EP3789264A1 - Method and device for slip detection and rail vehicle - Google Patents

Abstract

A method for detecting slip in a wheelset (7, 8) for a rail vehicle (1) comprises acquiring a plurality of measurement signals from a first and second speed sensor (5, 6) and determining a respective speed value for the first and second wheelsets (7, 7). 8) as a function of a respective measurement signal from the associated speed sensor (5, 6). The method further comprises forming speed value pairs each with a determined speed value for the first and second wheel sets (7, 8) and comparing the respective speed values and determining a correction factor for several speed value pairs as a function of the comparison. The method further comprises determining speed deviations as a function of the determined correction factor and determining a slip of the first and / or second wheel set (7, 8) as a function of the determined speed deviations.

Description

The invention relates to a method for determining a correction value with the simultaneous exclusion of slip events on one or more axles of a ground-based vehicle. The invention also relates to a device for carrying out such a method and a ground-based vehicle with such a device.

Rail vehicles are ground-based vehicles for which a vehicle speed and a path that can be derived from it must be precisely and reliably determined in manual or automatic driving mode. As a rule, speed sensors or travel incremental encoders are used, which are assigned to a wheel or wheel set of the rail vehicle in the case of the latter. Such sensors cannot, however, directly detect a skidding or sliding of a wheel, so that the wheel can turn faster or turn slower than the rail vehicle is actually traveling. Thus, a speed measured by means of the sensors may not correspond to a current vehicle speed of the rail vehicle. The term "correction factor" is also used synonymously below as the correction value.

One object of the present invention is to create a method for slip detection in a wheel set for a rail vehicle, which enables a vehicle speed of a rail vehicle to be reliably and precisely determined and which can help to keep delays in the operation of the rail vehicle low.

The object is achieved by a method for slip detection with simultaneous calculation of correction values for various axles for a ground-based vehicle, here a rail vehicle according to the independent patent claim. Beneficial Refinements of the method are given in the dependent claims.

According to one aspect of the invention, a method for slip detection in a wheel set for a rail vehicle, to which a first wheel set with a first speed sensor and a second wheel set with a second speed sensor are assigned, comprises detecting a plurality of measurement signals from the first and second speed sensors, which are each representative of a speed of the first and the second wheel set of the rail vehicle. The method further comprises determining a respective speed value for the first and for the second wheel set as a function of a respective measurement signal from the first or the second speed sensor. The method further comprises the formation of speed value pairs, each with a determined speed value for the first and the second wheel set. The method further comprises comparing the respective speed values for the first and second wheel sets of a formed speed value pair with one another and determining a uniform correction factor for all determined speed value pairs as a function of the comparison. The method further comprises determining speed deviations based on the uniformly valid correction factor and determining slip of the first and / or second wheel set as a function of the speed deviations. When used several times, the method also includes determining a plurality of correction factor deviations as a function of the determined correction factors and determining a slip of the first and / or second gear set based on the determined correction factor deviations.

By means of the method described, a reliable detection of sliding or skidding of a wheel set is possible and it can contribute to an accurate determination of the vehicle speed. The procedure enables a robust relative scale determination or correction factor determination with reliable slip and skid exclusion. Such a correction factor determination takes into account the determined correction factors of various route sections and the speed deviations that arise in the process. In this way, slip areas in the form of outliers based on the calculated speed deviations and correction factors can be reliably identified. The correction factors and correction factor deviations make it possible to determine speed deviations of a wheel set in order to obtain equality with regard to the speed of the wheel sets when using the correction factor.

According to a preferred development, the method includes controlling a vehicle speed of the rail vehicle as a function of the determined slip of the first and / or second wheel set. Controlling the vehicle speed of the rail vehicle can in particular include providing a safety surcharge for a permissible vehicle speed of the rail vehicle as a function of the determined slip, so that the vehicle speed of the rail vehicle is also controlled as a function of the provided safety surcharge.

• Ungenaue Messung des Raddurchmessers
• Abnutzung während der Fahrt
• Änderung des Reifeninnendrucks, zum Beispiel bei Gummibereifung
• Beladung, vornehmlich bei Gummibereifung.

