WO2023099755A1 - Method and device for influencing a travel speed of a rail vehicle - Google Patents

Abstract

The invention relates to a method for influencing a travel speed of a rail vehicle which comprises a friction brake system having at least one friction element (1, 2), wherein the influencing occurs as a function of at least one side effect, in particular brake lining wear, brake noise and/or brake odor, which would be produced by a braking process fictitiously carried out by the friction brake system in a current driving operating situation of the rail vehicle.

Description

DESCRIPTION

Method and device for influencing the driving speed of a rail vehicle

The invention relates to a method and a device for influencing a driving speed of a rail vehicle, which has a friction brake system comprising at least one friction element, according to the preambles of claims 1 and 9. The invention also relates to a rail vehicle with such a device according to claim 17 and a the method containing computer program 18.

field of invention

Rail vehicles often have electrodynamic brakes and, in addition, a friction brake system (blending), with the electrodynamic brakes being primarily used in order to reduce brake wear on the friction brake system. Although some rail vehicles have a friction braking system, they do not have electrodynamic brakes.

Therefore, in the event of a complete or partial failure of the electrodynamic brakes, service braking may have to be carried out mainly or exclusively with the friction brake system. The higher the braking application speed of the rail vehicle, i.e. the higher the speed at which friction braking begins, the higher the energy input and thus the temperature increase of the brake discs and brake pads. As a consequence, the fluctuation of the coefficient of friction p of the brake disc/brake pad pairing increases and with it the probability that the coefficient of friction p will decrease. At high braking application speeds, there is therefore a risk that braking distances will increase due to brake fading.

Brake fading (brake loss) is understood to mean the reduction in the braking effect of a friction brake system due to heating. In order to avoid brake fading, the maximum speed of the rail vehicle is limited by a maximum permitted speed depending on the situation. Besides that This is intended to minimize undesirable side effects of braking, such as brake wear, brake noise and/or brake smell or smoke.

State of the art

The generic WO 2018/054736 A1 discloses a method for influencing a permissible driving speed, among other things, of a rail vehicle in particular with a friction brake system, in which a braking effect is generated by friction elements pressing against one another, at least from information about a speed, a brake pressure and an outside temperature of the vehicle and at least the temperatures of one of the friction elements are predicted over absolute times, with heat conduction through the friction element and speed-dependent cooling of this friction element also being taken into account in order to influence the permissible driving speed, among other things, with regard to a calculated permissible driving profile.

The heat conduction through the friction element can be taken into account quite precisely in the calculations, since this is a material-dependent influencing factor with a small spread. However, this does not apply to the influencing factor of a speed-dependent cooling of the friction element. This is because influences in this regard, such as a disruption in the air flow or a change in humidity, produce a very high scatter range, which can falsify the forecast result.

The present invention is based on the object of further developing a method and a device of the type described above in such a way that undesirable side effects during braking are reliably reduced without the speed of the rail vehicle having to be reduced too much. A rail vehicle with such a device is also to be made available.

This object is achieved according to the invention by the features of independent claims 1 , 9 , 17 or 18 . Disclosure of Invention

The background to the considerations according to the invention is that during operation or when the rail vehicle is in motion in a current driving situation, at least one parameter is determined which characterizes the current driving situation, and that, based on the current driving situation, a braking process is fictitiously carried out, for example simulated.

The initial situation is therefore the current driving operation situation, in which the rail vehicle travels, for example, at a specific speed and load and under specific environmental and route conditions along a route that is, for example, level or has a specific gradient or a specific incline. For example, the speed, the load, the gradient or the gradient of the route are then recorded as parameters.

Undesirable side effects should not only be reduced in relation to the current driving situation, but also remain within a predefined framework in the event that defined braking is carried out in the current driving situation.

Due to the current driving situation, which takes place below a certain ambient temperature, for example, which then also acts on the friction brake element, and due to the fictitious, for example simulated braking process, a predictive (predicted) temperature T _pre d would then set on or in the at least one friction brake element , which is calculated or estimated using a model. The predicted temperature T _pred of the friction element is the sum of the current temperature T _act and the temperature rise AT that results from a fictitious braking: The predicted temperature T _pred that is calculated or estimated on the basis of the current driving situation and the fictitious braking process performed , would then cause a certain level of an undesirable first side effect in the form of brake wear on the friction element, and/or a certain level of an undesirable second side effect in the form of brake noise, and/or a certain level of an undesired third side effect in the form of brake smoke or brake smell .

The invention is based on the knowledge that the undesired side effects are each permitted with a specific maximum Correspond brake element temperature, which must not be exceeded during the ferry operation, so that the extent of each side effect remains below a desired limit.

However, under real conditions it is not sufficient to ensure that the temperature of the braking element is always below a maximum permissible braking element temperature. Because if braking were always performed at the maximum permissible brake element temperature, then in the event of, for example, emergency braking, the brake element would inevitably overheat in an undefined manner.

