This invention relates to a steerable truck for a railway car and a railway car and an articulated car equipped with this steerable truck.
Improving the ability of a railway car to smoothly travel along a curved track is and has been an important technical problem. There is a strong desire for an increased ability of a railway car to travel along curves, particularly for railway cars traveling along sharp curves in suburban railways such as underground railways.
Non-Patent Document 1 discloses that (a) the flange of the wheel 5 on the outer side of the front wheelset 1f contacts the rail 4a on the outer side and an attack angle θ develops; (b) this attack angle θ causes a lateral pressure Qsi to be applied by the inner track; and (c) the rear wheelset 1r is located approximately midway between the left and right rails 4a and 4b, so in the rear wheelset 1r, an attack angle θ does not develop to the same extent as in the front wheelset 1f. However, since a sufficient difference between the rolling radius of the left and right wheels 5 is not obtained, the radius difference in the rear wheelset is insufficient and causes a longitudinal creep force Fvc to develop. The inner track lateral pressure Qsi and the longitudinal creep force Fvc produce a yawing moment My in the counterclockwise direction about the center of gravity of the truck frame 2. In
Non-Patent Document 2 discloses that the truck frame 2 also has a yawing angle φ which is defined as the angle in a horizontal plane of the truck frame to the left and right with respect to the radial direction of the curved track. The yawing angle φ of the truck frame 2 has the same rotational direction as the attack angle θ of the front wheelset 1f. The yawing angle φ of the truck frame 2 causes the attack angle θ of the front wheelset 1f which is supported by this truck frame 2 to further increase.
Patent Document 1 discloses an invention in which in order to increase the ability of a railway car to travel along a curved track, an actuator is used as a supplemental means so that the truck frames which are positioned to the front and rear in the direction of travel pivot in synchrony with respect to the car body in the self-steering direction. That invention can decrease the yawing angle of the truck frame during travel along a curved track.
However, in order to carry out the invention disclosed in Patent Document 1, it is necessary to provide not only an actuator but also a controller for the actuator. In addition, it is necessary to provide safety measures for the event in which control of the actuator cannot be carried out in a normal manner. Therefore, the apparatus becomes complicated and costly.
A link-type steerable truck which uses links without using an actuator is also being developed.
In this steerable truck 11, the front wheelset 1f and the rear wheelset 1r are connected to a bolster 12, which is mounted on an unillustrated car body, and to a truck frame 13 by pairs of first links 14a and 14b. Of the first links 14a and 14b, each of the first links 14b which is connected to the truck frame 13 (referred to below as steering levers 14b) is connected to an axle box 19 which rotatably supports the front wheelset 1f or the rear wheelset 1r by a second link 15.
In this steerable truck 11, displacement of the bolster 12 on the car body side with respect to the truck 11 by the bogie angle is transmitted to the steering levers 14b throng the first links 14a. In the example shown in
The transmitted displacement adjusts the steering amount based on the lever ratio when the connection points between the steering levers 14b and the truck frame 13, i.e., the connection points 17 on the truck frame side act as centers of pivoting (fulcrums), and the front wheelset 1f and the rear wheelset 1r are steered through the connection points between the steering levers 14b and the second links 15, namely, through the connection points 18 on the wheelset side.
As shown in
With the steerable truck 11 shown in
Therefore, in this steerable truck 11, there is a limit to the degree of increase in the stiffness with which the truck frame 13 supports the front wheelset 1f and the rear wheelset 1r, and it is not easy to simultaneously provide all of the properties demanded of a truck for a railway car including the ability to stably travel along a straight track and prescribed vibration properties.
The present invention was made in light of such problems of the prior art, and it provides a steerable truck for a railway car which can be simply carried out at a low cost and which has excellent ability to travel along a curved track without worsening properties such as the ability to travel along a straight track and vibration properties. It also provides a railway car and articulated cars equipped with this steerable truck.
The steering angle of the front wheelset and the steering angle of the rear wheelset in the steerable truck disclosed in Patent Document 1 and the like and in the steerable truck explained while referring to
The present invention is contrary to such technical common sense, and it is based on the original technical concept: “When traveling along a curved track, of the steering angles of the wheelsets which are defined as the angles between an imaginary straight line connecting the center of the truck frame and the center of a circular arc defined by the curved track in a horizontal plane (referred to below as the reference line) and the centerlines of the front and rear wheelsets, by controlling the steering angle of the rear wheelset and preferably by controlling the steering angle only of the rear wheelset such that the steering angle which is the angle between the reference line and the centerline of the rear wheelset becomes larger than the steering angle which is the angle between the reference line and the centerline of the front wheelset, steering is performed such that the truck frame is aligned with the tangential direction of the curved track. Namely, the yawing angle of the truck frame which is the angle in a horizontal plane of the centerline in the fore and aft direction of the truck frame with respect to the radial direction of the curved track can be decreased. As a result, a steerable truck for a railway car which has excellent ability to travel along a curved track and which can be carried out simply and at a low cost and without a worsening of properties such as the ability to travel along a straight track and vibration properties can be provided”.
