EP3807512A1 - Method for wear detection and predictive wear prognosis of electromechanical actuators in relation to the operating time of a machine with combustion engine - Google Patents

Abstract

1. Method for wear detection and predictive wear prognosis of electromechanical actuators in relation to the operating time of a machine with combustion engine 2. A method for wear detection and predictable wear prognosis of electromechanical actuators (in particular throttle flap, exhaust-gas recirculation valve, exhaust-gas flap and overpressure valve at the turbocharger, or others) in relation to the operating time of a machine with combustion engine with at least one engine control unit, comprising a first measuring method for identifying the actuator wear in the form of movement profiles and the number of different actuator movements within individual movement profiles, wherein the number of different actuator movements is compared with reference data, and a second measuring method which identifies production errors through stimulation of the electromechanical actuators with a step change and measurement and evaluation of the step change response, or the settling time of the actual position in relation to the setpoint position.

Description

 Process for wear detection and predictive wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine

DESCRIPTION

The invention relates to a method for wear detection and predictive wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine.

No methods are known from the prior art, wear detection is not possible since there is no integrated method for wear detection. This means that no wear forecast is possible.

The invention has for its object to provide a method for wear detection and predictive wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine.

This object is achieved by the features of patent claim 1. Further embodiments and advantages according to the invention emerge from the subclaims.

Accordingly, a method for wear detection and predictable wear forecast of electromechanical actuators (especially throttle valve, exhaust gas recirculation valve, exhaust gas valve and pressure relief valve on the turbocharger or others) becomes the operating time of a machine with an internal combustion engine with at least one engine control unit, comprising a first measurement method for identifying the actuator wear in the form of movement profiles and the number of different actuator movements within individual movement profiles, the number of different actuator movements being compared with reference data and a second measuring method, the production error in such a way recognizes that the electromechanical actuators are stimulated with a jump and the step response or the settling time of the actual position to the target position is measured and evaluated

The invention is explained in more detail by way of example with reference to the accompanying figures. Show it:

Figure 1: Composition of the global process as a schematic representation

 Figure 2: Testcycle200 was created from real field data

Figure 3: Endurance test with test cycle 200

Figure 4: Visualization of the endurance test results

Figure 5: System diagram interaction of systems and components

 Figure 6: Exemplary electromechanical actuator, electrical

 Exhaust gas recirculation valve, 0% actuator position = valve fully open, 100% actuator position = valve fully closed, intermediate positions are possible e.g. 33% = valve closed to a third

The global method can be divided into two different measurement methods, as shown in Figure 1. Measuring method 1 identifies the actuator wear in the form of movement profiles and the number of different actuator movements within individual movement profiles. This number is compared with reference data.

The measurement procedure is used to detect and forecast wear on the electromechanical actuators.

The measuring method 2 is used to detect accidental or production errors. This increases the robustness of the entire method, since random errors cannot be detected using measuring method 1. For this purpose, a diagnostic function is used which controls the respective electromechanical actuator and at the same time the reaction time of the z. B. Actuator gangs records. The response time is compared with values from the specification. Figure 1 shows the composition of the process in a schematic representation.

Measuring method 1 is described below. This procedure can be divided into the following phases:

The test cycle is defined in phase 1. First, a real test / load cycle (field data of a fork-lift truck) is measured, which corresponds to a worst-case scenario - the worst case scenario that can occur in the future - as shown in Figure 2. In this specific example, this load cycle contains the measurement data (e.g. consisting of the exhaust gas recirculation valve position on the Y axis in percent and the time on the X axis). The data are recorded using an engine control unit. The valve communicates the relative valve position using electrical voltage. This voltage is discretized in the engine control unit by means of an analog / digital converter. One movement corresponds to the relative valve position over time. The valve position can take values in the interval of [0%, 100%]. 0% stands for the fully open state and 100% for the fully closed state of the valve (see Figure 6). The valve is regulated to the respective position depending on the load cycle of the internal combustion engine. The electric servomotor in the actuator opens or closes the valve. The adjustment of the valve position described here causes wear over the operating time of the internal combustion engine. In particular, commutator wear of the electric servomotor and mechanical wear in the gear (gear wheels) of the valve. These types of wear are predicted using the procedure described here. The test cycle is defined below as the standard test cycle 200. The test cycle 200 is scaled in the next step so that it corresponds to a defined service life of the internal combustion engine. This is achieved by deleting constant valve positions (persistence of the valve for a long time, e.g. one second in one and the same position) from the discretized measurement data. All movements are (temporally) set to 200 ms time compressed. The service life of the internal combustion engine can be simulated in a short time by compression and repeated repetition of the cycle. Figure 2 reveals the test cycle 200, which arises from real field data.