In order to solve this problem, it is proposed according to the invention that the predictive friction element temperature T _pred of the friction element is assigned a specific maximum permitted driving speed v _max Aiiowed of the rail vehicle related to the first, second and/or third side effect, at which the predictive Friction element temperature T _pre d of the friction element, the extent of the respective side effect that occurs is as large as a predefined maximum allowable extent of the same. The current driving speed v of the rail vehicle is limited to the specific maximum permitted driving speed VmaxAiiowed of the rail vehicle.

In other words, with the solution according to the invention, the driving speed of the rail vehicle is limited as a function of temperature in such a way that when braking, the extent of at least one of several side effects that are harmful to the environment or components, in particular brake pad wear, brake noise and brake smell to the point of brake smoke, is reduced.

Since the predictive temperature T _pred of the frictional member has a significant influence on each magnitude of the above-mentioned accompanying phenomena, the predicted temperature T _pre d of the frictional member is considered to represent the magnitude of the accompanying phenomenon. There is of course also a connection between the predicted temperature T _pred of the friction element and the traveling speed v of the rail vehicle, because braking from a relatively high traveling speed v entails a relatively high predicted temperature T _pre d .

A correlation or association between the predicted temperature T _pred and the running speed v of the rail vehicle is therefore established in the model. The model sets a specific maximum permitted driving speed VmaxAiiowed determines which is related to the respective side effect(s) and which not only takes into account the current driving operation situation, but also a fictitious braking operation. This means that if, for example, the train driver or an Automatic Train Operation (ATO) in a driving situation with a driving speed v, which is at most as high as the specific maximum permitted driving speed v _maxA n _O wed, would initiate a braking process, then the respective side effect are still within the permitted range.

On the other hand, when influencing the driving speed v of the rail vehicle, the speed potential should be exploited, which still exists in a current driving situation until the maximum extent of the relevant side effect(s) is reached, if in the current driving operation situation, for example, the maximum extent of the relevant side effect(s) , for example an upper permissible limit for brake wear and/or for brake smoke and/or for brake smell and/or for brake noise has not yet been reached. Consequently, the specific maximum permitted driving speed v _max Aiiowed can also represent an optimal speed.

According to a first aspect, the invention relates to a method for influencing the driving speed of a rail vehicle, which has a friction brake system comprising at least one friction element, the influencing taking place depending on at least one extent of a first, second or third accompanying phenomenon which occurs in a current driving operation situation of the rail vehicle would result from the braking process that is notionally performed by the friction brake system, with the method a) recording at least one parameter which characterizes the current driving operation situation of the rail vehicle, and in which b) the first side effect is the brake wear caused by the notionally performed braking process in the current driving operation situation of the at least one friction element, and/or as a second side effect the noise caused in the current driving situation by the fictitious braking process, and/or as a third side effect the noise in the current driving situation by the fictitious braking process brake smell or smoke caused by the braking process is used, and in which a predictive friction element temperature (T _pre d) of the Friction element is calculated or estimated, which would occur in or on the friction element if the braking process is notionally carried out in the current driving operation situation of the rail vehicle, and d) in a mapping (r) of the predictive friction element temperature (T _pre d) of the friction element a specific maximum permissible driving speed (v _max Aiiowed) of the rail vehicle related to the first side effect and/or to the second side effect and/or to the third side effect is assigned, at which the predicted friction element temperature (T _pred ) of the friction element the magnitude of the first attendant that occurs is as great as a maximum allowable magnitude of the first attendant, and/or the magnitude of the first attendant that occurs at the predictive friction element temperature (T _pred ) of the friction element is as great as a maximum allowable extent of the second concomitant, and/or in which the magnitude of the third concomitant occurring at the predicted friction element temperature (T _pre d) of the friction element is as great as a maximum allowable magnitude of the third concomitant of the predicted friction element temperature (T _pred ) of the Friction element is, and in which e) the driving speed (v) of the rail vehicle to the specific maximum permissible driving speed (v _max Aiiowed) of the rail vehicle is limited or set.

