EP3275759A1 - Method for lifting a wheel rail friction coefficient in a rail vehicle - Google Patents

Abstract

The invention relates to a method for increasing a wheel-rail friction coefficient in a rail vehicle, wherein at least one fluid in a device is directed from at least one reservoir through at least one fluid connection to at least one outlet nozzle and in the direction of a wheel-rail pairing the outlet nozzle flows, wherein at least one control unit controls at least an amount of the fluid. In order to increase the wheel-rail coefficient of friction, using an improved friction-increasing material, the fluid adheres to a wheel-rail pair and forms at least one sticky surface.

Description

The invention relates to a method for increasing a wheel-rail friction coefficient in a rail vehicle, a device for carrying out the method and a rail vehicle with the device.

To improve a coefficient of friction between a wheel and a rail in a rail vehicle today sand, usually gravel, is scattered on a rail at a leading wheel set, e.g. on snow, ice, rain, leaves, dirt or similar on the rail. When the wheel passes over the sand or gravel, sand or gravel pieces are ground by the wheel and increase the coefficient of friction between the wheel and the rail.

The system used today with sand has the following principal disadvantages: The sand is heavy. Correspondingly large containers must be carried along on the rail vehicle. A dosage of the sand, a response and a run after a shutdown is possible only with relatively large tolerances. The sand must be well dried or dried further during operation. Pipes for the sand need to be heated. Wheels are only exposed to sand from one side, sanding in case of a change of direction is usually not possible. A filling of a sanding plant is classified as harmful by a dust formation associated with it, so that automatic filling systems are needed. There are incidents in which the rail vehicle comes to a complete standstill on the sand and then remains virtually electrically isolated on rails. In this case, track circuits of a track busy message are no longer shorted and the rail vehicle "disappears" with it for a dispatcher. Such a situation is mitigated by company instructions.

The publication DE 10 2013 016 881 A1 describes a dispensing device for a first Reibwertmodifikator, a second Reibwertmodifikator or a mixture thereof. Each coefficient of friction modifier can be solid, granular, pasty or liquid. The dispensing device is provided for a rail vehicle. The disadvantage here is that solid, granular Reibwertmodifikatoren can cause the same problems as sand or gravel. Pasty or liquid Reibwertmodifikatoren can be displaced in a driving operation of a wheel-rail pairing or drain from a wheel surface or a rail surface.

From the newspaper article "mollusc adhesive for medicine" in the "Hennigsdorfer General Anzeiger" of 25 April 2012, an adhesive material is known, which is obtained from a shell adhesive. The clam adhesive sticks firmly under water on almost any kind of surface and is robust. The component dihydroxyphenylalanine (DOPA), which is an amino acid, contributes to this. From this, adhesives are already being derived which can be used in medicine. A polymer adhesive having DOPA-derived nitrodopamine groups also has the property of decomposing under the irradiation of ultraviolet light. As a result, the shell adhesive is removable again. The clam adhesive is also biocompatible. The disadvantage here is that, apart from an application in medicine, no further field of application has yet been found.

The invention is therefore based on the object to provide a method and an apparatus with which a wheel-rail coefficient of friction is increased, wherein an improved Reibwerterhöhendes material is used.

This object is achieved by a method according to claim 1. Furthermore, the object is achieved with a device according to claim 8. Advantageous embodiments of the invention are contained in the subclaims.

According to the invention, the object is achieved in a method for increasing a wheel-rail coefficient of friction in a rail vehicle, wherein at least one fluid in a device is conducted from at least one storage container through at least one fluid connection to at least one outlet nozzle and in the direction of a wheel rail. Pairing out of the outlet nozzle, wherein at least one control unit controls at least an amount of the fluid. The fluid adheres to a wheel-rail mating and forms at least one sticky surface.

The advantage of the solution according to the invention is that, instead of sand, a novel fluid or a novel Newtonian or non-Newtonian fluid is used to increase the coefficient of friction. This avoids the disadvantages of using sand in a sanding plant. The fluid adheres to a wheel-rail pairing, ie on a wheel and / or a rail, and forms a sticky surface, so that the friction between the wheel and the rail is increased in a rolling of the wheel. The fluid is stored and guided in a device comprising the reservoir, the fluid connection and the outlet nozzle.

In particular, the fluid is liquid-like or paste-like and is sprayed or sprayed in the direction of the wheel-rail pairing. The fluid may thus be a Newtonian liquid or a non-Newtonian liquid and as such better guided and metered than e.g. Sand. A fluid jet can be directed by spraying or spraying targeted to the wheel-rail pairing.

