EP0621165B1 - Running gear for railway vehicles - Google Patents

Abstract

The invention relates to running gear for rail vehicles in which a running gear frame (2) is carried by the wheels or wheel sets (1) by means of primary springs, and on which the coach body (4) or the coach body (4) of the rail vehicle is directly supported by means of secondary springs (3) via a rocker (5), and the rocker (5) or the coach body (4) is also connected with respect to the running gear frame (2) by means of shock absorbers which damp vertical and rolling movements and at least one rail support (8-10) which absorbs rolling movements and bears fixed levers (9) which are connected to the rocker (5) or to the coach body (4) via pendulum element (10) which are mounted in an articulated fashion. The object of the invention is, with the aim of achieving a maximum possible coach cross-section, to find an inclination device in which, during the rolling of the coach body (4) when there is an excess of centrifugal force, as far as possible the centre of motion lies in the plane of the centre of rolling, which inclination device can be retrofitted on existing running gear, can be used under existing coach bodies (4) and is distinguished by simple constructional elements. This object is achieved in that at least one of the pendulum elements (10) of the roller support consists of an actuator which can be acted on in the opposite direction when one transverse end of the rocker (5) or one side of the coach body (4) dips or rises. <IMAGE>

Description

The invention relates to a running gear for rail vehicles, in which a running gear frame is supported by primary springs from the wheels or wheel sets and on which the car body or the car body of the rail vehicle is supported directly via secondary springs via a cradle and the cradle or the car body further relative to the running gear frame Shock absorbers which dampen vertical and roll movements and at least one roll support which dampens roll movements is connected, which carries fixed levers which are connected to the cradle or the car body via articulated pendulums.

Such a drive is known for example from DE-OS 41 22 741.

In particular when cornering, the centrifugal force results in roll movements of the car bodies, which are generally cushioned by means of a roll support. During these roll movements, the car body tilts to the outside of the curve in accordance with the centrifugal force on the spring system and increases the lateral acceleration on the passenger. These subjectively unpleasant side accelerations limit the driving speed, especially on winding roads.

From practice it is already known to incline the car body against the centrifugal force when cornering and thereby to reduce the lateral acceleration.

In one of these previously known inclination systems (Talgo-Pendular-System, ETR 42 (1993) H1-2, p. 39), a pendulum of the car body with a high-lying rotary pole is realized by a high-placed secondary spring in such a way that the car body is similar to one free pendulum moves and thus the centrifugal force is reduced to the passenger. A disadvantage of this system is that the outer contour of the car in the lower area (seat level) has to be restricted, which in turn results in a reduction in the available passenger space.

In a further known inclination system (SIG-Neitec ETR 42 (1993) H1-2, pp. 36, 37), a pendulum device is arranged between a cradle of the drive and the drive frame, an air cylinder being excited between the cradle and the drive frame by centrifugal force is activated, which is arranged horizontally in the transverse direction between the cradle and the carriage frame and tilts the cradle or the car body with a lifting movement towards the inside of the bow, the lifting movement being brought about by the unstable pneumatic cylinder, which reacts to transverse movements between the cradle and the carriage frame. The center of rotation of the pendulum system is around the center of gravity of the car body. A disadvantage of this embodiment is that, in order to activate the inclination system (pendulum device), transverse movements between the cradle and the carriage frame are required to a considerable extent in order to accomplish the inclination. As a result, the usable cross section of the car body is significantly reduced.

In practice, a pendulum suspension of the car body as described above is known (ABB-Neitec X2000 ETR 42 (1993) H1-2, p. 31, 32), but here a working cylinder is arranged transversely between the drive frame and the cradle, whereby the working cylinder is actively acted upon by means of control electronics which are dependent on transverse acceleration. The working cylinder uses the pendulum system to tilt the car body against the centrifugal force, the achievable angle of inclination being approximately 8 °.

The fulcrum of this system is also around the center of gravity of the car body. The disadvantage of this system is that the rotating pole in the axis of gravity again reduces the cross-section of the usable body.

From the magazine Ö & P Oil Hydraulics and Pneumatics, Issue 36 (1992), No. 10 it is also known that for the roll angle correction between the carriageway and car body in case of excess centrifugal force, working cylinders are arranged between the chassis and the car body, with several working cylinders in succession in the longitudinal direction of the car body are arranged, these are interconnected and switched so that an even load distribution takes place on all trolleys. The roll angles are compensated for by corresponding electronically controlled actuation of the working cylinders and corrected to the mean roll angle 0. The task of this known device is therefore limited to a roll angle correction for uniform loading of the bogies.