According to a second aspect, the invention relates to a device for influencing a driving speed of a rail vehicle, which has a friction brake system comprising at least one friction element, the device being designed such that the influencing takes place depending on at least one extent of a first, second or third accompanying phenomenon, which occurs in one in a current driving operation situation of the rail vehicle by the friction braking system would arise, the device comprising at least the following: a) connected to the rail vehicle recording means, which are designed to record at least one parameter which characterizes the current driving operation situation of the rail vehicle, b) a computing unit in which a model, in particular a simulation model, is implemented, c) a control device which is designed to influence the driving speed of the rail vehicle, wherein d) the model executes steps and calculations in such a way that it d1 ) as the first side effect, the braking process performed fictitiously in the current driving operation situation caused brake wear of the at least one friction element, and/or as a second side effect, the brake noise caused by the imaginary braking process in the current driving situation, and/or as a third side effect, the brake smoke or brake smell caused by the imaginary braking process in the current driving situation and that it calculates or estimates a predictive friction element temperature (T _pre d) of the friction element on the basis of the at least one parameter and the braking process that is notionally executed in the current driving situation, and that it d3) calculates or estimates in an association (r) the predicted friction element temperature (T _pre d) of the friction element is assigned a specific maximum permitted driving speed (v _max Aiiowed) of the rail vehicle related to the first accompanying phenomenon and/or to the second accompanying phenomenon and/or to the third accompanying phenomenon, at which the the predicted friction element temperature (T _pre d) of the friction element is as great as a maximum permissible extent of the first accompanying phenomenon, and/or at which the predicted friction element temperature (T _pre d) of the friction element adjusting level of the first side effect is as large as a maximum allowable level of the second side effect, and/or at which the at the predictive Friction element temperature (T _pre d) of the friction element, the extent of the third accompanying phenomenon is as great as a maximum permitted extent of the third accompanying phenomenon of the predicted friction element temperature (T _pred ) of the friction element, and wherein e) the computing unit is designed such that on the basis of the steps and calculations of the model, it generates output signals for the control device, which then, on the basis of the output signals, limits or sets the driving speed of the rail vehicle to the specific maximum permitted driving speed (v _max Aiiowed).

Consequently, only one accompanying phenomenon from the group of the first, second and third accompanying phenomena or also two accompanying phenomena or all three accompanying phenomena can (can) be selected or used in order to determine the specific maximum permitted driving speed v _max Aiiowed. If a number of accompanying phenomena are used, then, for example, the specific maximum permitted driving speed v _max Aiiowed is selected as a permitted maximum driving speed of the rail vehicle, which has the absolute smallest value. The maximum permissible driving speed v _max Aiiowed is then also specific, because it relates to a specific side effect, in this case precisely to the side effect which has the smallest value for the specific maximum permissible driving speed v _max Aiiowed. Alternatively, for example, one of the three specific maximum permissible driving speeds v _maxA n _0W ed could be used as the maximum driving speed of the rail vehicle in sections. A weighting of specific maximum permissible driving speeds v _maxA n _O wed for at least two side effects when determining the maximum driving speed of the rail vehicle is also conceivable.

Therefore, if the driving speed v of the rail vehicle is limited to the specific maximum permitted driving speed v _maxA n _0W ed of the rail vehicle, then this specific maximum permitted driving speed v _max || _0W ed represents a maximum permitted speed of the rail vehicle, which is related to the first concomitant and/or the second concomitant and/or the third concomitant. It is of course possible that that Rail vehicle is operated with a lower driving speed in relation to the specific maximum permitted driving speed v _max Aiiowed.

If the driving speed v of the rail vehicle is set to the specific maximum permitted driving speed v _max Aiiowed, this specific maximum permitted driving speed v _max nowed also represents an optimal speed of the rail vehicle, because the potential described above is then fully utilized.

A rail vehicle is to be understood here as meaning any type of track-bound vehicle with a drive unit, in particular traction vehicles or also without a drive unit such as wagons in rail vehicle formations and a rail vehicle formation made up of a number of rail vehicles.

A model should be understood to mean any mathematical model that can be implemented by a storable program in a computing unit and with the help of which the variables mentioned can be calculated based on the parameters.

In particular, the parameter cannot be a temperature variable. In other words, then, a purpose of the model is to estimate or calculate the predicted friction element temperature T _pre d from the at least one parameter, but the predicted friction element temperature T _pred is preferably not measured by a temperature sensor. Temperature sensors can then advantageously be avoided, the expense of which for assembly, wiring, calibration and implementation is relatively high.

On the other hand, it is also possible that the proportion of the predictive friction element temperature T _pr ed, which only results from the current driving situation, is measured using at least one temperature sensor arranged directly or indirectly on the friction element.

Advantageous developments of the invention specified in the independent claims are presented in the dependent claims.

A development of the method proposes that in the model first values of the current friction element temperature T _act of the friction element be assigned second values of the running speed v _act of the rail vehicle in such a way that a allowed range (T _ac t, Vact) of first values T _ac t and second values _vac t is defined, in which the extent of the first accompanying phenomenon occurring at the predicted friction element temperature of the friction element is at most as great as a maximum allowed extent of the first accompanying phenomenon, and/or in which the extent of the second accompanying phenomenon occurring at the predicted friction element temperature of the friction element is at most as great as a maximum permitted extent of the second accompanying phenomenon, and/or in which the at the predicted friction element temperature of the Friction element adjusting extent of the third side effect is at most as large as a maximum allowable extent of the third side effect. The permitted range (T _ac t, Vact) is delimited by an edge curve r, which defines the association between the specific maximum permitted driving speed v _max Aiiowed and the predicted friction element temperature T _pre d.

