The present invention relates to a rail vehicle having a plurality of rail car bodies, wherein a first and a second rail car body are supported on a bolster of a Jacobs bogie, wherein the rail car bodies are connected to one another by a spherical joint mechanism, with the spherical joint mechanism being arranged on the bolster.
Rail vehicles having Jacobs bogies are sufficiently known from the prior art. The most famous here is the TGV in which two rail car bodies are supported on a Jacobs bogie in a gangway region.
Such a Jacobs bogie comprises a frame, with a respective set of wheels being arranged at the frame by primary springs at both ends of the frame. A so-called bolster that is supported on the frame by secondary springs is supported on the frame. The two rail car bodies are supported on the bolster by a spherical joint mechanism. Such a spherical joint mechanism for a Jacobs bogie is known from WO 2005/023619. However, the pitching movements and the kink movements, rolling movements and compensating movements are greatly restricted here. The reason for this can be found in the fact that only the one rail car body is movable relative to the other rail car body. The other rail car body is fixedly connected to the bolster so that it is rigid. This means that both pitching movements and kink, rolling and compensating movements are only permitted to a relatively small degree.
The underlying object of the invention consequently comprises providing a joint mechanism for a Jacobs bogie in a rail vehicle of the initially named kind, wherein the joint mechanism is able to compensate or absorb all the movements that occur during travel, also at larger angles, in particular such movements as pitching, rolling and kink movements as well as compensating movement such as occur when such vehicles travel over switch points.
In accordance with the invention, it is proposed to achieve the object that the joint mechanism has at least two spherical joint bearings. Provision is in particular made here that the two joint bearings are arranged in a plane with respect to one another, which brings about a space-saving construction so that the spacing between the rail car bodies, that is the length of the gangway between the two vehicles, can be selected as small, but so that e.g. substantial kink movements are nevertheless permitted.
A first variant of such a spherical joint mechanism in accordance with the invention having two spherical joint bearings is characterized in that the at least two joint bearings have a common pivot point. Provision is made in detail for this purpose that two ball segments supported in one another or on one another are provided to form the two joint bearings having such a common pivot point, wherein the outer ball segment is received by a bearing shell of a ball segment kind. Such a double-spherical joint mechanism is furthermore characterized in detail in that the inner ball segment has a connection member to the bolster of the Jacobs bogie. The connection member furthermore has a support for connection to the bolster. The outer ball segment has a saddle for connection to the one first rail car body, with the bearing shell being connected to the other second rail car body. Each of the two joint bearings is thus connected to a rail car body.
As already stated, the above-described double-spherical bearing is able to substantially absorb all the movements occurring during travel such as rolling, pitching, pivoting (kink) and compensating movements as well as combinations thereof, and indeed at comparatively large angles; however, this design has the disadvantage that the bolster is not free of torque under all circumstances. Such torques in particular arise when forces act in the direction of the longitudinal vehicle axis or of the transverse vehicle axis on the double-spherical joint mechanism in accordance with the invention whose pivot point is spaced apart from the surface of the bolster. Forces that act in the direction of the longitudinal vehicle axis on the joint mechanism at the level of the pivot point are ultimately those that arise on accelerating and decelerating the vehicles. Transverse forces, that is forces transverse to the longitudinal axis of the vehicle, arise due to centrifugal forces or so-called track guiding forces. Longitudinal and transverse forces are therefore horizontal forces. The torques from them have to be absorbed directly by the bolster. The reaction forces due to such torques are transmitted to the frame of the Jacobs bogie by the springs with which the bolster is supported on the frame. To avoid this, longitudinal arms and transverse arms, e.g. lemmiscate arms, can be provided between the bolster and the frame of the Jacobs bogie to avoid a deflection of the bolster on the frame. This means that substantially no reaction forces should be transmitted by the horizontally impacting forces to the springs by which the bolster is supported on the frame.
