EP3645353A1

EP3645353A1 - Rail vehicle having a starting assistance function based on frictional braking forces

Info

Publication number: EP3645353A1
Application number: EP18735506.0A
Authority: EP
Inventors: Philippe Artru; Reinhard Loebner
Original assignee: Knorr Bremse Systeme fuer Nutzfahrzeuge GmbH; Knorr Bremse Systeme fuer Schienenfahrzeuge GmbH
Current assignee: Knorr Bremse Systeme fuer Nutzfahrzeuge GmbH; Knorr Bremse Systeme fuer Schienenfahrzeuge GmbH
Priority date: 2017-06-30
Filing date: 2018-06-12
Publication date: 2020-05-06
Also published as: WO2019001950A1; EP3645355A1; WO2019001949A1; EP3645354B1; WO2019001951A1; DE102017009125A1; EP3645354A1; DE102017009127A1

Abstract

The invention relates to a rail vehicle (1), comprising a frictional-force-based braking device (18) controlled by an electronic control device (6), an electric traction drive, which is controlled by the electronic control device (6) and which drives the rail vehicle, and an input device (12), by means of which a first signal (8) representing a starting request can be input into the electronic control device (6), a starting assistance function being implemented in the electronic control device (6), by means of which starting assistance function a release of the frictional-force-based braking device (18) and an activation of the electric traction drive are controlled during a transition from a detected standstill to a driving state when the first signal (8) representing the starting request is received from the input device (12) by the electronic control device (6). According to the invention, a sensor device (48) is provided, which directly or indirectly senses the standstill frictional braking force (FHR) holding the rail vehicle (1) at a detected standstill and/or the standstill frictional braking torque (MHR) holding the rail vehicle (1) at a detected standstill or a standstill variable derived from the standstill frictional braking force and/or from the standstill frictional braking torque and which inputs a third signal (42) dependent on the sensed standstill frictional braking force and/or on the sensed standstill frictional braking torque or on the sensed derived standstill variable into the electronic control device (6), and thereupon the electronic control device (6) controls the frictional-force-based braking device (18) and in particular also the traction drive in accordance with the third signal (42) within the framework of the starting assistance function when the first signal (8) representing the starting request is received by the electronic control device (6).

Description

Rail vehicle with a traction aid function based on friction braking forces

description

The invention is based on a rail vehicle with a friction-force-based braking device controlled by an electronic control device, an electric traction drive controlled by the electronic control device, which drives the rail vehicle, an input device by means of which a signal representing a start-up request can be input into the electronic control device, wherein the electronic control device is implemented a traction assistance function by which a release of the friction-force-based braking device and an activation of the electric traction drive is controlled at a transition from a detected stop to a driving state, when received by the electronic control device, the signal representing a starting request from the input device, according to the preamble of claim 1.

Such a rail vehicle is known for example from DE 10 2009 005 624 A1. There, it is stated that when traction vehicles start from a standstill, above all at gradients and inclines, the traction force of the traction drive and the braking force must be controlled in a coordinated manner in order to prevent the rail vehicle from being hit during start-up, for example. rolling back on a slope route. It can come in particular to a jerky start, which affects the comfort of the passengers. It has therefore been proposed to coordinate the control of the braking force and the control of the traction force, on the one hand to prevent rolling back and on the other hand to improve the comfort.

This implements a so-called traction aid function or a Hill Start Assist or Hill Start Assist, which provides an automated support, for example here for rail vehicles when approaching inclines, through which rolling back prevent is changed. The driver of the rail vehicle does not need to operate the service or parking brake system. With this comfort function, the brake is released when starting only when the traction drive provides sufficient torque to prevent rolling back of the rail vehicle.

According to DE 10 2009 005 624 A1, such a traction aid is implemented in a rail vehicle by detecting a rolling back of the rail vehicle when starting from standstill from the course of the measured speed and then controlling the traction force of the traction drive with the aid of this measured speed. The disadvantage here, however, on the one hand, that passive speed sensors only from a certain speed limit detect a non-zero speed and on the other hand, that the rail vehicle when starting from a standstill must first roll back a bit before the control of the traction drive can be active.

The invention is based on the object, a rail vehicle with traction help function by the simplest possible means such that the disadvantages described above can be avoided.

This object is achieved by the features of claim 1. Advantageous developments of the invention are the subject of the appended subclaims.