In other words, the current temperature T _act of the friction element is determined, measured or estimated. Furthermore, the current speed v _ac t of the vehicle is known. The predictive friction element temperature _Tpred is calculated from the given T _ac t and v _ac t, ie the fictitious target temperature if a defined braking were to be carried out at the current time. However, T _pred must never be greater than T _max ; ideally, T _pred is just below it. How large T _pred can actually be can be read from the boundary curve r. If it is recognized that T _pre d is still well below T _max , it can be concluded that the driving dynamics potential is far from being exhausted, that _vac t can still be increased, namely up to VmaxAiiowed- This VmaxAiiowed is on the edge of edge curve r.

Furthermore, in the method, the imaginary braking process can be carried out with a specific braking effect, a specific braking force or with a specific braking pressure or with a specific braking torque.

In the method, the fictitious braking process can also be carried out with a standardized type of braking, with at least one of the following types of braking being used as the standardized type of braking: emergency braking, emergency braking, emergency braking, emergency braking, service braking in accordance with DIN EN 14478:2005-06. According to a development of the method, at least one of the following parameters can be used as a parameter that characterizes the current driving operation situation of the rail vehicle: the current speed of the rail vehicle, the current braking force, the current braking torque, the current brake pressure, the ambient temperature of the rail vehicle, the current load and/or loading of the rail vehicle, an uphill or downhill gradient on the route traveled by the rail vehicle.

The friction element can in particular contain a brake disc and/or a brake pad of a disc brake of the friction brake system.

Limiting or setting the driving speed of the rail vehicle to the specific maximum permissible driving speed (v _max Aiiowed) can be carried out in particular by an Automatic Train Operation (ATO) or by a train driver (Tf).

According to a further development, in the event that the friction braking system of the rail vehicle comprises a plurality of friction braking devices, the driving speed of the rail vehicle can be influenced using the wheel braking device for which the smallest amount of the specific maximum permissible or permitted driving speed v _max Aiiowed has been determined.

The influencing of the driving speed described above by determining the specific maximum permissible driving speed (v _max Aiiowed) can relate to a local friction braking device, ie for example to a specific disc brake. In a train hierarchy with segment, consist and train levels, the maximum permitted train speeds v _max nowed i determined locally at friction braking devices i can then be consolidated within the train hierarchy. Various methods can be used for consolidation:

- In the simplest case, the absolute smallest specific maximum permitted speed v _maxA n _O wed (determined via all friction braking devices in the train) is used as the maximum permitted driving speed for the entire rail vehicle formation.

There are also various methods for eliminating statistical

outliers available. For example, all determined values VmaxAiiowed i sorted in a series of increasing values and taken from the smallest X percent (where X is a predefined percentage) and then an average or highest value of the smallest X percent.

As already explained above, the parameter that characterizes the current driving operation situation can be at least one of the following parameters: the current speed of the rail vehicle, the current braking force, the current braking torque, the current braking pressure, the ambient temperature of the rail vehicle, the current load and/or or loading of the rail vehicle, an uphill or downhill gradient on the route traveled by the rail vehicle, service or emergency braking with a braking effect that is less than the braking effect for the defined type of braking. This list is not exhaustive. Furthermore, other parameters are conceivable which can characterize a current driving operation situation of a rail vehicle, such as a coefficient of friction between the wheels and the rails.

The at least one friction element of the friction brake system can preferably contain a brake disc and/or a brake pad of a disc brake of the friction brake system.

According to a development of the device, the model can be designed so that first values of the current friction element temperature (T _act ) of the friction element are assigned second values of the running speed (v _ac t) of the rail vehicle in such a way that a permitted range (T _ac t, Vact ) is defined by first values (T _ac t) and second values (v _act ), in which the extent of the first accompanying phenomenon occurring at the current friction element temperature (T _act ) of the friction element is at most as large as a maximum permitted extent of the first accompanying phenomenon, and/or in which the extent of the second accompanying phenomenon occurring at the current friction element temperature (T _ac t) of the friction element is at most as great as a maximum permitted extent of the second accompanying phenomenon, and/or in which the at the current Friction element temperature (T _act ) of the friction element (1) the extent of the third accompanying phenomenon that occurs is at most as great as a maximum permitted extent of the third accompanying phenomenon, the permitted range (T _ac t, Vact) being limited by an edge curve (r). , which the assignment between the specific maximum permitted driving speed (v _max Aiiowed) and the predicted friction element temperature (Tpred) defined.

The control device can preferably be included in the device by an Automatic Train Operation (ATO).