Another possibility of keeping the bolster supported by springs on the frame of the Jacobs bogie substantially free of torques due to the influence of longitudinal and transverse forces comprises, in accordance with a second variant of the spherical joint mechanism, the spherical joint mechanism having at least two joints in the direction of the vertical axis of the rail vehicle that are arranged spaced apart from and above one another. That is, two spherical joint bearings are provided that are in particular connected to one another by a spacer bolt. An upper ball joint is here provided as the spherical joint bearing and serves the connection to the two rail car bodies, with the lower ball joint being connected to the bolster of the Jacobs bogie. In detail, the bolster has a pot for receiving the lower ball joint in which the lower ball joint is supported as a spherical bearing. The support takes place here such that the lower spherical joint bearing is pivotably or rotationally movable relative to the pot. Since the lower spherical bearing is arranged in the pot in a pivotably articulated manner relative to the pot, longitudinal and transverse forces that are introduced into the upper spherical bearing by the rail car bodies and which would introduce torques into the bolster due to the lever arm generated by the spacer bolt between the two spherical joint bearings and per se can be substantially intercepted. This means that the bolster is substantially free of torque due to a joint mechanism which has spherical joint bearings arranged spaced apart from and above one another and with which the lower bearing is supported in a pivotably movable manner on the bolster of the Jacobs bogie.
It is advantageous in this connection for the two joint bearings arranged above one another to be installed such that they provide the respective greater surface, that is have the smallest bearing pressure, in the direction of the vertical load and of the supporting force. The two joint bearings are rotated by 180° with respect to one another to this extent.
The invention will be described in more detail below by way of example with reference to the drawings.
The Jacobs bogie 1 shown in
The first variant of a spherical joint mechanism 20 shown in
The spherical joint mechanism 20 has the common pivot point 32. A spacing 33 from the upper side of the bolster 10 is formed by the connection member 31 in conjunction with the support in the bolster. This spacing 33 forms a lever arm that exposes the bolster 10 to corresponding torques on the engagement of horizontal forces at the pivot point 32. The forces that engage at the pivot point 32, for example, include forces in the longitudinal direction of the vehicle, that is in particular forces on accelerating and decelerating the rail vehicle. Transverse forces in the horizontal direction arise due to the effect of centrifugal forces or also due to the effect of track guiding forces. To keep the bolster 10 free of torque to this extent, the bolster can be supported with respect to one another toward the frame of the Jacobs bogie by longitudinal and/or transverse arms, e.g. in the form of a lemmiscate arm.
The spherical joint mechanism 40 shown in
The connection between the spherical joint bearing 47 and the spherical joint bearing 57 takes place, as already mentioned, by the spacer bolt 50. The joint arm 42 for connecting the spherical joint bearing 47 to the rail car body 16 is provided with two limbs 42a and 42b for receiving the ball segment 48 of the spherical joint bearing 47. The ball segment 48 is held between these two limbs 42a and 42b of the joint arm that is fork-like in this respect. The limb 42a receives a clamping member 41c that is connected to the spacer bolt 50 by a stud bolt 41d. The spacer bolt 50 in turn contacts the limb 42b. In the same manner, the lower spherical bearing 57 has a clamping member 61a that contacts the ball segment 58 and that is connected to the spacer bolt 50 by a stud bolt 61b. The bolster is connected by the stud bolt 63 to the pot 12 and thus to the lower spherical joint bearing 57.
Rolling, pitching, kink and compensating movements or also combinations of these movements can now be taken up and transmitted by the spherical joint mechanism 40 having the two joint bearings arranged above one another and spaced apart from one another; in addition, this design, however, also ensures that the bolster remains substantially free of torque on an engagement of horizontal forces. This results from the following:
The spherical joint bearing 47 has a pivot point 70; the spherical joint bearing 57 has the pivot point 75. The spacing between the two pivot points 70 and 75 is marked by 80 and forms a lever arm. If forces in a horizontal direction are now introduced into the pivot point 70 of the spherical joint mechanism 40, the ball segment 58 of the lower spherical joint bearing 57 can pivot in the bearing shell 59. This means that the torques arising due to the introduction of horizontal forces into the upper spherical joint bearing 47 are substantially intercepted by the lower spherical joint bearing 57, whereby the bolster 10 on which the spherical joint mechanism 40 is held by the pot 12 remains substantially free of torque.
Number | Date | Country | Kind |
---|---|---|---|
15178284.4 | Jul 2015 | EP | regional |
This application is the U.S. national stage of PCT/EP2016/000682 filed Apr. 27, 2016, which claims priority of European Patent Application 15178284.4 filed Jul. 24, 2015 of which is hereby incorporated by reference in its entirety.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2016/000682 | 4/27/2016 | WO | 00 |