A real and application-oriented test cycle (as used in this description) is preferable to a synthesized cycle (non-contiguous or statistical movement stimulation). Because the real test cycle includes a logical and functional connection of the different movements. In other words, the information of the motion overlay is available in a real application. Phase 2 represents the load test (cf. Wöhler test). A certain number of the actuators in question (possibly several of the same type in order to obtain a sufficient sample size) are loaded with the test cycle 200 until the actuators either fail due to wear or outside work according to their specification. The actuator positions or movements from the test cycle 200 are specified by means of an H-bridge or a controllable voltage source in the form of an electrical voltage (which each represents a position). This means that the test cycle 200 as electrical. Voltage course is stimulated. During the test, the functions of the actuators are continuously monitored and recorded, as shown in Figure 3. Table 1 shows the number of movements of the test cycle 200.

Test cycle 200 _ runtime = 200 ms · 100 movements = _ 20.0 [s] large movement 26

medium movement 37

small movement 37

 Total 100

Table 1 Figure 3 shows the endurance test with the test cycle200. In order to meet the requirements of the worst-case scenario, the ambient temperature is raised to 40 ° C during the stress test. The actuators are assessed by the manufacturer at the end of the test to confirm the respective wear.

In phase 3, reference data is generated as follows: Several motion profiles are defined (number or granularity of the profiles can vary depending on the test cycle). Movement profile 1 large movements (e.g.> 30%), movement profile 2 medium movements (e.g. <= 30% and> 10%), movement profile 3 small movements (e.g. <= 10%) (cf. Table 3). On the basis of the motion profiles, the maximum movements made during the endurance run or stress tests can be determined absolutely (see Table 1). Example: Actuator 4 massive wear after 830 operating hours (see Figure 4). It has the lowest operating time of all actuators. As a first approximation - worst-case analysis - the time threshold of 800 operating hours is defined (see Table 2). The maximum number of movements per profile (reference values) can be calculated according to Formula 1 (see Table 3): (Formula 1)

n _ma xpx = maximum number of movements per profile

n _px = number of movements per profile

t _max = time threshold [h]

c _t = time constant = 3600

T _Cyci = duration of the test cycle ₂₀₀ [s]

Table 2 shows the result of the endurance test with Testzyk- Ius200.

 Table 2

Table 3 shows the calibratable thresholds of the maximum number of movements per movement profile (right column) according to Formula 1.

 Table 3

Figure 4 shows the visualization of the endurance test results.

Table 4 In phase 4 the predictions are calibrated and calculated. The reference values are now calibrated in the engine control unit. During the operating period, the control unit calculates the current status (remaining movements per actuator per movement profile) and predicts after how many more operating hours the maximum number of movements per actuator will have been reached. This information is communicated via an interface (e.g. CAN bus). For the forecast, the method of time series analysis is used in combination with the method of exponential smoothing, which are explained below: The process created here (reduction of the profile movements through the load cycle of the internal combustion engine) is steady and monotonously falling. This is a consequence of the subsampling (sampling or calculation in multiples of the observation interval). The strong smoothing effect leads to a linear trend (model) (straight line equation). The process consists of the operating time of the internal combustion engine and the remaining movements per actuator per profile. Exponential smoothing is used to periodically predict the remaining movements per profile (the numbering or sequence of the formulas corresponds to the calculation sequence in the engine control unit): Calculation 1. Order as an intermediate value:

Z1 ₁ [% 3 = intermediate value of exponential smoothing 1. order

a = smoothing constant for exponential smoothing 1. order

O _bsrv [%] = current measured / calculated actual value of the remaining

 movements

Z1 _t -i [%] = previous intermediate value (Formula 2)

2nd order calculation:

Z2 _t [%] = intermediate value of second-order exponential smoothing

ß = smoothing constant for 2nd order exponential smoothing

Z1 _t [%] = intermediate value of exponential smoothing 1. order

Z2 _ti [%] = previous intermediate value 2 ₁ - ß · Zl _t + (1— ß) · Z2 _{t- 1} (formula 3)

The smoothing constants (a and ß) can be determined using field data and simulation of the process or with the help of an optimization process.

After exponential smoothing has been calculated (for the entire forecast horizon), Formula 4 is applied. The current smoothing factors at the time of the forecast horizon are smoothed again and multiplied by the forecast horizon. To do this, the Y-axis section is added and the result is the forecast (remaining movements) at time FCH (for example, after another 100 operating hours, the respective actuator will have reached 70% of its total movements).

(Formula 4) Calculation of the time of failure:

 Another possibility is to calculate the time of complete wear. In other words, when and at what point in time the respective component will have reached the maximum number of movements. This is achieved by using formulas 5 to 7. The slope m (average slope) is calculated over the entire forecast horizon and the y-intercept. Then the straight line equation is solved after the (remaining) operating time. ° bsrvMin corresponds to 0% residual movements in this case.