The device can also include first selection means interacting with the model, with which the first and/or the second and/or the third accompanying phenomenon can be selected. In particular, the selection means can further comprise a control panel with which an operator can select the first and/or the second and/or the third concomitant, in which case the model based on the selected concomitant(s) performs the calculations, assignments and steps described above executes

The device can also be designed with the model that the imaginary braking process is carried out with a specific braking effect, a specific braking force or with a specific braking pressure or with a specific braking torque.

Furthermore, the model can be designed in the device so that the fictitious braking process is carried out with a defined type of braking, the model using at least one of the following types of braking as the defined type of braking: emergency braking, emergency braking, emergency braking, emergency braking, service braking.

The model can also be designed in the device so that it uses at least one of the following parameters as a parameter that characterizes the current driving operation situation of the rail vehicle: the current speed of the rail vehicle, the current braking force, the current braking torque, the current brake pressure, the ambient temperature of the rail vehicle, the current load and/or loading of the rail vehicle, an uphill or downhill gradient on the route traveled by the rail vehicle.

The invention also relates to a rail vehicle with a device as described above. Brief description of the drawing

Exemplary embodiments of the invention are shown in the drawing and explained in more detail in the following description. In the drawing shows

1 shows a schematic representation of an exemplary embodiment of a pneumatic friction brake device with a brake disk and a brake caliper with brake pads;

2 shows a functional diagram of an exemplary embodiment of a device according to the invention for an embodiment of the method according to the invention;

3 shows a flow chart of the method according to the invention according to a preferred embodiment;

4 shows a diagram in which an association between a current friction element temperature T _act and the driving speed v as well as a permitted range T for the accompanying phenomenon “brake wear” are shown.

Description of the exemplary embodiments

A section of a friction brake device of a rail vehicle, shown schematically in FIG. 1, shows a pneumatic disk brake. This includes a first friction element 1, which is designed, for example, as a brake disc, which is mounted on an axle of the rail vehicle, not shown, and a brake caliper. The brake caliper has a second friction element 2, which includes two brake pads. Furthermore, the brake caliper has a brake cylinder 4 with compressed air connections 6 and a piston 5 as well as a linkage 3 . The piston 5 actuates the linkage 3, as a result of which the brake pads arranged on the linkage 3, ie the second friction element 2, are pressed against the brake disc, ie the first friction element 1. Compressed air from a compressed air system (not shown) of the rail vehicle is applied to the piston 5 via the compressed air connections 6 in order to actuate the linkage 3 . The compressed air system has components for controlling and regulating the friction brake device, such as compressors, brake control devices, etc.

A preferred embodiment of a device for influencing the driving speed of the rail vehicle, shown in FIG. 2, has a computing unit 7 in which a model is implemented, with which calculations, assignments and steps are carried out in accordance with the method according to the invention.

The device also includes a control unit 8, with which the driving speed v of the rail vehicle is influenced on the basis of the results of the calculations, assignments and steps of the model.

Pressing the first friction element 1 and the second friction element 2 against each other causes a braking effect on the rail vehicle. In this case, the kinetic energy of the rail vehicle is converted into heat, which causes the temperature of the first friction element 1 and the second friction element 2 to rise. A loosening of the first friction element 1 and the second

Friction element 2 from each other causes a reduction or cancellation of the braking effect on the rail vehicle. This, as well as an effect of known heat transfer principles, reduces the temperatures in the first friction element 1 and in the second friction element 2, i.e. the first friction element 1 and the second friction element 2 cool down. The temperature behavior described is calculated or estimated using the method according to the invention.

The device comprises a driving speed sensor 10 for detecting a driving speed v, a brake pressure sensor 11 for detecting a brake pressure p and thus a braking force F _B , an ambient temperature sensor 12 for detecting an ambient temperature Tu, a timer 13 for detecting an absolute time t and a display unit 9 , which are connected to a computing unit 7 via corresponding data lines. The driving speed sensor 10, the brake pressure sensor 11 and the ambient temperature sensor 12 are arranged in a chassis of the rail vehicle, not shown. However, it is also conceivable that the driving speed v and the brake pressure p are read into the processing unit 7 from a data bus system of the rail vehicle. Furthermore, it is also conceivable that the brake pressure p is approximately determined from a deceleration and a mass to be braked. The deceleration is calculated, for example, by differentiating the driving speed v, and the mass m to be braked is determined via a load braking device.

In addition, it is also conceivable that instead of a driving speed v, an angular speed of a wheel or a wheel speed is detected and the thermal calculations are carried out with this angular speed or this wheel speed.

The time measuring device 13 and the computing unit 7 are implemented in a control unit (not shown) and arranged in a car body (not shown). Via corresponding data lines, arithmetic logic unit 7 receives data relating to vehicle speed v from vehicle speed sensor 10, data relating to braking pressure p or braking force F _B from brake pressure sensor 11, data relating to ambient temperature Tu from ambient temperature sensor 12, and data relating to the time from timer 13 Absolute time t (time stamp) and performs arithmetic operations according to the method of the invention. Furthermore, configuration data of the rail vehicle that has been entered into the computing unit 7 can also flow into the computing operations. Here, for example, a current driving operation situation of the rail vehicle is characterized using the driving speed v, the Tu, the ambient temperature Tu, the absolute time t and the configuration data.