Disclosure of the invention

The invention is based on a rail vehicle having a friction-force-based braking device controlled by an electronic control device, an electric traction drive controlled by the electronic control device, which drives the rail vehicle, an input device by means of which a first signal representing a start-up request can be input into the electronic control device in the electronic control device, a traction assist function is implemented, by which a release of the friction-force-based braking device and an activation of the electric traction drive at is controlled a transition from a detected stop to a driving condition when the electronic control device has received the first signal representing the approaching request from the input device.

Consequently, a standstill of the rail vehicle must on the one hand actively detected by the electronic control device and on the other hand be received by the electronic control device representing a Anfahrwunsch first signal from the input device before the electronic control device as part of the traction help the release of friction-based braking device and the activation of the electric Traction drive coordinated.

According to the invention, a sensor device is provided, which contains at least the stationary friction braking force holding the rail vehicle at a detected standstill and / or the stationary friction braking torque holding the rail vehicle at a detected standstill or one derived from the standstill friction braking force and / or from the standstill friction braking torque Detected directly and indirectly and generates a third signal dependent on the detected standstill friction braking force and / or the detected standstill friction braking torque or the detected derived standstill size and drives in the control device, and that the electronic control device is designed to as part of the traction help function, the friction-force-based braking device and in particular also controls the traction drive depending on the third signal when it has received the first signal representing the approach request.

Although the rail vehicle is in the braked state, external forces, such as downhill forces such as stalling the rail vehicle on a downgrade or uphill slope, can cause significant stiction forces to exist between the friction partners of the friction based braking device at standstill Standstill static friction forces are called. In a disk brake device, the standstill friction braking force corresponds approximately to the static friction force at the effective locations between the brake disk and the brake linings. This adhesive driving force then constitutes a circumferential force because it acts tangentially with respect to the circular circumferential direction of the brake disk. From this static friction force can then be determined as a product of the standstill friction braking force and the lever arm between the center axis of the brake disc and the effective sites readily standstill friction braking torque.

Indirectly detecting the standstill friction braking force and / or the stall friction braking torque or the quantity derived therefrom is understood to mean, for example, an element somewhere within the power flow between the frictional contact of the friction partners of the friction based braking device and a coupling of mechanical elements of the braking device Measured on a car body or chassis of the rail vehicle reaction force and then measured the standstill friction braking force and / or the standstill friction braking torque from this measured reaction force and the present geometric relationships such as Lever arms is determined.

Preferably, the sensor device is also configured to directly or indirectly detect a starting friction braking force and / or a starting friction braking torque or a starting variable derived from the starting friction braking force and / or from the starting friction braking torque, wherein the detection of the starting torque is Friction braking force and / or the starting friction braking torque during a transition from the detected standstill to a driving state in which the friction-force-based braking device has just been transferred to a fully released state, and that the third signal (also) depending on the detected start-up Friction brake force and / or produced by the detected starting friction braking torque or by the detected derived starting-size and einsteuert in the electronic control device.

The completely released state of the friction-force-based braking device is determined, for example, by the sensor device in that then the summarized frictional braking force and / or the detected friction braking torque is approximately equal to zero.

In a disc brake device, the starting frictional braking force approximately corresponds to the sliding frictional force at the effective locations between the brake disc and the brake linings. This sliding frictional force also constitutes a circumferential force because it acts tangentially with respect to the circular circumferential direction of the brake disk. From this sliding frictional force can then be determined as a product of the starting friction braking force and the lever arm between the center axis of the brake disc and the active sites readily the starting friction braking torque.

By indirectly detecting the starting friction braking force and / or the starting friction braking torque or the starting variable derived therefrom, it is to be understood that, for example, an element somewhere within the power flow between the frictional contact of the friction partners of the friction-based braking device and a coupling of measured reaction force on a car body or chassis of the rail vehicle and then the starting friction braking force and / or the starting friction braking torque from this measured reaction force and the present geometric relationships such as Lever arms is determined.

In other words, as part of the traction help function, the coordination between releasing the friction-force-based braking device from its standstill applied state on the one hand and the activation of the electric traction drive and optionally also the size of the traction drive generated by the traction drive or the starting torque generated by the traction drive on the other hand controlled on the basis of the third signal, which depends on the sensor device a) from the detected standstill friction braking force and / or the detected standstill friction braking torque or the derived standstill size, and / or b) from the detected starting friction braking force and / or from the detected starting friction braking torque or from the detected derived starting magnitude

c) is generated and is controlled in the electronic control device.