The present invention is a steerable truck for a railway car having a truck frame which rotatably supports a front wheelset positioned on the front side in the direction of travel and a rear wheelset positioned on the rear side in the direction of travel through axle boxes, and a truck frame steering unit for controlling the steering angle of at least the rear wheelset when traveling along a curved track, characterized in that when the truck is traveling along a curved track, the truck frame is steered so as to be aligned with the tangential direction of the curved track by controlling the steering angle of the rear wheelset by the truck frame steering unit so that the steering angle of the rear wheelset is larger than the steering angle of the front wheelset.
Also the present invention is a steerable truck for a railway car having a truck frame which rotatably supports a front wheelset positioned on the front side in the direction of travel and a rear wheelset positioned on the rear side in the direction of travel through axle boxes, and a truck frame steering unit for controlling the steering angle of at least the rear wheelset when traveling along a curved track, characterized in that when the truck is traveling along a curved track, the yawing angle of the truck frame, which is the angle formed in a horizontal plane between the radial direction of the curved track and the centerline in the fore and aft direction of the truck frame, is decreased by controlling the steering angle of the rear wheelset by the truck frame steering unit so that the steering angle of the rear wheelset is larger than the steering angle of the front wheelset.
In the present invention, the truck frame steering unit preferably controls only the steering angle of the rear wheelset during travel along a curved track.
In the present invention, control of the steering angle of the rear wheelset by the truck frame steering unit is preferably carried out by a link mechanism mounted on the truck frame. Furthermore, the link mechanism preferably controls the steering angle in accordance with the bogie angle which is the relative displacement of the truck frame with respect to the car body when traveling along a curved track.
In the present invention, the link mechanism preferably has a first link which connects the car body and the truck frame, and a second link which connects the first link and at least an axle box which rotatably supports the rear wheelset.
In the present invention, the stiffness of the links connected to the rear wheelset is preferably different from the stiffness of the links connected to the front wheelset.
From another standpoint, the present invention is a railway car having a truck on the front side and a truck on the rear side in the direction of travel, characterized in that at least one of the trucks on the front side and the rear side in the direction of travel is the above-described steerable truck for a railway car according to the present invention.
The present invention is also a railway car characterized by having the above-described steerable truck for a railway car according to the present invention on the front side and on the rear side in the direction of travel, with the steerable trucks for a railway car being provided so that the rear wheelset is positioned on the inner side in the direction of travel.
In addition, the present invention is articulated cars characterized by having the above-described steerable truck for a railway car according to the present invention at least in the articulated portion between two car bodies.
According to the present invention, a steerable truck for a railway car which has excellent ability to travel on a curved track and which can actually be realized because it can be carried out simply and at low cost, and a railway car and articulated cars having this steerable truck can be provided
a) and 6(b) are explanatory views showing an example of applying a steerable truck according to the present invention to a car with 2-axle bogie trucks.
Below, the best mode for carrying out the present invention will be explained while referring to the attached drawings.
In the following explanation, an example will be given of the case in which control of the steering angle of the rear wheelset by a truck frame steering unit according to the present invention is carried out by a link mechanism mounted on the truck frame. In addition, in the following explanation, the same components as the components in above-described
This steerable truck 21 has a truck frame steering unit 20 mounted only on the rear wheelset 1r.
The rear wheelset 1r in this steerable truck 21 is connected to a bolster 12 which is mounted on an unillustrated car body and to a truck frame 13 by pairs of first links 14a and 14b. Of the first links 14a and 14b, each first link 14b which is connected to the truck frame 13 (referred to below as the steering lever 14b) is connected by a second link 15 to an axle box 19 which rotatably supports the rear wheelset 1r.
In this steerable truck 21, displacement of the bolster 12 on the car body side with respect to the truck 21 by the bogie angle is transmitted from first links 14a to the steering levers 14b. In the example shown in
The transmitted displacement adjusts the steering amount in accordance with the lever ratio when the connection points between the steering levers 14b and the truck frame 13, namely, connection points 17 on the truck frame side act as centers of pivoting (fulcrums), and the rear wheelset 1r is steered through the connection points between steering levers 14b and the second links 15, namely, through connection points 18 on the wheelset side.
With this steerable truck 21, only the rear wheelset 1r is steered by the truck frame steering unit 20, so the relationship between the steering angle α1 of the front wheelset 1f and the steering angle α2 of the rear wheelset 1r becomes α2>α1.