According to FIG. 3, to carry out the method according to the invention on the basis of practical tests and/or technical experience, in a preparatory step 100 one or more accompanying phenomenon-specific edge curves T are first created and provided, which limit the range of all pairs of values _{T_ac} t, v_act below the curve profile , for which even with a defined braking from T_ _ac t, v_ _ac t out the friction element temperature increases only to the extent that the new temperature T_ _pred

T_pred ^— T_act + AT still remains below a maximum permissible friction element temperature, which does not allow the associated side effect - for example brake wear - to occur or only to a small, tolerable extent. The shape of the edge curve T depends on the type of concomitant phenomenon and on the defined fictitious type of braking.

In an initial step 200, the current driving operation situation FBS of the rail vehicle is used, which can either be determined currently or which is stored in a retrievable manner. In this exemplary embodiment, the current driving situation is characterized by the following technical parameters: braking pressure p or braking force, driving speed v, surface temperature of the friction element—preferably a brake disk—T_act, ambient temperature Tu, time (stamp) t and various configuration data.

In a subsequent step 300, it is determined which of the disruptive side effects brake wear, brake noise, brake smell or smoke is to be minimized, which also involves a selection of the fictitious type of braking and the associated associated side effect-specific edge curve T. The calculation of the predictive temperature T _pred as a function of the current speed _vac t is already implicitly contained in this edge curve as a pair of values.

In the optional parallel step 400, if the edge curve T is not or not fully specified, a predictive friction element temperature T _pred of the friction element is calculated or estimated or measured on the basis of this input information using a fictitious braking process, which is in or on the Friction element would set if the braking process is performed fictitious in the current driving situation of the rail vehicle. This also results in a pair of values T _pred , v _act related to the assigned speed. The fictitious braking process can be carried out using a simulation model, for example.

In subsequent step 500 it is determined whether the pair of values T _act , v _act is still below the course of the edge curve T or whether the alternatively calculated in step 400 Temperature T _pre d is less than the maximum allowable temperature T _max . If not, the predictive temperature T _pred would exceed the maximum permitted temperature in a fictitious braking. Therefore, in this case, a warning or alarm is issued so that the predicted extent of the disruptive side effect can be reduced manually or automatically by reducing the speed.

In step 600, as a result of the knowledge gained from the fictitious braking process about the predictive friction element temperature T _pre d of the friction element, a specific maximum permitted driving speed v _max Aiiowed of the rail vehicle related to the associated side effect is assigned in an assignment F(T _act ). which the degree of concomitant occurring at the predicted friction element temperature T _pre d of the friction element is as great as a maximum allowable degree of this concomitant of the predicted friction element temperature T _pr ed of the friction element. This step can be viewed as an extension (optimization) of step 500: in step 500 the driver or the automatic driving system is only signaled that or whether the rail vehicle is driving too fast or too slow; in step 600, on the other hand, a specific maximum permissible driving speed is signaled.

This maximum permissible driving speed v _maxA ii _0W ed can be displayed to the driver as an indication of an optimal speed in step 700 and/or can be specified as a control signal in parallel step 800 of a control unit.

The method according to the invention is illustrated in FIG. 4 as an example for the case of the accompanying phenomenon “brake wear”. The boundary curve T is selected in such a way that for each pair of values T _act , v _act below this boundary curve T, i.e. in the shaded area, the value of the brake disc temperature is never greater than that for the wear optimization becomes a critical temperature value T _max . The definition of the boundary curve T depends on device-specific factors, such as material composition and dimensioning of the brake unit, and situation-related requirements, such as temperature safety, even under predefined braking scenarios.

In the exemplary embodiment, optimized value pairs for T _act , v _act lie on the edge of edge curve T. If a value pair _T act , v _act t is below edge curve T, speed v can be increased to a value VmaxAiiowed while maintaining the temperature so that the pair of values T _ac t, VmaxAiiowed lies on the edge of the boundary curve T. v _maxA n _O wed would therefore be used as the maximum allowed speed.

The predictive friction element temperature T _pred can be determined geometrically with this diagram. The actual, current state, which is described by the pair of values Tact, Vact, is a coordinate point in the diagram. Starting from this, T _pre d can be determined as follows:

1 . Form a horizontal straight line, i.e. parallel to the x-axis, through the coordinate point.

2. The parallel line intersects the curve T at an intersection. Depending on the position of the coordinate point, the point of intersection is usually to the right of the coordinate point. If the intersection point is identical to the coordinate point, the intersection point is to the left of the coordinate point.