Preferably, after adhering to the wheel-rail mating, the fluid is biodegradable, particularly under the influence of ultraviolet radiation. In this way, residues on the wheel and / or the rail are avoided. In particular, no polluting substances.

In an expedient embodiment of the invention, the fluid comprises an amino acid, e.g. Dihydroxyphenylalanine (DOPA) and / or a related amino acid, e.g. Nitrodopamine, and / or at least one other ingredient of a shell adhesive. This type of amino acid is biodegradable and water resistant and thus well usable even in rainy or humid weather. Nitrodopamine is redeposable under the influence of ultraviolet radiation.

In addition, the fluid may include at least one antifreeze that prevents freezing of the fluid in the device. In this way, the fluid is well usable even in cold weather.

For example, the fluid may include at least one additive that prevents sticking of the fluid in the device and evaporates upon exit of the fluid from the outlet nozzle. Thereby, the reservoir, the fluid line and the outlet nozzle are protected from solidified fluid settling.

In addition, the fluid may have a specific gravity which is smaller than the specific gravity of sand, in particular gravel, and / or the fluid may be harmless to health. It is advantageous if the specific gravity of the fluid is smaller than that of sand, because this can be reduced by a rail vehicle mitzuführendes weight. A health-friendly fluid is advantageous for the maintenance personnel and it can be dispensed with a complex automatic filling of the device.

Furthermore, the solution of the object in an apparatus for performing the method according to the invention, in which the reservoir is fluidly connected via the fluid connection with the outlet nozzle and the control unit is at least one actuator with the fluid connection in operative connection. The outlet nozzle comprises at least one adjusting device, by means of which at least one property of at least one fluid jet is adjustable.

It is advantageous that the fluid jet can be adjusted as needed. The property of the fluid jet can thereby determine a size of a wetted surface on the wheel and / or the rail. As a result, an amount of the required fluid can be optimized.

Preferably, the property of the fluid jet is at least one beam direction, at least one beam strength and / or at least one beam shape. The beam direction and the beam strength can be set more accurately than e.g. when using sand. A beam shape may e.g. be adjusted depending on the viscosity of the fluid.

In a particular embodiment of the invention, at least one hydraulic pump, at least one maintenance unit, at least one check valve and at least one shut-off valve are arranged between the reservoir and the outlet nozzle, the maintenance unit preferably comprising at least one filter, at least one separator and at least one pressure reduction. The components mentioned allow a good handling of the fluid within the device. The filter is for cleaning the fluid and separators for separating e.g. excess water from the fluid. The pressure reduction includes a pressure relief valve, which, despite possibly variable pressures on the inlet side, ensures that a certain outlet pressure is not exceeded on the outlet side.

In a further embodiment, the actuating device is in operative connection with at least one valve device in the fluid connection. The actuating device together with the valve device serves to influence a flow rate or a metering of the fluid and can be actuated automatically or manually by means of the control unit.

In an advantageous development of the invention, at least one first fluid supply line and at least one second fluid supply line are arranged on opposite sides of a wheel in one direction of travel of the rail vehicle, and by means of at least one direction of travel switching, the fluid supply line belonging to the respective current travel direction can be activated. It is advantageous that the wheel-rail pairing can be wetted in both directions of travel of the rail vehicle of the fluid.

According to a particular embodiment, the device has at least one surface structure which comes into contact with the fluid, which prevents sticking of the fluid to the surface structure, wherein the surface structure has, in particular, a lotus effect. The lotus effect refers to the low wettability of a surface, as can be observed in a lotus plant surface, which has a special surface structure. Accordingly, liquids emit surface structures that are technical imitations of the natural surface structures of the lotus plant. Low wettability surface structures are also referred to as hydrophobic surfaces. It is important that sticking of the fluid to the surface structure in the device be prevented because it can prevent blockages and / or constrictions in the device.

Suitably, the device can be heated and / or cooled. As a result, the device can be operated both in cold and in warm ambient temperatures.

Also claimed is a rail vehicle with the device according to the invention.

In the following an embodiment of the invention will be explained in more detail with reference to a single figure.

The figure shows a schematic structure of a device according to the invention.

In the single figure, the device 1 according to the invention and two wheels 2 of a rail vehicle otherwise not shown are shown. The wheels 2 move on a rail or running rail 3.