In this case, for example, the electronic control device may be configured to calculate a downhill force acting on the rail vehicle on the basis of the third signal (in particular dependent on the detected standstill friction braking force and / or on the detected standstill friction braking torque or on the derived standstill size) or estimates and controls the friction-force-based braking device and / or the traction drive as part of the traction assistance function depending on the calculated or estimated downgrade force.

The downgrade force represents an example of a stall amount derived from the detected stall friction braking force and / or the detected stall friction braking torque.

This training measure is based on the idea that the tendency of the rail vehicle to roll back to the starting pressure is greater, the greater is the downhill power and the smaller the lower the downhill power is and therefore a correspondingly higher or lower starting force provided by the traction drive must, on the one hand to prevent rolling back of the rail vehicle and on the other hand, the starting pressure. Thus, in each case a traction force or a corresponding traction torque in relation to the currently existing downgrade force can be provided controlled by the traction drive by the electronic control device, by which (s) a rollback and a starting jerk are just avoided.

In order to avoid rolling back of a rail vehicle approaching, for example, uphill, the following condition must be fulfilled at all times:

FlVlotor ⁺ Fßrems ^> F | - | ang in which

FMotor the starting traction force of the traction drive when starting,

Fßrems the (still) acting braking force when starting,

F _{Hang is} the downhill force on the uphill stretch.

Accordingly, the starting traction force or starting traction torque applied by the traction drive when starting off from standstill within the traction aid is preferably (also) dependent on the gradient acting on the rail vehicle on inclines under the premise of a jerk-free and non-traction approach

Downgrade force determined, which in turn is calculated or estimated on the basis of the third signal from the electronic control device.

In addition, other parameters that may play a role in a traction help function can be determined depending on or based on the third signal or on the basis of the calculated or estimated downgrade force, such as the time period within which the friction force based braking device from zuspannten state in the complete release state is transferred and / or the period of time within which the traction drive must apply a required traction force or a required traction torque. Such a period of time may also include information about the time of the beginning and the end of the respective period of time.

The invention can be implemented with simple means, because for this purpose only a determination or measurement of the stationary and / or starting friction brake force and / or the stall and / or starting friction braking torque within the friction-based braking device and an implementation of a corresponding evaluation software in the electronic control device are necessary.

The features listed in the dependent claims advantageous developments of the invention specified in the independent claim are listed. The friction-force-based braking device preferably has at least one disc brake device assigned to a wheel or a wheel set and attached to a chassis, which has at least one brake pad which comes into frictional contact with brake disc for brake release and brake contact for brake release, a brake caliper connected to the at least one brake pad and a brake housing, on which the brake caliper is mounted.

Furthermore, the sensor device may comprise at least one sensor which is arranged and configured on or in the disc brake device and / or on or in the console and / or on at least one bearing point of the console on the chassis, that the sensor at least at standstill and / or during Approaching the rail vehicle directly or indirectly measures the friction braking force acting on the brake disk or the frictional braking torque acting on the brake disk and then generates the third signal.

The term "friction braking force" or "friction braking torque" should be understood to mean at least the standstill friction braking force and / or the starting friction braking force or the standstill friction braking torque and / or the starting friction braking torque.

For example, the brake housing on the console on the one hand articulated by a hinge bearing and on the other hand supported by a support supporting the at least one sensor such that the brake housing pivots due to the adhesion or Gleitreibungskontakt the at least one brake pad with the brake disc friction brake force to the joint bearing and thereby a reaction force is generated in the support, which measures the at least one sensor directly or indirectly. For the determination of the friction braking force then the lever arm between the joint bearing and the support is authoritative.

Alternatively or additionally, for example, two mutually spaced sensors arranged on or in the console or at their bearings on Car body be arranged, between which then in relation to the reaction forces measured by them then a lever arm is present, from which the electronic control device can then easily on the friction brake torque or the friction brake force.

In particular, the sensor may be formed by a force measuring sensor, such as by a strain gage strain gauge with associated electronic bridge circuit, e.g. in the electronic control device or by a working on the basis of thin-film technology (DFT) sensor.

In order to check the plausibility of the third signal output by the at least one force measuring sensor, at least one pressure measuring sensor can be provided which, in the case of a pneumatic disc brake device, measures the brake pressure and activates it in the electronic braking device, from which it uses an implemented algorithm in which the known geometric dimensions of the one or more pneumatic or hydraulic braking force generator (s) of the disc brake device determines the normal force acting on the brake disc and from this and the static friction coefficient or coefficient of sliding friction then the friction braking force and compares this value with the value obtained on the basis of the force measuring sensor.