For ground-based vehicles, such as rail vehicles, it is necessary both in manual and in automatic driving mode to precisely and reliably determine the vehicle speed and the route that can be derived from it. This can be achieved, for example, with the use of path incremental encoders that are assigned to a respective wheel or wheel set of a rail vehicle. It is a finding in connection with the present invention that even by means of such sensors, sliding or skidding of a wheel set is not always reliably detected. The wheel of the wheel set can, for example, turn faster than the rail vehicle is actually moving (skidding) or it turns slower than the rail vehicle travels (gliding). In the case of path incremental encoders, conclusions are usually drawn about the path covered or the speed of the wheel and the rail vehicle with the aid of the diameter and the circumference of the wheel derived from it. If the wheel diameter of a wheel changes, the wheel and vehicle speed calculated from the wheel revolutions change. Causes for the incorrect or inaccurate wheel diameter determination are, for example:

• Inaccurate measurement of the wheel diameter
• Wear while driving
• Change in tire pressure, for example with rubber tires
• Loading, primarily with rubber tires.

If a speed determination changes, for example due to a faulty or imprecise wheel diameter, speed differences are caused between different travel incremental encoders. Such differences can be mistakenly interpreted as sliding or skidding and treated as allegedly adjacent slip. Assuming that there is a slip, predetermined safety surcharges for speed intervals are increased, since an actual vehicle speed can be estimated more poorly. This is the reason for an incorrectly safety-related reduction in the vehicle speed, so that the rail vehicle now travels more slowly and considerable delays can be caused.

For a reliable determination of the vehicle speed and safe operation of the rail vehicle, it is therefore advantageous to reliably detect any slip (sliding or skidding) of the wheel or wheel set and to allow it to flow into a control of the vehicle speed. Reliable slip detection can be carried out by means of the method described, so that delays in a rail vehicle are counteracted and closed can contribute to the scheduled and punctual operation of the rail vehicle.

According to a further development, the method includes discarding one of the determined correction factors as a function of the determined speed deviations per correction factor or correction factor deviation between correction factors, and controlling a vehicle speed of the rail vehicle as a function of the remaining correction factors. The determined speed deviations of the calculated correction factors as well as the correction factor deviations make it possible to precisely identify the phases and time ranges in which a wheel slips.

For example, there is a speed difference between the two wheel sets that would justify a correction factor of about 1.1. If a correction factor of, for example, 4 is determined for a short time, this correction factor deviates significantly from the others and can be determined as a slip. A uniform correction factor, for example 2.55, is determined for the detection and any gaps or deviations in the individual correction factors per difference are shifted into respective speed deviations. The further the deviation from the uniformly calculated correction value, the greater the speed deviations. The successively calculated correction factors for route sections and / or the speed deviations accordingly have a clear peak, which enables reliable slip detection. If the correction factors described were now averaged, this would cause an unjustified adjustment of the vehicle speed. A safety margin would be incorrectly applied to the vehicle speed.

Using the method described, such outliers caused by slippage can be reliably identified and assessed appropriately. Because, for example, such a If the value of the correction factor is discarded, it is no longer included in the evaluation and the vehicle speed of the rail vehicle and a safety surcharge can be specifically coordinated.

According to a preferred development of the method or one of the described developments of the method, the determination of the correction factor comprises a regression analysis. Statistical analysis methods can be used with the aim of achieving the best possible averaging of the specific correction factors, for example by minimizing the speed deviations that occur as a result. Such a regression analysis and adjustment calculation can, for example, be based on the method of least squares.

According to a development of the method or one of the described developments of the method, the method comprises specifying a deviation threshold value for a tolerable speed deviation and comparing the determined speed deviations with the predefined deviation threshold value. The method accordingly further comprises determining a slip of the first and / or second wheel set as a function of the comparison of the determined speed deviations with the predefined deviation threshold value. In particular, a slip range can thus be identified on the basis of a tolerable speed deviation in the form of a deviation threshold value which should not be exceeded during operation.

According to a development of the method or one of the described developments of the method, the first and the second speed sensor each have a path incremental encoder. Accordingly, determining a respective speed value for the first and for the second wheel set comprises providing circumferential values for a wheel of the first wheel set and a wheel of the second wheel set, which one of the incremental encoders is assigned to each. The method further comprises detecting a number of revolutions of the respective wheel of the first gear set and the second gear set and determining a respective speed value for the first gear set and for the second gear set as a function of the respective provided circumferential values and the respective detected number of revolutions.