The device 1 comprises fluid power components which are arranged in a predetermined sequence along a fluid connection or a fluid line 5. The fluid connection may comprise at least one tube and / or at least one tube. The fluid connection 5 starts at a reservoir 4 for the fluid and continues to a hydraulic pump 6 adapted to the fluid. In the further course of the fluid connection 5, a maintenance unit 7 with a filter 7a, a separator 7b and a pressure reduction 7c is arranged. Behind the maintenance unit 7, the fluid connection 5 leads to a check valve 9 and subsequently to a shut-off valve 10. Between the maintenance unit 7 and the check valve 9, a control unit 8 is arranged with an actuating device 8a. The control unit 8 is connected to the actuator 8a via a control line 8b. The actuator 8a is connected to a valve device 8c in the fluid connection 5.

The fluid connection 5 further connects the shut-off valve 10 with a direction of travel switching 11, which divides the fluid connection 5 into a first fluid supply line 11a and a second fluid supply line 11b. The first fluid supply line 11a leads to the wheels 2 and the rail 3 and is opposite to a first direction of travel x1 of the rail vehicle. The second fluid supply line 11 b leads to the wheels 2 and the rail 3 and is opposite to a second direction of travel x2 of the rail vehicle.

According to the figure, the first fluid supply line 11a and the second fluid supply line 11b each have a branch for two wheels 2, but may also have branches for more than two wheels 2. Alternatively, the first fluid supply line 11a and the second fluid supply line 11b may each be provided unbranched and in each case only for one wheel 2. At each end of a first fluid supply line 11a and a second fluid supply line 11b, an outlet nozzle 12 is arranged. The outlet nozzle 12 comprises an adjusting device, not shown in the figure, for a fluid jet emerging from the outlet nozzle and not shown in the figure.

In operation, the fluid is stored in the reservoir 4 and pumped out by means of the hydraulic pump 6 from the reservoir 4. In the maintenance unit 7, the fluid is removed from the impurities by means of the filter 7a. In the separator 7b, for example, excess water is separated from the fluid. The pressure reduction 7c comprises a pressure valve which, despite possibly variable pressures on the inlet side of the pressure valve, ensures that a certain outlet pressure is not exceeded on the outlet side of the pressure valve.

The control unit 8 controls the actuator 8a via a control line 8b in response to predetermined parameters, e.g. a sliding of a wheel 2 on the rail 3. The actuator 8a can also be operated manually. The actuator 8a actuates the valve means 8c for adjusting the flow rate of the fluid in the fluid connection.

The check valve 9 prevents backflow of the fluid in the fluid connection 5. By means of the stopcock 10, the fluid connection 5 can be shut off, e.g. when the rail vehicle is not in operation.

The direction of travel switching 11 allows operation of the device 1 in a first direction of travel x1 and a second direction of travel x2 of the rail vehicle. When the rail vehicle is operated in the direction of travel x1, the first fluid supply line 11a is opened and the second fluid supply line 11b is blocked. As a result, the fluid is directed counter to the first direction of travel x1 to the wheels 2 or the rail 3, wherein the wheels roll in the first direction of travel x1. When the rail vehicle is operated in the direction of travel x2, the second fluid supply line 11b is opened and the first fluid supply line 11a is blocked. As a result, the fluid is directed counter to the second direction of travel x2 to the wheels 2 or the rail 3, wherein the wheels 2 roll in the second direction of travel x2.

Alternatively, the direction of travel switching 10 can be omitted. Instead, for the first direction of travel x1 and the second direction of travel x2 each have their own device 1 may be present.

At each outlet nozzle 12, the fluid jet is adjusted by means of the adjusting device. If the fluid is a Newtonian liquid, it can be sprayed or sprayed. If the fluid is a non-Newtonian fluid, it can be injected. A beam direction, a beam strength and a beam shape can be set. The adjustment takes place as a function of the viscosity of the fluid. The higher the viscosity of the fluid, the greater the required radiant intensity. For example, the beam direction may be more in the direction of the rail 3 than in the direction of the wheel 2. Conversely, the beam direction can also be stronger in the direction of the wheel 2 than in the direction of the rail 3. The beam direction can also be directed centrally on the space between the wheel 2 and the rail 3. The beam shape can be cone-shaped, wherein an opening angle of a fluid cone can be adjusted. When the fluid jet is concentrated, ie, has a cylindrical shape, a smaller area is wetted than when the fluid jet is fan-shaped. The fluid jet may comprise any number of sub-beams.