According to a preferable measure, the friction-force-based braking device can be formed by an active friction-force-based electro-pneumatic or electro-hydraulic service brake device or by a passive friction-force-based electro-pneumatic spring brake device or by a friction-force-based electro-mechanical brake device.

drawing

The invention will be described in more detail below by means of embodiments with reference to the accompanying drawings. Show it: a highly schematic illustrated and braked on a slope held rail vehicle with, for example, three bogies; a plan view of a highly schematically illustrated Scheibenbrem device direction as assigned to the rail vehicle of Figure 1, for example, each axis of a bogie. a highly schematic side view of a bogie, which is arranged here by way of example on an axis a disc brake device according to a first embodiment; a highly schematic side view of a bogie, to which here by way of example on an axis a disc brake device according to a second embodiment is arranged

Description of the embodiments

The rail vehicle 1 shown in Figure 1 according to a preferred embodiment of the invention, for example, three bogies 2, each with two axes 4 and is held here, for example, braked on a slope distance.

The rail vehicle 1 has an electronic control device 6, which may be formed as a single unit or unit or functionally divided into a plurality of separate control devices.

This electronic control device 6, shown in FIG. 3 and FIG. 4 for reasons of simplicity of illustration, controls not only an electro-pneumatic service brake device but also an electric traction drive of the rail vehicle. Also, not shown here electro-pneumatic parking brake device is preferably controlled by the electronic control device 6. The electronic control device 6 furthermore receives a first signal 8 by means of a first signal line 10 from an input device 12 indicated in FIGS. 3 and 4, by way of which a driver controls the traction drive in the forward direction. can control the time spent by the traction drive Antnebsleistung. The electronic control device 6 then controls a traction request signal, which is dependent on the first signal 8 and on safety and / or comfort functions, in the traction drive in order to drive the rail vehicle 1 accordingly.

The electro-pneumatic service brake device and the electro-pneumatic parking brake device, which has as a force generator, for example, passive spring brake cylinders, for example, each equipped with an electro-pneumatic, controlled by the electronic control device valve device 14 (Figure 3 and Figure 4). From the electro-pneumatic valve device 14 of the electro-pneumatic service brake device, a pneumatic line 16 is pulled to pneumatic disc brake devices 18. In this pneumatic line 16, a brake pressure sensor 20 is preferably arranged, which measures the pneumatic brake pressure fed into the disc brake device 18 and feeds back a corresponding brake pressure signal as a second signal 21 via a second signal line 22 into the electronic control device 6, for example within one into the electronic control device 6 implemented brake pressure control to measure an measured by the brake pressure sensor actual brake pressure to a desired brake pressure, which corresponds to a brake request signal.

In this electronic control device 6, a traction help function is implemented, which provides an automated assistance when starting the rail vehicle 1, in particular on gradients as in Figure 1, by the rolling back or a starting pressure is prevented. The driver of the rail vehicle 1 does not need to operate the service or parking brake system. As a result of this comfort function, the service brake device, for example, is only released when the traction drive provides sufficient torque to prevent the rail vehicle 1 from rolling back. Consequently, the control of the electro-pneumatic braking device and of the electric traction drive is coordinated with the aid of this traction aid function when starting the rail vehicle 1 in the situation shown in FIG. 1 (approaching the downhill force). FIG. 2 shows a schematic plan view of a pneumatic disc brake device 18, as is present here, for example, on each axle of the bogies of the rail vehicle. In addition to the electronic control device 6 already described above, which controls the individual pneumatic disc brake devices 18 on the axles 4 via the electro-pneumatic valve device 14, a respective brake disc 24 is present here, for example, two pliers levers 26 of a brake caliper 28 fastened to the brake disc 24 The brake linings 30 are each attached to one end of a caliper lever 26 of the brake caliper 28 in Bremszuspannfall rubbing cooperating brake pads. The brake caliper 28 is attached to a brake housing 32 at one or more bearings on a console 34, which in turn is mounted on the bogie 2 by bearings 36. Exemplary embodiments of such a console 34 are shown in FIG. 3 and in FIG.