According to a further development of the method or one of the described further developments of the method, determining a slip of the first and / or second wheel set as a function of the determined speed deviations includes detecting areas of the first and / or second wheel set that are influenced by and not influenced by slip depending on the correction factors determined and / or the determined speed deviations. The control of a vehicle speed of the rail vehicle then also takes place as a function of the identified areas of the first and / or second wheel set that are influenced by and are not influenced by slip.

According to a development of the method or one of the described developments of the method, the method includes forming an arithmetic mean of the correction factors determined. A vehicle speed of the rail vehicle is accordingly also controlled as a function of the arithmetic mean of the correction factors that is formed. In particular, the identified slip areas are not included in the formation of the arithmetic mean, so that a falsification of the averaging is counteracted. Alternatively, another averaging method or another value formation method can also be used for a summarizing correction factor, so that, for example, a weighting of the correction factors is also taken into account.

The arithmetic mean of the correction factors can also be stored for a subsequent travel cycle of the rail vehicle. Controlling a vehicle speed of the rail vehicle then takes place, for example, as a function of the stored arithmetic mean of the correction factors and is loaded, for example, when starting operation and directly included in the control of the vehicle speed.

The described method and the described developments of the method enable reliable and precise slip detection on a finely granular level. No additional sensors are required and there is no need for generous safety surcharges, which are included in advance in the speed and path calculation due to a possible occurrence of slip in order to counteract the corresponding sliding or skidding processes. There are therefore no general safety surcharges to be assumed and this can contribute to increased accuracy in determining the vehicle speed of the rail vehicle.

For example, the method only requires two path incremental encoders, which are mounted on axles of the rail vehicle that are not mechanically coupled. With the help of only two travel incremental encoders, the vehicle speed and the route for the rail vehicle are determined. For example, data relating to wheel circumferences are provided. However, since the wheel circumferences are only known to a limited extent, the raw data for the calculated speeds of the first and second wheelset recorded by means of the measurement signals of the path incremental encoders deviate from the real vehicle speeds of the rail vehicle. These speed deviations can be accepted up to a given size.

However, these deviations may be too large for reliable slip detection and are determined and then calculated. A particularly precise and reliable slip detection can then take place. The detection of slip makes it possible, in particular, to detect slip-influenced Separate areas that are not affected by slippage. In areas that are not influenced by slip, general safety surcharges in relation to the vehicle speed for a possible occurrence of slip which conventionally could not be determined or could not be determined with sufficient accuracy can be reduced considerably. Rail vehicles such as trains can then run punctually according to the timetable or at least undesired delays in a train operation can be reduced.

The described method and the developments enable a high level of applicability regardless of a vehicle type of a rail vehicle and a route that is traveled by it. The method implements a generic approach and does not require any information about the route, such as longitudinal inclination. Also, no information about a current acceleration or braking process is required.

The method described and the developments also provide a high level of acceptance by a user, since no interaction on the part of the user is necessary. The method can in particular be carried out in an automated manner. In addition, a gain in performance for adherence to a timetable can be achieved due to reducible delays and higher route utilization. In addition, the method provides a clear approach which can contribute to the maintenance-friendly operation of a rail vehicle.

In addition, the method can be carried out inexpensively. Existing path incremental encoders can be used to carry out the method and the method can be combined with other approaches for the detection of systematic deviations, such as sliding and slipping processes in path incremental encoders. With regard to the large number of rail vehicles used, significant cost savings can be made possible. In addition, the process is relatively future-proof, as there are few or no returns are to be expected. With returns, among other things, customer-side complaints and manufacturer-side improvements are referred to.

The method described contributes in particular to improved accuracy with regard to sliding and skid detection and meets high accuracy requirements with regard to determining the vehicle speed. It enables the evaluation of highly redundant information through adjustment and statistical tests, among other things with the aim of calculating a correction factor with high accuracy and then automatically detecting systematic errors in order to be able to exclude them so that they do not flow into the final correction factor determination. Furthermore, by means of the method described, a flexible target of accuracy with regard to the scale and thus also the speed is possible.

Another aspect of the invention relates to a device for slip detection in a wheel set for a rail vehicle, which device is set up to carry out one of the methods described above. The device is implemented, for example, as an on-board computer or control unit of the rail vehicle, which has a computing unit and a data memory and enables the recorded measurement signals and the determined speed values to be evaluated and processed. Alternatively or additionally, such a device is implemented as a backend or external server unit that can communicate with the rail vehicle using signals.