The rear wheelset 1r which is steered by the truck frame steering unit 20 is moved towards the outer rails as shown by the arrow in
In a steerable truck 21 in which the bolster 12 on the car body side, the truck frame 13, and the rear wheelset 1r are connected by pins or the like, the longitudinal creep forces Fvc which act on the rear wheelset 1r are transmitted by the steering levers 14b from the rear wheelset 1r to the axle boxes 19 with the connection points 16 on the car body side acting as fulcrums and with the connection points 18 on the wheelset side acting as points of effort, and it is transmitted to the truck frame 13 via the connection points 17 on the truck frame side as acting forces F.
Therefore, in the steerable truck 21, as described above, the longitudinal creep forces Fvc is applied to the truck frame 13 as acting forces F in the opposite directions from a conventional truck 3.
With the conventional truck 3 shown in
In this steerable truck 21, due to the truck frame 13 rotating in the clockwise direction as shown in
Next, the difference between a typical link-type steerable truck and a truck according to the present invention will be explained. In the typical link-type steerable truck 11 shown in
By comparing
The present invention was accomplished based on the above-described new knowledge.
Namely, as shown in
As an example of the structure of a truck frame steering unit 20 which makes the truck frame 13 steerable, as shown in
This link-type truck frame steering unit 20 makes actuators such as are used in Patent Document 1 unnecessary, so not only does a controller for an actuator become unnecessary, but safety measures for the case in which control of the actuator cannot be carried out in the normal manner also become unnecessary.
In a steerable truck 21 for a railway car according to the present invention, a truck frame steering unit 20 which makes the steering angle α2 of the rear wheelset 1r larger than the steering angle α1 of the front wheelset 1f is not limited to the one shown in
As shown in
In the truck frame steering unit 20-1 shown in
In this case, the lever ratios of the steering levers 14b for the front wheelset 1f and the rear wheelset 1r do not satisfy Lr=Lf as shown in
In this manner, by making the steering angle α2 of the rear wheelset 1r larger than the steering angle α1 of the front wheelset 1f, the force acting upon the rear wheelset 1r is made different from the force acting on the front wheelset 1f, so a force acts on connection points 17 on the truck frame side. Accordingly, the present invention can also be accomplished by the structure shown in
In order to make the steering angle α1 of the front wheelset 1f different from the steering angle α2 of the rear wheelset 1r, the truck frame steering unit 20-2 shown in
By making the stiffness of the rear wheelset 1r higher than the stiffness of the front wheelset 1f, the balance of the forces acting on the connection points 17 on the truck frame side is upset, forces are generated at the connection points 17, and the truck frame 13 is steered by the forces acting at the connection points 17.
The truck frame steering unit 20-3 shown in
If the positions of the steering links 14b for the front wheelset 1f are inwards in the widthwise direction of a car from the positions of the steering links 14b for the rear wheelset 1r, even if the lever ratios are the same, if the distances bf, br of the positions where forces act on the front wheelset 1f and the rear wheelset 1r satisfy br>bf, the balance of the forces acting on the connection points 17 on the truck frame side is upset. As a result, the truck frame 13 can be steered.
Next, a situation in which a steerable truck 21 according to the present invention is mounted on a railway car 31 will be explained.
a) and 6(b) are explanatory views showing an example in which a steerable truck according to the present invention is applied to a car with 2-axle bogie trucks.
The basic arrangement is such that the steering angle for the rear wheelset 1r of each steerable truck 21 is larger for the steerable trucks 21 mounted both on the front side and on the rear side in the direction of travel in
However, the direction of travel of the railway car 31 reverses. Therefore, as shown in
In the case shown in
The steerable truck 21 according to the present invention shown in
From the results shown in
A steerable truck according to the present invention exhibits the behavior shown in
At this time, as shown in Table 1, the fulcrums of the “steering levers” are on the car body side, the points of effort are on the wheelset side, and the points of load are on the truck frame side. Therefore, due to the yawing moment acting on the truck frame, the yawing angle of the truck frame decreases. Due to the yawing angle of the truck frame decreasing, the attack angle of the front wheelset also decreases, and the inner track lateral pressure and the outer track lateral pressure both decrease.
In the above description, examples of carrying out the present invention have been explained, but the present invention is not limited to these examples, and suitable variations are of course possible as long as they fall within the technical concept set forth by the claims.
An axle box suspension used in a steerable truck according to the present invention is not limited to the monolink type as in the examples of
Number | Date | Country | Kind |
---|---|---|---|
2007-245494 | Sep 2007 | JP | national |
2007-265734 | Oct 2007 | JP | national |
Number | Date | Country | |
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Parent | PCT/JP2008/066719 | Sep 2008 | US |
Child | 12727604 | US |