In Figure 2 is not directly visible in the brake housing 32 of the pneumatic disc brake device 18, a pneumatic brake cylinder arranged as a force generator, which acts on the caliper levers 26 of the brake caliper 28 driving. During the travel of a rail vehicle 1, the brake disk 24 rotates about a rotation axis 38. The brake linings 30 are arranged laterally to the brake disk 24 and in particular in a tolerance range parallel to the side surfaces of the brake disk 24. The active surfaces of the brake pads 30 each cover a portion of a side surface of the brake disc 24. The brake caliper 28 has in the embodiment of a U-shape.

By an input from the electronic control device 6 via an electrical control line 40 in the electro-pneumatic valve device application signal, this electro-pneumatic valve device 14 generates a pneumatic brake pressure with which the pneumatic brake cylinder of the disc brake device 18 is vented, in which case the pliers lever 28, the two brake pads 30 bring in frictional contact with the brake disc 24 and here symbolized by arrows normal forces F _N, a frictional force between the brake pads 30 and the brake disc 24 is generated, which are aligned parallel to the side surfaces of the brake disc 24. In the case of the rail vehicle 1 braked on the slope by means of the disk brake devices 18, a friction braking force F _H R is generated by each of the disk brake devices 18, which are also shown as an arrow in FIGS. 3 and 4, or a corresponding friction braking torque M _H R generates. At standstill, this frictional braking force F _H R corresponds in each case to the static frictional force, which results from brake friction linings 24, 30 based on the respective coefficient of static friction between the friction partners. Therefore, the total friction braking force F _H R, ie the total friction braking force acting on the rail vehicle 1 at standstill, the sum of the friction braking forces F _H R at the action points between the brake disc 24 and the brake pads 30. This friction brake force F _H R represents then a circumferential force, because it acts tangentially with respect to the circular circumferential direction of the brake disk 24, as can be easily imagined from the arrows representing the friction braking force F _H R in FIG. 3 and FIG.

The rail vehicle 1 is therefore in the situation of Fig. 1 in a state decelerated by the disc brake devices 18 and at a standstill, which is detected by suitable sensors e.g. is detected by speed sensors.

Furthermore, a sensor device is provided which detects the rail brake vehicle in the detected standstill holding friction braking forces F _H R of the disc brake devices 18 here, for example, indirectly.

The sensor device is also designed to directly or indirectly detect a starting friction braking force F _H R and / or a starting friction braking torque M _H R or a starting amount derived from the starting friction braking force and / or the starting friction braking torque, wherein the detection of the starting friction braking force F _H R and / or the starting friction braking torque M _H R takes place during a transition from the detected standstill to a driving state in which the friction-force-based braking device has just been transferred to a fully released state. The fully released state of the friction-based Scheibenbremseinnchtung example, determined by the sensor device that then the detected friction braking force F _H R and / or the detected friction braking torque M _H R is approximately equal to zero.

The sensor device is then designed such that it respectively activates a third signal 42 which is dependent on the friction braking force F _H R, which is indirectly detected here, or which represents it, via a third signal line 44 into the electronic control device 6. Alternatively or additionally, generation of the third signal 42 on the basis of the directly or indirectly detected friction braking torque M _H R is possible.

The directly or indirectly detected friction braking force F _{HR represents} a static friction braking force (standstill) or a sliding friction braking force (starting) and the directly or indirectly detected friction braking torque M _H R is a static friction braking torque (standstill) or a sliding friction braking torque (starting).

In the embodiment of Figure 3, for example, the brake housing 32 of the disc brake device 18 on the one hand on the mounted on the bogie bracket 34 by a joint bearing 46 articulated and on the other hand mounted on the bogie 2 by a force measuring sensor 48 of the sensor device supporting support 50.

When the rail vehicle is at a standstill, the brake housing 32 is pivoted about the pivot bearing 46 as a result of the frictional braking force F _H R created by the friction contact of the brake pads 24, thereby generating a reaction force, for example, as a tensile force in the support 50, which, for example, on the support 50 arranged force measuring sensor 48 of the sensor device measures and reports to the electronic control device 6 via the third 44 signal line. In the electronic control device 6, the frictional braking force F _H R generated by the disc brake device 18 is then determined on the basis of the third signal 42 of the force measuring sensor 48 and of the lever arm between the pivot bearing 46 and the support 50. Alternatively or additionally, in the electronic control device 6, the frictional braking force F _H R generated by the disc brake device 18 can be determined based on the signal of the brake pressure sensor 20, for example by an implemented algorithm, on the basis of stored geometric dimensions of the pneumatic brake cylinder of the disc brake device 18 on the brake disc 24 acting normal force F _N and from this and the adhesion friction coefficients or the sliding friction coefficient then the friction braking force F _H R is determined.