According to a further aspect of the invention, a rail vehicle comprises a first set of wheels and a second set of wheels, which are mechanically decoupled from one another. The wheel sets are coupled via one or more car bodies of the rail vehicle, but there is no direct mechanical coupling between the wheel sets, for example by means of a gearbox. The rail vehicle further comprises a first speed sensor and a second speed sensor, the one are assigned to the respective wheelset. The speed sensors each have a travel incremental encoder and the measurement signals from the speed sensors are each representative of a speed of the first wheel set and the second wheel set. Furthermore, the rail vehicle has the device described above, which is coupled to the speed sensors for signaling purposes.

Because the device and the rail vehicle are set up to carry out one of the methods described above, the described properties and features of the method are also disclosed for the device and for the rail vehicle, and vice versa.

Figur 1

eine schematische Darstellung eines Schienenfahrzeugs mit einer Vorrichtung zur Schlupferkennung für mindestens ein Radsatz des Schienenfahrzeugs,

Figur 2

ein Ablaufdiagramm für ein Verfahren zur Schlupferkennung für mindestens ein Radsatz des Schienenfahrzeugs,

Figur 3

ein weiteres Ablaufdiagramm für ein Verfahren zur Schlupferkennung für mindestens ein Radsatz des Schienenfahrzeugs, und

Figur 4

beispielhafte algorithmische Zusammenhänge zum Verarbeiten bei der Durchführung des Verfahrens zur Schlupferkennung.

The above-mentioned properties, features and advantages of the invention and the manner in which they are achieved are explained in more detail by the following description of the exemplary embodiments of the invention in conjunction with the corresponding figures. Show it:

Figure 1

a schematic representation of a rail vehicle with a device for slip detection for at least one wheelset of the rail vehicle,

Figure 2

a flowchart for a method for slip detection for at least one wheelset of the rail vehicle,

Figure 3

a further flowchart for a method for slip detection for at least one wheelset of the rail vehicle, and

Figure 4

exemplary algorithmic relationships for processing when carrying out the method for slip detection.

Figure 1 shows a schematic side view of a rail vehicle 1 with a control unit 3, which is signal-coupled to a first speed sensor 5 and a second speed sensor 6. The speed sensors 5 and 6 are travel incremental encoders for the wheelsets 7 and 8. The wheelsets 7 and 8 have respective wheels and axles that are not mechanically coupled directly to one another. The speed sensors 5 and 6 enable the acquisition of measurement signals that are each representative of a speed of the first wheel set 7 and the second wheel set 8 of the rail vehicle 1. As will be explained below, the path incremental encoders mounted on the axles can usefully be used to generate a to enable reliable and precise detection of sliding and skidding of the wheels of the first and / or second wheel set 7 and 8.

A method for slip detection in one of the wheel sets 7, 8 for the rail vehicle 1 can be carried out according to the method shown in FIG Figure 2 or the in Figure 3 flowchart shown in the control unit 3 can be performed. In a step S1, a plurality of measurement signals from the first speed sensor 5 and the second speed sensor 6 are recorded.

In a step S2, a respective speed value for the first wheel set 7 is determined as a function of a respective measurement signal from the first speed sensor 5 and a respective speed value for the second wheel set 8 is determined as a function of a respective measurement signal from the second speed sensor 6. Furthermore, speed value pairs are formed, each with a determined speed value for the first and the second wheel set 7, 8. If a predetermined number of usable speed value pairs has been determined or formed, the method is continued in a step S3. For example, a measurement signal from the first and second speed sensors 5 and 6 is recorded every half second for a period of one minute, so that 120 speed value pairs are formed.

In step S3, the respective speed values for the first and second wheelsets 7, 8 of a respective speed value pair formed are compared with one another and a correction factor is determined for all speed value pairs as a function of the comparison.

In a step S4, speed deviations are determined as a function of the determined correction factor. In particular, a statistical model can be used for the evaluation. In particular, a regression analysis or a compensation calculation takes place in step S4, which is based, for example, on the method of least squares, which carries out a minimization method with regard to the smallest possible deviation of the determined speed deviations with regard to a correction factor for all value pairs.

For example, the following mathematical relationships can be formulated for each determined speed pair: v_messessen_Sensor1_i = correction factor * v_messessen_Sensor2_i. The mathematical value "correction factor" is only available once and this is automatically set by the minimization method. For "v_gemessen_Sensor1_i", deviations "v_gemessen_Sensor1_Deversion_i" of the type v_gemessen_Sensor1_i + v_gemessen_Sensorl_Abnehmerung_i = correction factor * v_messessen _Sensor2_i are determined such that the sum of the squares of these deviations is minimal.

