solved that the moment of inertia increases when the overall size of the ball screw device is enlarged to obtain a high strength, and it is therefore possible to reduce the size and weight of the ball screw device.
The foregoing and further objects, features and advantages of the invention will become apparent from the following description of example embodiments with reference to the accompanying drawings, wherein like numerals are used to represent like elements and wherein:
Embodiments of the invention will be described below with reference to the drawings. In the following description, the terms “right” and “left” mean the right and left in the drawings, respectively, and the left direction is the forward direction.
The ball screw device 1 includes: a steel screw shaft 2, extending in the right-and-left direction, that is provided with a thread groove 2a and a spline groove 2b extending in the right-and-left direction; a ball screw nut 3 engaged with the thread groove 2a of the screw shaft 2 with balls 4 interposed therebetween; a hollow shaft 5 integrated with the ball screw nut 3 and extending to the left; a ball spline outer cylinder 6 that is engaged with the spline groove 2b of the screw shaft 2 with balls 7 interposed therebetween and guides the right and left (axial) rectilinear motion of the screw shaft 2; a housing 8 that rotatably supports the hollow shaft 5 through bearings 9 and fixedly supports the ball spline outer cylinder 6; a motor 10 including a magnet (rotor) 10a fixed on an outer circumferential surface of the hollow shaft 5 and a stator 10b fixed on the inner circumferential surface of the housing 8 so as to face the magnet 10a; a stopper 14 for preventing the screw shaft 2 from moving forward more than a predetermined distance; and a braking means 15 that reduces the speed of the forward movement of the screw shaft 2 before the impact of the stopper 14.
The screw shaft 2 and the hollow shaft 5 are concentrically disposed, and, because the hollow shaft 5 doubles as the rotor of the motor 10, the ball screw device 1 is used in a form in which the hollow shaft 5 and the ball screw nut 3 are rotated to rectilinearly move the screw shaft 2.
In
The hollow shaft 5 has a large diameter portion 11 that is substantially cylindrical and that has a required radial gap between the hollow shaft 5 and the large diameter portion 11, and a small diameter portion 12 that is continuous with the left end of the large diameter portion 11 and of which the minimum inner diameter is smaller than the outer diameter of the tip portion of the screw shaft 2.
As shown in
The ball screw device 1 is suitable for use in an electromagnetic suspension for a car, for example. The electromagnetic suspension is a damper in which the axial motion transmitted from a tire is converted to a rotational motion via a ball screw mechanism, the motor 10 receives the rotational motion, and the electromagnetic force generated in the motor 10 is used as the damping force. In some cases, at the time of over contraction of the suspension such as when the car runs over a bump, the bump stopper provided on a portion that rectilinearly moves hits a flange portion of a motor or the like, and the motor 10 that is rotating at a high speed is therefore suddenly stopped, whereby an excessively large axial force can be applied to the ball screw portion (2, 3 and 4) due to the inertial torque of the motor 10. Thus, it is an issue how to protect the ball screw mechanism in such a case.
According to the above-described ball screw device 1, before the stopper 14 hits the housing 8, the left end portion (the end portion on the forward side, that is, the tip portion) of the screw shaft 2 is fitted into the small diameter portion 12 of the hollow shaft 5, whereby a dragging force (braking force) is applied to the screw shaft 2. As a result, the speed of the forward movement of the screw shaft 2 is reduced, which results in reduction in the rotational speed of the motor 10. Thus, when the stopper 14 hits the housing 8, the inertial torque of the motor 10 has already been reduced. In this way, the ball screw mechanism is protected, and the occurrence of a problem such as the occurrence of brinelling is prevented.
The construction of the braking means 15 is not limited to the above-described construction as long as the braking means 15 reduces the speed of the forward movement of the screw shaft 2 before the impact of the stopper 14. Examples of such a construction will be described below.