The fluid adheres to the wheel 2 and / or on the rail 3 and forms a sticky surface. As a result, a coefficient of friction between the wheel 2 and the rail 3 is increased. Slipping or sliding of the wheel 2 on the rail 3 is avoided. As a result, the wear on the wheel 2 and on the rail 3 is reduced and increases the reliability. The fluid can include dihydroxyphenylalanine (DOPA), an amino acid that can be derived from a natural mussel adhesive. The fluid may also include polymers comprising dihydroxyphenylalanine (DOPA) or related groups, eg, nitrodopamine groups.

LIST OF REFERENCE NUMBERS

1

contraption

2

wheel

3

rail

4

reservoir

5

fluid communication

6

hydraulic pump

7

maintenance unit

7a

filter

7b

separators

7c

pressure reduction

8th

control unit

8a

actuator

8b

control line

8c

valve means

9

check valve

10

stopcock

11

Mounted unit

11a

First fluid supply line

11 b

Second fluid supply line

12

outlet nozzle

x1

First direction of travel

x2

Second direction

Claims (15)

A method for increasing a wheel-rail friction coefficient in a rail vehicle, wherein at least one fluid in a device (1) from at least one reservoir (4) is passed through at least one fluid connection (5) to at least one outlet nozzle (12) and in the direction of Wheel-rail pairing (2, 3) flows out of the outlet nozzle (12), wherein at least one control unit (8) controls at least an amount of the fluid, characterized in that the fluid at a wheel-rail pairing (2, 3) adheres and forms at least one sticky surface. A method according to claim 1, characterized in that the fluid is liquid-like or paste-like and in the direction of the wheel-rail pairing (2, 3) is sprayed or sprayed. A method according to claim 1 or 2, characterized in that the fluid is biodegradable after adhering to the wheel-rail pairing (2, 3), in particular under the influence of ultraviolet radiation. Method according to one of claims 1 to 3, characterized in that the fluid comprises an amino acid, for example dihydroxyphenylalanine (DOPA) and / or an amino acid related thereto, for example nitrodopamine, and / or at least one further constituent of a mussel adhesive. Method according to one of claims 1 to 4, characterized in that the fluid comprises at least one antifreeze, which prevents freezing of the fluid in the device. Method according to one of claims 1 to 5, characterized in that the fluid comprises at least one additive which prevents sticking of the fluid in the device and evaporates upon leakage of the fluid from the outlet nozzle. Method according to one of claims 1 to 6, characterized in that the fluid has a specific gravity which is smaller than the specific gravity of sand, in particular gravel, and / or that the fluid is harmless to health. Device (1) for performing a method according to any one of claims 1 to 7, wherein the reservoir (4) via the fluid connection (5) is fluidly connected to the outlet nozzle (12) and the control unit (8) via at least one actuating device (8a ) is in operative connection with the fluid connection (5), characterized in that the outlet nozzle (12) comprises at least one adjusting device by means of which at least one property of at least one fluid jet is adjustable. Device (1) according to claim 8, characterized in that the property of the fluid jet comprises at least one beam direction, at least one beam strength and / or at least one beam shape. Device (1) according to claim 8 or 9, characterized in that between the reservoir (4) and the outlet nozzle (12) at least one hydraulic pump (6), at least one maintenance unit (7), at least one check valve (9) and at least one stopcock (10) are arranged, wherein the maintenance unit (7) preferably at least one filter (7a), at least one separator (7b) and / or at least one pressure reduction (7c). Device according to one of claims 8 to 10, characterized in that the actuating device (8a) is in operative connection with at least one valve device (8c) in the fluid connection (5). Device (1) according to one of claims 8 to 11, characterized in that at least one fluid supply line (11a) and at least one second fluid supply line (11b) in a direction of travel (x1, x2) of the rail vehicle on opposite sides of a wheel (2) are arranged and by means of at least one change of direction of travel (11) belonging to the respective current direction of travel (x1, x2) fluid supply line (11a, 11 b) can be activated. Device (1) according to one of claims 8 to 12, characterized in that the device (1) has at least one coming into contact with the fluid surface structure, which prevents sticking of the fluid to the surface structure, wherein the surface structure in particular a lotus effect having. Device (1) according to one of claims 8 to 13, characterized in that the device (1) can be heated and / or cooled. Rail vehicle with a device (1) according to one of claims 8 to 14.

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