In step S5, a slip of the first and / or second wheel set 7, 8 is determined as a function of the determined deviations for the measured speeds with respect to a calculated correction factor and the vehicle speed of the rail vehicle 1 is determined as a function of the detected slip, taking into account the previously calculated correction factor controlled.

The method for slip detection can also take place in accordance with the flow diagram illustrated in FIG. 3, which shows the variable relationships in accordance with Figure 4 includes. In a step S1 it is checked whether the default conditions for the variables to be processed are met. If this is not the case, the method is continued in a step S2. If the default conditions are met, the method is continued in step S3.

In step S3, measurement signals from the path incremental encoders are recorded and speed values are determined for the respective axles or wheel sets 7 and 8. Furthermore, speed value pairs are formed which each contain a speed value for the first and the second wheel set. If a predetermined number of evaluable speed value pairs has been formed, the method is continued in a step S5. Otherwise, the method is ended or started again in step S1.

In step S5, a k _{PSSA section} factor is determined or adapted. The k _{PSSA section} factor represents a correction factor that is calculated for all pairs of measured values, for example 120 pairs of measured values, which form a section, by minimizing the speed deviations with respect to a sensor. In particular, the following relationships apply: v_messessen_Sensor1_i + v_gemessen_Sensor1_Aberstoffung_i = correction factor * v_messessen _Sensor2_i, where "i" runs from 1 to 120, for example. The correction factor k _{PSSA section} factor is estimated or calculated by the adjustment. The acronym "PSSA" refers to the English term "pseudo static scale adjustment" and can be referred to in German as pseudo-static scale adjustment.

In a step S7, the mathematical and stochastic model on which the adjustment is based is checked. The mathematical model includes the assumption that there is only one scale factor k _PSSA-Section for, for example, all 120 speed pairs, and the stochastic model includes that Assumption of the accuracy of the measured speeds. Furthermore, the accuracy of the correction factor calculated from the previous step S5 is compared with a predetermined threshold value. If a desired accuracy is fulfilled and the assumptions in the mathematical and stochastic model are not refuted, the method can be continued in a step S9. If a desired accuracy is not met and / or the assumptions of the model tests are refuted, the method is continued in a step S8.

In step S8, the current data and determined speed values are discarded. The method is ended and, when new speed values arrive, it is started again in step S1.

In step S9, it is checked whether kfactorsInSeries are available. For example, kfactorsInSeries has the value 3. If corresponding correction factors that are valid 3 times have been calculated in a row, the method is continued in a step S11. Otherwise, the correction factor k _{PSSA-Section is} stored, the method is ended and then restarted in step S1 when new measured values arrive.

The variables kfactorsInSeries represent a number of the successively calculated and valid correction factors. A correction factor is calculated from, for example, 120 pairs of values. It is possible that a valid correction factor was calculated in the first minute and none in the following minute. Then there is a valid correction factor. But you need 3 to progress in the process. In the third minute, for example, a valid one is calculated. If there are 3 it continues.

In step S11, all possible combinations of two of the determined k _{PSSA section} factors are set up. With three k _{PSSA section} factors there are 3 combinations of two: 12, 13 and 23.

With a value of 4 for the kfactorsInSeries it would be the combinations: 12, 13, 14, 23, 24 and 34.

In a step S13 it is checked whether the calculated correction factors of the respective combinations are the same in the sense of agreeing within tolerable deviations. This includes the comparison of the determined correction factors. If the correction factors match within a predefined tolerance range, the method is continued in a step S15. Otherwise, the method is ended and started again in step S1. Each combination includes two different correction factors that are compared with one another. With a value of 3 for the kfactorsInSeries, there are 3 independently calculated correction factors, which can be created within 3 minutes or extend over a longer period of time, for example 148 minutes.

In step S15, an arithmetic mean is calculated and the k _PSSA factor is provided for a real-time method for slip and skid exclusion. The k _PSSA factor is the arithmetic mean of the k _{PSSA section} factors. With a value for the kfactorsInSeries of 3, there are exactly 3 pieces.