In this case, the signal of the brake pressure sensor 20 and the signal of the force measuring sensor 48 for mutual plausibility and monitoring within the electronic control device 6 can be used. In both cases, it is an indirect detection of the friction braking force F _H R _, because this is just not measured directly at the effective locations between the brake pads 30 and the brake disc 24. Alternatively, of course, it is also conceivable to determine the friction braking force F _H R directly at these active sites.

The traction help function then coordinates when starting the rail vehicle 1 from the situation shown in Figure 1 on a input via the input device 12 representing a desire to start representing first signal 8 out the release of the disc brake means 18 of the rail vehicle and the activation ie in starting the electric Traction drive and optionally also the size of the traction drive generated by the traction drive or the starting torque generated by the traction drive on the basis of the third signal 42, which represents the friction braking force F _H R.

In other words, as part of the traction assist function, the coordination between the disengagement of the friction-force-based disc brake devices 18 and the activation of the electric traction drive and, in particular, the magnitude of the traction drive generated by the traction drive and the starting torque generated by the traction drive are based on the example of FIG indirectly detected frictional braking force F _H R dependent third signal 42 controlled. The electronic control device 6 can also be designed to calculate or estimate a downhill force acting on the rail vehicle 1 on the basis of the third signal 42 dependent on the detected friction braking force F _H R, and in the context of the traction assistance function as a function of the calculated or estimated downforce force, the friction force-based Disc brake devices 18 and in particular the traction drive controls or coordinates.

This advancing measure is based on the idea that the tendency of the rail vehicle 1 to roll back to the starting pressure is greater, the greater is the downhill power and the smaller the lower the downhill power and thus a correspondingly higher or lower starting force provided by the traction drive must be on the one hand to prevent rolling back of the rail vehicle 1 and on the other hand, the starting pressure. Thus, a traction force or a corresponding traction torque controlled by the traction drive can be made available by the electronic control device 6 in each case in relation to the currently present downgrade force, by means of which (s) rollback and a starting jerk are precisely avoided.

In addition, other parameters that may play a role in a traction help function can be determined depending on or based on the third signal dependent on the detected friction braking force F _H R or on the basis of the calculated or estimated downforce force, such as the time duration within which the friction-force-based disc brake devices 18 is transferred from the application state to the complete release state and / or also the time period within which the traction drive has to apply a required traction force or a required traction torque. Such a period of time may also include information about the time of the beginning and the end of the respective period of time.

In the embodiment of Figure 4, the brake housing 32 of the pneumatic disc brake device 18 is held by means of the bracket 34 on the bogie 2, for example, seen from each other parallel to the brake disc plane with spaced bearing points 36 of the bracket 34 at the rotary Gesteh 2, for example, each a force measuring sensor 48 is arranged to detect acting on the bearings 36 forces. For reasons of scale, the bearing points 36 and the force measuring sensors 48 are each shown in FIG. 4 as one unit. These force measuring sensors 48 are then covered by the sensor device.

This can be realized, for example, in that the two bearing points have measuring pins as force measuring sensors 48, which are each designed to measure the bearing forces occurring at the respective bearing point and correspondingly output two third signals 42 via the third signal line 44 to the electronic control device 6.

Because then seen in the plane parallel to the brake disc plane, a lever arm between the two bearings 36 is provided by an algorithm implemented in the electronic control unit 6 algorithm of the two third signals 42 and the value for the lever arm, the friction braking torque M _H R and the friction braking force F _H R calculated. As already described in the exemplary embodiment of FIG. 3, here as well, alternatively or additionally, the signal of a brake pressure sensor 20 can be used to make the third signal plausible.