3. In any case, the temperature rise AT corresponds to the distance from the intersection point to the vertical T= T _max .

4- T _pred ^- T _act ⁺ AT

However, it should be noted that an optimization of the speed v is not desirable or possible in all cases. On the one hand, it may be that a reduction in the side effects has a higher priority than an optimized speed v. For example, it may be more important to drive at a reduced speed v to minimize wear on the brake pads. On the other hand, there are operational framework conditions that Do not allow speed increases, for example driving through residential areas at a reduced speed, entering bus stops at a reduced speed or similar.

However, if the framework conditions allow speed optimization to be permitted and sensible, this method can also be used to compensate for delays in the timetable on suitable routes.

It should also be noted that the method described above as an example for optimizing brake wear can be used analogously - using side effects-specific edge curves r for each of the other side effects mentioned, i.e. also "brake noise" and/or "brake smell" through to "brake smoke". . In addition, several of these methods can be projected simultaneously, and one of the projected methods could then be selected and used depending on the situation.

reference list

1 first friction element

2 second friction element

3 rods

4 brake cylinders

5 pistons

6 compressed air connections

7 unit of account

8 control unit

9 display unit

10 vehicle speed sensor

11 brake pressure sensor

12 ambient temperature sensor

13 Timing device v driving speed

Vgct current driving speed

VmaxAllowed specific maximum allowed driving speed

Tu ambient temperature

P brake pressure

Tact current friction element temperature

Tpred predictive friction element temperature r edge curve

Claims

22 CLAIMS

1 . Method for influencing the driving speed of a rail vehicle, which has a friction brake system comprising at least one friction element (1, 2), characterized in that the influencing takes place depending on at least one extent of a first, and/or second and/or third undesired side effect, which occurs in in a current driving operation situation of the rail vehicle due to the friction brake system, in addition to actual braking, a notional braking process would occur, with method a) at least one parameter being recorded which characterizes the current driving operation situation of the rail vehicle, and in b) as a first side effect the brake wear of the at least one friction element (1, 2) caused in the current driving situation by the fictitious braking process, and/or as a second side effect, the brake noise caused in the current driving situation by the fictitious braking process, and/or as a third side effect, the current driving situation caused by the fictitious braking process is used, and in which a predictive friction element temperature (T _pre d) of the friction element (1, 2) is calculated or estimated, which would occur in or on the friction element (1, 2) if the braking process is fictitious in the current operating situation of the rail vehicle, and d) the predicted friction element temperature (T _pred ) of the friction element (1, 2) is assigned a specific maximum permitted driving speed (v _max Aiiowed) of the rail vehicle, based on at least one of the side effects, in an assignment (r), in which the predicted friction element temperature (T _pre d) of the friction element (1, 2) the extent of the accompanying phenomenon that occurs is as great as a maximum is the permitted extent of this accompanying phenomenon of the predicted friction element temperature (Tp _r ed) of the friction element, and in which e) the running speed (v) of the rail vehicle is set or limited to the specific maximum permitted running speed (v _max Aiiowed) of the rail vehicle, or a relevant signal is issued.

2. The method according to claim 1, characterized in that in the model first values of the current friction element temperature (T _ac t) of the friction element (1) second values of the current driving speed (v _ac t) of the rail vehicle are assigned such that a permitted Area (T _act , v _act ) of first values (T _act ) and second values (v _act ) is defined _in which the extent of the first accompanying phenomenon is at most as large as a maximum permitted extent of the first accompanying phenomenon, and/or in which the extent of the second accompanying phenomenon occurring at the current friction element temperature (T _act ) of the friction element (1, 2) is at most as large as a maximum permitted extent of the second accompanying phenomenon, and/or in which the extent of the third accompanying phenomenon occurring at the current friction element temperature (T _act ) of the friction element (1, 2) is at most as great as a maximum permitted extent of the third accompanying phenomenon, whereby the permitted range (T _act , v _act ) is delimited by an edge curve (r) which defines the relationship between the specific maximum permitted driving speed (VmaxAiiowed) and the predicted friction element temperature (T _pre d).

3. The method according to claim 1 or 2, characterized in that the imaginary braking process is carried out with a specific braking effect, a specific braking force or with a specific braking pressure or with a specific braking torque.