The method described relates to a quasi-static scaling adjustment and is preferably used in connection with a method for sliding and skidding exclusion. The control unit 3 implements a processing unit which enables the distance incremental encoder to be scaled to a referencing distance incremental encoder. When carrying out the method described, in particular the in Figure 4 The illustrated algorithmic relationships between various variables are taken into account in the slip detection as follows:
The first, topmost graph according to Figure 4 shows the vehicle speed of the rail vehicle 1 over time according to the measurement signals of the first and second path incremental encoder. One the two position incremental encoders act as reference incremental encoders.

The second graph according to Figure 4 shows an associated time representation of the calculated k _{PSSA section} factors. The illustration indicates that only speed value pairs are taken into account for further processing which have a value that is greater than a predefined threshold value v _{PSSA limit} . The v _{PSSA limit} is a threshold value. In particular, pairs of measured values are only formed if both measured speeds are above this value. One background for such a beneficial procedure is of an error-related nature. A correction factor can be calculated with high accuracy if the vehicle is moving fast enough. If the 120 pairs of measured values of a section were also to be filled at low speeds, the target accuracy for k _PSSA factor in step S7 may not be achieved under certain circumstances.

The third graph shows whether the k _PSSA factors of the combinations are equal (point below the top line) or not equal (point above the top line). Each point stands for a combination. The lower dashes or lines in the lower area of the third graph indicate whether the k _PSSA factor is generally valid, see S7, in order to be able to be used for the formation of the combination. If there is no line in the area, this means that the corresponding factor should not be processed any further. The lower line or the lower line is derived from the further graphs, the fourth and fifth graphs, the Figure 4 from. If there are lines below the solid line, a corresponding lower line is drawn in the third graph.

The fourth graph shows the statistically determined deviation according to a statistical test based on the results of the least squares method (χ ² test). A check for each area is fulfilled when the specified limit or the specified deviation threshold value (visualized by a solid line) is not exceeded by the determined values (illustrated as individual line sections).

The fifth graph in FIG. 5, counted from above, shows the accuracy of the k _{PSSA section} factors for each area. A corresponding requirement is met if the accuracy of the k _{PSSA section} factor (individual line sections ) does not exceed a specified accuracy limit for the k _{PSSA section} factor according to the illustrated variable σ _{kPSSAsection limit} (solid line).

The sixth graph shows that the k _{PSSA section} factor deviates significantly from zero. The k _{PSSA section} factor corresponds to the correction factor described above.

In particular, the relationships shown in the third graph are relevant for the method described. The line sections shown below the points show the range of the k _{PSSA section} factors that meet the mathematical stochastic model analysis and a specified accuracy. These k _{PSSA section} factors are used to compare the correction factors. Outliers are discarded and not taken into account.

If the k _{PSSA section} factors in the possible combinations formed from factors calculated by kfactorsInSeries are statistically the same, the points associated with the k _{PSSA section} factors are arranged in the third graph below the upper solid line. The areas used for this comparison are the line _segments shown below the points that are to be assigned to the k factorsInSeries.

The k _{PSSA section} factors are the correction factors; In principle, correction factor deviations are only calculated for non-linear problems in order to iteratively arrive at the correct correction factor. In the present case, however, it is a linear problem, see equation, where the correction factor is is calculated directly. In this calculation, the deviations arise in the measured speeds of a sensor, because there may only be one correction factor for 120 value pairs, for example. These deviations are taken in order to conclude that slip (sliding / skidding) is occurring and the section is then discarded (steps S7 and S8). For example, how much speed is to be added or subtracted from the first sensor, for example, so that the speed of the reference sensor is multiplied by the correction factor. One optimization criterion is the minimization of such deviations to the square. However, other criteria for an optimization calculation are also acceptable, such as absolute values.

Although the invention has been illustrated and described in detail on the basis of exemplary embodiments, the invention is not limited to the disclosed exemplary embodiments and the specific combinations of features explained therein. Further variations of the invention can be obtained by one skilled in the art without departing from the scope of the invention as claimed.