LIST OF REFERENCE NUMBERS

1 rail vehicle

2 bogie

4 axis

6 control device

8 first signal

10 first signal line

12 input device

14 valve device

16 pneumatic line

18 disc brake device

20 brake pressure sensor

21 second signal

22 second signal line

24 brake disc

26 pliers lever

28 brake caliper

30 brake pads

32 brake housing

34 console

36 bearings

38 axis of rotation

40 control line

42 third signal

44 third signal line

46 joint storage

48 force measuring sensor

50 support

FHR friction braking force

M _H R Friction braking torque

F _N normal force

Claims

claims

1 . Rail vehicle (1) with

a) a friction-force-based braking device (18) controlled by an electronic control device (6),

b) an electric traction drive controlled by the electronic control device (6), which drives the rail vehicle,

c) an input device (12), by means of which a first signal (8) representing a start-up request can be controlled into the electronic control device (6), wherein

c) in the electronic control device (6) a traction help function is implemented, by which a release of the friction-force-based braking device (18) and an activation of the electric traction drive is controlled in a transition from a detected stop to a driving state, when the electronic control device (6) the first signal (8) representing the approach request has been received by the input device (12), characterized in that

c) a sensor device (48) is provided, which holds at least the standstill friction braking force (F _H R) holding the rail vehicle (1) in a detected standstill and / or the standstill friction braking torque (M _H R) or a standstill quantity derived from the standstill friction braking force and / or from the standstill friction braking torque (MHR) is detected directly or indirectly, and one of the detected standstill friction braking force (F _H R) and / or the recorded standstill Friction braking torque (M _H R) or dependent on the detected derived standstill size dependent third signal (42) generates and einsteuert in the electronic control device (6), and that

d) the electronic control device (6) is designed to control the friction-force-based braking device (18) and, in particular, the traction drive as a function of the third signal (42) as part of the traction help function when they receive the first signal (8) representing the approach request Has.

Rail vehicle according to claim 1, characterized in that the friction-force-based braking device (18) at least one wheel or a wheel set (4) and via a bracket (34) on a chassis (2) fixed disc brake device (18) which at least one with a brake disk (24) for brake clamping in frictional contact and for releasing brake friction brake pad (30), one with the at least one brake pad (30) connected brake caliper (28) and a brake housing (32), on which the brake caliper (28) mounted is.

Rail vehicle according to claim 2, characterized in that the sensor device (48) comprises at least one sensor which is so on or in the disc brake device (18) and / or on or in the console (34) and / or at least one bearing point (36). the console (34) on the chassis (2) is arranged and formed that the at least one sensor at least at standstill and / or when starting the rail vehicle (1) on the brake disc (24) or on the brake pads (30) acting friction brake directly or indirectly measures and generates dependent on the third signal (42).

Rail vehicle according to Claim 3, characterized in that at least one sensor is formed by a force-measuring sensor (48), such as a strain gauge or a sensor based on thin-film technology (DFT).

Rail vehicle according to claim 2 and according to claim 3 or 4, characterized in that the brake housing (32) on the bracket (34) on the one hand articulated by a hinge bearing (46) and on the other hand by a at least one sensor (48) supporting support (50) is mounted such that at the detected stop of the rail vehicle (1) the brake housing (32) due to the frictional contact of the at least one brake pad (30) with the brake disc (24) resulting friction braking force pivoted about the joint bearing (46) and thereby a reaction force in the column (50) is generated, which measures the at least one sensor (48) directly or indirectly.

6. Rail vehicle according to one of the preceding claims, characterized in that the electronic control device (6) is designed to calculate or estimate on the basis of the third signal (42) acting on the rail vehicle (1) downhill power and in the traction assistance function depending on the calculated or estimated

Downgrade force controls the friction force based braking device (18) and / or the traction drive.

7. Rail vehicle according to one of the preceding claims, characterized in that the friction-force-based braking device is formed by an active friction-based electro-pneumatic or electro-hydraulic service brake device or by a passive friction-based electro-pneumatic spring brake device or by a friction-force-based electro-mechanical braking device.

8. Rail vehicle according to one of the preceding claims, characterized in that the sensor device (48) is designed such that it has a starting friction braking force and / or a starting friction braking torque or one of the starting friction braking force and / or the starting friction braking force. Detected friction braking torque derived start-up variable directly or indirectly, wherein the detection of the starting friction braking force and / or the starting friction braking torque during a transition from the detected standstill takes place to a driving condition in which the friction-based braking device (18) of a prevailing at standstill State has been converted to a fully released state, and that it generates the third signal (42) in dependence on the detected starting friction braking force and / or the detected starting friction braking torque or the detected derived starting magnitude and in the electronic control device ( 6) einsteuert.

9. Rail vehicle according to claim 8, characterized in that the completely dissolved state of the friction-force-based braking device is determined, for example, by the sensor device that then the detected friction braking force and / or the detected Reibungsbremsmo- ment are approximately zero.