According to the above-described ball screw device 1, as in the case of the ball screw device 1 of the first embodiment, before the stopper 14 hits the housing 8, the left end portion (the end portion on the forward side, that is, the tip portion) of the screw shaft 2 is fitted into the small diameter portion 12 of the hollow shaft 5, whereby a dragging force (braking force) is applied to the screw shaft 2. As a result, the speed of the forward movement of the screw shaft 2 is reduced, which results in reduction in the rotational speed of the motor 10. Thus, when the stopper 14 hits the housing 8, the inertial torque of the motor 10 has already been reduced. In this way, the ball screw mechanism is protected, and the occurrence of a problem such as the occurrence of brinelling is prevented.
The first embodiment shown in
In
According to the ball screw device 1 of the third embodiment, before the stopper 14 hits the housing 8, the end portion of the screw shaft 2 is fitted into the small diameter portion 12 of the hollow shaft 5, and the O ring 17 is in sliding contact with the inner surface of the small diameter portion 12 of the hollow shaft 5, whereby an air chamber is formed that, as the screw shaft 2 moves forward, generates a counterforce that increases with the forward movement of the screw shaft 2. As a result, the speed of the forward movement of the screw shaft 2 is reduced, which results in reduction in the rotational speed of the motor 10. Thus, when the stopper 14 hits the housing 8, the inertial torque of the motor 10 has already been reduced. In this way, the ball screw mechanism is protected, and the occurrence of a problem such as the occurrence of brinelling is prevented. Thereafter, when the screw shaft 2 is moved so that the left end portion of the screw shaft 2 is positioned in the large diameter portion 11 of the hollow shaft 5, the original state is recovered in which there is an air gap between the outer circumferential surface of the screw shaft 2 and the inner circumferential surface of the hollow shaft 5.
In
According to the screw device 1 of the fourth embodiment, before the stopper 14 hits the housing 8, the end portion of the screw shaft 2 hits the elastic body 18, whereby a force is applied that is directed opposite to the direction in which the screw shaft 2 is moving. As a result, the speed of the forward movement of the screw shaft 2 is reduced, which results in reduction in the rotational speed of the motor 10. Thus, when the stopper 14 hits the housing 8, the inertial torque of the motor 10 has already been reduced. In this way, the ball screw mechanism is protected, and the occurrence of a problem such as the occurrence of brinelling is prevented.
In
According to the ball screw device 1 of the fifth embodiment, when the screw shaft 2 is stopped by the stopper 14, the left end (tip) of the screw shaft 2 is first brought into contact with the movable spring-receiving member 23, and the movable spring-receiving member 23 moves to the left while pressing the elastic member 24, whereby the speed of the forward movement of the screw shaft 2 is reduced, which results in reduction in the rotational speed of the motor 10. Thus, when the stopper 14 hits the housing 8, the inertial torque of the motor 10 has already been reduced. In this way, the ball screw mechanism is protected, and the occurrence of a problem such as the occurrence of brinelling is prevented.
Although, in the above-described embodiments 4 and 5, constructions are shown in which the elastic member is provided on the support portion, the elastic member may be provided on the tip portion of the screw shaft.
The above-described ball screw device 1 can be used as an electric actuator. In this case, the ball screw device 1 is used in a form in which the rotational driving force from the motor is converted into a thrust force directed in the axial direction of the screw shaft 2 via the ball screw nut 3, the bearings 9 bear the axial reaction force to the thrust force, helping the screw shaft 2 to rectilinearly move, the ball screw nut 3 receives the axial force applied to the screw shaft 2, and the ball spline outer cylinder 6 bears produced torque.
While the invention has been described with reference to example embodiments thereof, it is to be understood that the invention is not limited to the described embodiments or constructions. To the contrary, the invention is intended to cover various modifications and equivalent arrangements. In addition, while the various elements of the example embodiments are shown in various combinations and configurations, other combinations and configurations, including more, less or only a single element, are also within the spirit and scope of the invention.
Number | Date | Country | Kind |
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2007-335566 | Dec 2007 | JP | national |