List of reference symbols

1

Rail vehicle

3

Control unit of the rail vehicle

5

first speed sensor / position incremental encoder

6th

second speed sensor / position incremental encoder

7th

first axle / first wheel set of the rail vehicle

8th

second axle / second wheel set of the rail vehicle

S (i)

Step of a method for slip detection and / or correction factor determination in a wheel set for a rail vehicle

t

time

v

Vehicle speed

Claims (12)

A method for slip detection in a wheel set (7, 8) for a rail vehicle (1) to which a first wheel set (7) with a first speed sensor (5) and a second wheel set (8) with a second speed sensor (6) are assigned, comprising : - Acquisition of a plurality of measurement signals from the first speed sensor (5) and the second speed sensor (6), each of which is representative of a speed of the first wheel set (7) and the second wheel set (8) of the rail vehicle (1), - Determining a respective speed value for the first wheelset (7) as a function of a respective measurement signal from the first speed sensor (5) and for the second wheelset (8) as a function of a respective measurement signal from the second speed sensor (6), - Formation of speed value pairs, each with a determined speed value for the first and the second wheel set (7, 8), - Comparing the respective speed values for the first and the second wheel set (7, 8) of a formed speed value pair with one another and determining a correction factor via formed speed value pairs as a function of the comparison, - determining a speed deviation of a wheelset (7, 8) as a function of the determined correction factor, and - Determining a slip of the first and / or second wheel set (7, 8) as a function of the determined speed deviation. The method of claim 1 comprising:
Controlling a vehicle speed of the rail vehicle (1) as a function of the determined slip of the first and / or second wheel set (7, 8) taking into account the correction factor. The method of claim 2, wherein controlling the vehicle speed of the rail vehicle (1) comprises: - Providing a safety margin for a permissible vehicle speed of the rail vehicle (1) as a function of the determined slip, and - Controlling the vehicle speed of the rail vehicle (1) as a function of the provided safety surcharge. A method according to any one of claims 1 to 3, comprising: - Determination of at least one further correction factor as a function of the comparison of the respective speed values for the first and second wheelsets (7, 8) of the speed value pairs formed with one another, Discarding one of the correction factors determined as a function of the speed deviations determined in the process, and - Controlling a vehicle speed of the rail vehicle (1) as a function of the remaining correction factor or factors. Method according to one of Claims 1 to 4, in which the determination of the speed deviations comprises a regression analysis. A method according to any one of claims 1 to 5, comprising: - Specifying a deviation threshold value for a tolerable speed deviation, - comparing the determined speed deviations with the specified deviation threshold value, and - Determination of a slip of the first and / or second wheel set (7, 8) as a function of the comparison of the determined speed deviations with the predefined deviation threshold value. Method according to one of Claims 1 to 6, in which the first and second speed sensors (5, 6) each have a travel incremental encoder and the determination of a respective speed value for the first wheel set (7) and for the second wheel set (8) comprises: - Provision of circumferential values for a wheel of the first wheelset (7) and a wheel of the second wheelset (8), each of which is assigned a path incremental encoder, - Detecting a number of revolutions of the respective wheel of the first wheel set (7) and the second wheel set (8), and - Determination of a respective speed value for the first wheel set (7) and for the second wheel set (8) as a function of the respective provided circumferential values and the respective detected number of revolutions. Method according to one of Claims 1 to 7, in which the determination of a slip of the first and / or second wheel set (7, 8) as a function of the determined speed deviations comprises:
Detection of areas of the first and / or second wheelset (7, 8) that are influenced by and not influenced by slip as a function of the determined speed deviations and / or a determined correction factor deviation, and - Controlling a vehicle speed of the rail vehicle (1) as a function of the identified areas of the first and / or second wheelset (7, 8) that are influenced by and are not influenced by slip. A method according to any one of claims 1 to 8, comprising: - Determination of at least one further correction factor as a function of the comparison of the respective speed values for the first and second wheelsets (7, 8) of the speed value pairs formed with one another, - Formation of an arithmetic mean of the correction factors determined, and - Controlling a vehicle speed of the rail vehicle (1) as a function of the arithmetic mean formed of the correction factors. The method of claim 9 comprising: - Storing the arithmetic mean of the correction factors for a subsequent travel cycle of the rail vehicle (1), and - Controlling a vehicle speed of the rail vehicle (1) as a function of the stored arithmetic mean of the correction factors. Device (3) for slip detection in a wheel set (7, 8) for a rail vehicle (1), which is set up to carry out a method according to one of Claims 1 to 10. Rail vehicle (1), having: - A first set of wheels (7) and a second set of wheels (8), which are mechanically decoupled from one another, - A first speed sensor (5) and a second speed sensor (6), which are assigned to a respective wheel set (7, 8) and each have a travel incremental encoder, and whose measurement signals are each representative of a speed of the first wheel set (7) and the second Wheelset (8), and - A device (3) according to claim 11, which is coupled to the speed sensors (5, 6) in terms of signaling.

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