The object of the present invention is to find a tilting device in order to achieve the largest possible wagon cross-section, in which, when the wagon body is swayed with excess centrifugal force, the rotation pole is in the plane of the wanking pole, which can be retrofitted to existing drives, which can be used under existing wagon bodies and which can be used characterized by simple components.

This object is achieved in the above-mentioned drive in such a way that at least one of the pendulum of the anti-roll support consists of an actuator which can be acted upon in the opposite direction when immersing or lifting a transverse end of the cradle or one side of the car body. The advantage of this training lies in the fact that the rotating pole lies approximately at the level of the secondary spring, thereby making the greatest possible use of the boundary profile.

According to the invention advantageously both pendulums consist of actuators. The actuators are also advantageously lockable. It is also advantageous that the actuators can be locked in their end position. According to one embodiment of the invention, at least one actuator on both sides of the longitudinal axis of the rail vehicle is equipped with a travel measuring device that measures the required stroke movement of the actuators to compensate for the roll movement. Two anti-roll supports are advantageously arranged symmetrically to the transverse axis of the drive with pendulums consisting of actuators. According to the invention it is further conceivable that the actuator consists of a working cylinder. As an alternative, the actuator can be designed as a mechanical linear drive according to the invention. By means of the invention described above, the drive for a rail vehicle can advantageously be equipped with a tilting device which can also be retrofitted into existing drives. The inclination device according to the invention can also be used under existing car bodies and is characterized by simple components. In particular, the greatest possible usable carriage cross section is achieved by the inclination device according to the invention.

According to an alternative embodiment of the invention in a running gear for rail vehicles, in which a running gear frame is supported by primary springs from the wheels or wheel sets and on which the wagon body or the wagon body of the rail vehicle is supported directly via secondary springs and the cradle or the wagon body further compared to the drive frame via vertical and roll movements damping shock absorbers and at least one roll movement damping roll support is connected, which carries fixed levers that are connected via articulated pendulums to the cradle or the car body, an actuator is integrated in a torsion shaft of the roll support that when immersing or lifting a transverse end of the cradle or one side of the car body can be acted on in the opposite direction.

Details of the invention are explained with reference to the drawing in one embodiment.

Fig 1

Den Querschnitt durch ein Laufwerk gemäß der Erfindung

Fig 2

Einen Teil der Draufsicht auf das Laufwerk nach Fig 1

Fig 3

Einen Teil eines Mittellängsschnittes durch das Laufwerk nach Fig 1

Das erfindungsgemäße Laufwerk besteht im wesentlichen aus dem von den zwei Radsätzen (1) über nicht dargestellte Primärfedern getragenen Laufwerkrahmen (2), auf dem über pneumatische Sekundärfedern (3) eine den Wagenkasten (4) tragende Wiege (5) vertikal beweglich gelagert ist. Der Wagenkasten (4) lagert dabei über seitliche, oberhalb der Sekundärfedern (3) auf der Wiege (5) befestigte Gleitstücke (6) auf dem Laufwerk und ist über einen zentrisch in der Wiege (5) angeordneten Drehzapfen (7) auf dem Laufwerk horizontal geführt. Neben erforderlichen, für vorliegende Erfindung nicht relevanten Vertikal- und Schlingerdämpfern ist die Wiege (5) weiter gegenüber dem Laufwerkrahmen (2) über mindestens eine, im dargestellten Ausführungsbeispiel zwei Wankstützen abgefedert. Jede dieser Wankstützen besteht aus einer horizontal in Laufwerkquerrichtung am Laufwerkrahmen (2) drehbar gelagerten Torsionswelle (8), die an ihren Längsenden drehfest Hebel (9) trägt, an deren freiem Ende etwa vertikal ein Pendel (10) gelenkig gelagert ist. Dieses Pendel (10) ist mit seinem anderen freien Ende ebenfalls gelenkig an der Wiege (5) befestigt.Show it

Fig. 1

The cross section through a drive according to the invention

Fig. 2

Part of the top view of the drive according to FIG. 1

Fig 3

Part of a central longitudinal section through the drive according to FIG. 1

The drive according to the invention essentially consists of the drive frame (2) carried by the two wheel sets (1) via primary springs (not shown), on which a cradle (5) carrying the car body (4) is mounted so that it can move vertically via pneumatic secondary springs (3). The car body (4) is mounted on the carriage via lateral sliders (6) attached to the cradle (5) above the secondary springs (3) and is horizontal on the carriage via a pivot pin (7) arranged centrally in the cradle (5) guided. In addition to the necessary vertical and anti-roll dampers which are not relevant to the present invention, the cradle (5) is further cushioned with respect to the drive frame (2) by at least one, two roll supports in the exemplary embodiment shown. Each of these anti-roll supports consists of a torsion shaft (8) which is rotatably mounted horizontally in the transverse direction of the running gear on the running gear frame (2) and which has non-rotatably mounted levers (9) at its longitudinal ends, at the free end of which a pendulum (10) is articulated approximately vertically. This pendulum (10) is also articulated to the cradle (5) with its other free end.