4. The method according to any one of the preceding claims, characterized in that the imaginary braking process is carried out with a defined type of braking. Method according to Claim 4, characterized in that at least one of the following standardized types of braking is used as the defined type of braking: emergency braking, emergency braking, emergency braking, emergency braking, service braking. Method according to one of the preceding claims, characterized in that at least one of the following parameters is used as a parameter which characterizes the current driving operation situation of the rail vehicle: the current speed of the rail vehicle, the current braking force, the current braking torque, the current brake pressure, the ambient temperature of the rail vehicle, the current load and/or loading of the rail vehicle, an uphill or downhill gradient on the route traveled by the rail vehicle. Method according to one of the preceding claims, characterized in that the friction element (1, 2) includes a brake disc and / or a brake pad of a disc brake of the friction brake system. Method according to one of the preceding claims, characterized in that the limitation or setting of the driving speed of the rail vehicle to the specific maximum permitted or optimal driving speed (v _max Aiiowed) is carried out by an Automatic Train Operation (ATO). Device for influencing a driving speed of a rail vehicle, which has a friction brake system comprising at least one friction element (1, 2), characterized in that the influencing takes place depending on at least one extent of at least one accompanying phenomenon, which is caused by the friction brake system in a current driving operation situation of the rail vehicle fictitious braking process would arise, for which purpose the device comprises at least the following: 25 a) recording means (10, 11, 12, 13) connected to the rail vehicle, which are designed to record at least one parameter that characterizes the current driving operation situation of the rail vehicle, b) a computing unit (7), in which a model is implemented , c) a control device, which is designed to influence the driving speed of the rail vehicle, wherein d) the model executes steps and calculations in such a way that it d1 ) as the first side effect, the brake wear of the at least one friction element caused by the braking process that is fictitious in the current driving operation situation (1, 2), and/or as a second side effect, the brake noise caused by the imaginary braking process in the current driving situation, and/or as a third side effect, the brake smell or smoke caused by the fictitious braking process in the current driving situation and that it d2) calculates or estimates a predictive friction element temperature (T _pred ) of the friction element (1, 2) on the basis of the at least one parameter and the braking process that is notionally executed in the current driving situation, and that it d3) calculates or estimates in a Allocation (r) of the predictive friction element temperature (T _pred ) of the friction element is assigned a specific maximum permitted driving speed (v _max Aiiowed) of the rail vehicle related to at least one of the side effects, at which the current friction element temperature (T _ac t) of the Friction element (1, 2) the extent of the respective accompanying phenomenon that occurs is as great as a maximum permitted extent of the accompanying phenomenon of the predicted friction element temperature (T _P red) of the friction element (1, 2), and wherein e) the computing unit is designed, that it generates output signals for the control device on the basis of the steps and calculations of the model, which then, based on the output signals, limits or sets the driving speed of the rail vehicle to the specific maximum permitted driving speed (v _max Aiiowed), or outputs a relevant signal. 26 Device according to Claim 9, characterized in that the model is designed so that it assigns first values of the current friction element temperature (T _ac t) of the friction element (1, 2) to second values of the running speed (v _ac t) of the rail vehicle in such a way that a permitted range (T _ac t, Vact) of first values (T _act ) and second values (v _act ) is defined, in which the extent adjusted at the current friction element temperature (T _act ) of the friction element (1, 2). of the first accompanying phenomenon is at most as large as a maximum permitted extent of the first accompanying phenomenon, and/or in which the extent of the second accompanying phenomenon occurring at the current friction element temperature (T _act ) of the friction element (1, 2) is at most as large as a maximum permitted extent of the second accompanying phenomenon, and/or in which the extent of the third accompanying phenomenon occurring at the current friction element temperature (T _ac t) of the friction element (1, 2) is at most as large as a maximum permitted extent of the third accompanying phenomenon , the permitted range (T _act , v _ac t) being delimited by an edge curve (r), which defines the association between the specific maximum permitted driving speed (v _max Aiiowed) and the predicted friction element temperature (T _pre d). Device according to Claim 9 or 10, characterized in that the control device is included in an Automatic Train Operation (ATO). Device according to one of Claims 9 to 11, characterized in that it comprises first selection means which interact with the model and with which the first and/or the second and/or the third accompanying phenomenon can be selected. Device according to one of Claims 9 to 12, characterized in that the model is designed such that the imaginary braking process is carried out with a specific braking effect, a specific braking force or with a specific braking pressure or with a specific braking torque. 27 Device according to one of claims 9 to 13, characterized in that the model is designed so that the fictitious braking process is carried out with a defined type of braking. Device according to Claim 14, characterized in that the model is designed so that it uses at least one of the following types of braking as the defined type of braking: emergency braking, emergency braking, emergency braking, emergency braking, service braking. Device according to one of Claims 9 to 15, characterized in that the model is designed such that it uses at least one of the following parameters as a parameter which characterizes the current driving operation situation of the rail vehicle: the current speed of the rail vehicle, the current braking force, the current Braking torque, the current brake pressure, the ambient temperature of the rail vehicle, the current load and/or loading of the rail vehicle, an uphill or downhill gradient on the route traveled by the rail vehicle. Rail vehicle with a device according to one of Claims 9 to 16. Computer program with program code means for carrying out the method according to one of Claims 1 to 8 with a computing unit (7) of a device according to one of Claims 9 to 16.