When the car body (4) with the cradle (5) rolls in the transverse direction of the vehicle, the cradle (5) dips into the secondary spring (3) with its one transverse end and rises with a corresponding amount from the secondary spring (3) on this side. out. These rolling movements are transferred via the pendulum (10) and lever (9) into the torsion shaft (8) and twist the torsion shaft (8). The roll movements are cushioned by the spring action of the torsion shaft (8). With this roll load, the torsion shaft (8) acts via the pendulum (10) and lever (9) and provides the roll stiffness necessary for good running properties. The vehicle wobbles around a roll pole, which is determined from the vehicle's system parameters such as primary spring stiffness, stiffness of the roll support, base of the secondary spring and center of gravity. Under centrifugal force, the torsion shaft (8) of the anti-roll device is stretched until the required counterforce is achieved, which creates the balance of forces. In the embodiment of the drive according to the invention, at least one of the pendulums (10) is designed as an actuator. This actuator (pendulum (10)) overcompensates the deformation of the torsion shaft (8) by extending or retracting, so that the vehicle is inclined into the curve with unchanged roll stiffness and roll pole. The actuator (pendulum (10)) does not work against the weight of the vehicle but only rotates the body around the pole. The secondary spring (3) is stretched in the vertical direction on the outside of the arc and the corresponding secondary spring (3) is compressed inside the arc. Thanks to the two-point air spring control, this happens with only a slight resistance of the secondary springs (3) (only air flow resistance). As in the normal state, the vertical suspension is provided by the compressed or stretched secondary spring (3). The required inclination of the car body (4) is controlled depending on the excess centrifugal force or depending on the force. This control of the actuators (pendulum (9)) is not the subject of the present invention.

Claims (9)

1. Running gear for rail vehicles, in which a running gear frame is supported, via primary springs, by the wheels or wheelsets and on which the coach body is supported via secondary springs, by means of a bolster, or on which the coach body of the rail vehicle is directly supported, and on which, furthermore, the bolster or coach body is connected, relative to the running gear frame, by means of shock absorbers, which dampen vertical and rolling motions, and at least one roll-support, which cushions rolling motions and supports fixed levers connected by hinge-mounted pendulums to the bolster or coach body, characterized in that at least one of the pendulums (10) comprises a final control element, which, when a transverse end of the bolster (5) or a side of the coach body (4) plunges or rises, can be actuated in the counter-direction.
2. Running gear according to Claim 1, characterized in that both pendulums (10) comprise final control elements.
3. Running gear according to Claims 1 and 2, characterized in that the final control elements are lockable.
4. Running gear according to Claims 1 to 3, characterized in that the final control elements are lockable in the end position.
5. Running gear according to Claims 1 to 4, characterized in that at least one final control element is equipped on both sides of the longitudinal axis of the rail vehicle with a path-measuring instrument measuring the necessary lifting motion of the final control elements in order to compensate for the rolling motion.
6. Running gear according to Claims 1 to 5, characterized in that two roll-supports (8 to 10) are disposed symmetrically to the transverse axis of the running gear, having pendulums (10) comprising final control elements.
7. Running gear according to Claims 1 to 6, characterized in that the final control element comprises a working cylinder.
8. Running gear according to Claims 1 to 7, characterized in that the final control element is configured as a mechanical linear drive mechanism.
9. Running gear for rail vehicles, in which a running gear frame is supported, via primary springs, by the wheels or wheelsets and on which the coach body is supported via secondary springs, by means of a bolster, or on which the coach body of the rail vehicle is directly supported, and on which, furthermore, the bolster or coach body is connected, relative to the running gear frame, by means of shock absorbers, which dampen vertical and rolling motions, and at least one roll-support, which cushions rolling motions and supports fixed levers connected by hinge-mounted pendulums to the bolster or coach body, characterized in that there is integrated into a torsion shaft (8) of the roll-support (8 to 10) a final control element, that [sic], when a transverse end of the bolster (5) or a side of the coach body (4) plunges or rises, can be actuated in the counter-direction.

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