Forecast _time [h] = operating time in hours until the lower threshold is reached

^Q bsrvMin

 ° bsrvMin [%] = lower threshold of wear, here: 0% residual movements

 = Slope

b [%] = Y intercept

 I t + FCw [%] = intermediate value of exp. Smoothing of the 1st order at the time FCH

 CW [h] = forecast horizon (e.g. 10 5 (observation interval)

 = 50 = FCH

Z2 _t + fCH-i [%] = intermediate value of the exp. Smoothing 2nd order at the time FCH - 1

Forecast _vec [%] = forecast vector of length ^FCH

T ₀ bserv [h] = observation interval, one forecast calculation per toserv i bsrvMin b) (formula 5)

Forecast _f ine =

 m

With:

Y intercept b: (Formula 6)

Slope m:

Forecast _vec [end] - Forecast _vec [start]

 m = -

T _obse r _v ^' length (Forecast _vec ) (Formula 7)

The prediction result is continuously monitored during the runtime. For this purpose, the forecast error (MAPE, Mean Absolute Percentage Error, see Formula 4) is determined periodically. If an excessive deviation appears over several periods, the smoothing coefficients of the exponential smoothing are adjusted more, if the deviation is small, the smoothing factors are adjusted slightly or not.

M = MAPE [%]

n = number of forecasts

A _t = currently determined value of the remaining movements [%]

F _t = forecast value of the remaining movements [%]

(Formula 8)

 The forecast of the remaining movements or the remaining operating time is compared with the regular maintenance interval of the internal combustion engine. If a regular maintenance interval cannot be reached due to the fact that the remaining operating time is less than the difference between the time of the regular maintenance interval and the remaining operating time, the time to be observed for the electromechanical actuator maintenance is communicated. If the regular maintenance interval can be reached, the status is communicated that the electromechanical actuators should be replaced during the next regular maintenance. If the electromechanical actuators are not serviced in good time, a diagnostic status is activated.

Figure 5 shows the system diagram or the interaction of the systems and components. For example, actuator 1 = throttle valve, actuator 2 = exhaust gas recirculation valve, actuator 3 = exhaust gas valve, actuator 4 = pressure relief valve on the turbocharger. The actuators 1 - 4 are regulated components of the internal combustion engine. The positions or movements of the actuators are regulated via the engine control unit depending on the load spectra requested (e.g. by the driver of a machine). The engine control unit identifies the individual movements in the respective profiles and calculates the forecast using formulas 2 to 8. The calculated forecast value is, for. B. via CAN bus (J1939) telegram made available to other systems (signaling).

Measuring method 2 is described below. In order to increase the robustness of the global process, the triggering reaction time of the electromechanical actuators is checked in addition to the motion profiles (measurement process 1) (measurement process 2). The movement profiles make the wear and the wear forecast visible or measurable. However, accidental or production errors in the drive of the electromechanical actuator cannot be detected in this way. For this reason, a further measuring method is now described in order to be able to recognize random errors in the actuator drive and thus to make the global method more robust with regard to errors that are due. Functioning of the measuring method 2: At a defined and favorable time, e.g. B. after (run-on time) or before the operating time of the internal combustion engine, the electromechanical actuators are stimulated with a jump (from 0% = closed to 100% = completely open). The step response, more precisely the settling time of the actual position to the target position, is measured and evaluated. The required actuating time or settling time of the actuators when new can be found in the manufacturer's specification. The tolerance range (or series spread) of the settling time is 19% according to the specification. Table 4 shows the wear-related deviations of the actuators used from measurement method 1. It can be seen that the tolerance range of the settling time of 19% has been exceeded. The settling time is one of the features that is used to identify abnormalities in the individual actuators. Others are e.g. B. Internal resistance of the actuator, torque, speed, etc. The settling time is the only one that is automatic during the operation of the internal combustion engine. can be measured (from the point of view of the engine control unit especially for non-intelligent electromechanical actuators such as H-bridge actuators). The settling time without the other mentioned features alone is too imprecise to represent exact forecasts or the exact wear. That is why it is used in this procedure for wear identification as additional information, but above all for the detection of random errors in the drive. For this purpose, a threshold (in consultation with the manufacturer instead of 19%, 33%) is defined as to when a significant deviation of the settling time from the new condition but also from normal wear and tear (as shown in table 4) can be seen.

Claims

Process for wear detection and predictive wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine

1 . Method for wear detection and predictable wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine with at least one engine control unit, comprising a first measurement method for identifying the actuator wear (especially throttle valve, exhaust gas recirculation valve, exhaust gas valve and pressure relief valve on the turbocharger or others) in the form of Movement profiles and the number of different actuator movements within individual movement profiles, the number of different actuator movements being compared with reference data, and a second measurement method that detects production errors in such a way that the electromechanical actuators are stimulated with a jump and the step response, or the settling time of the actual position to the target position is measured and evaluated.

2. A method for wear detection and predictable wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine according to claim 1,

characterized in that a real test or load cycle is measured.

3. Method for wear detection and predictable wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine according to one or more of the preceding claims, characterized in that the real test or load cycle is digitized and scaled so that it corresponds to a defined service life of the internal combustion engine.

4. A method for wear detection and predictable wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine according to one or more of the preceding claims,

characterized in that the relevant actuators (possibly several of the same type in order to obtain a sufficient sample size) are loaded with the test or load cycle until the actuators either fail due to wear or work outside their specification.

5. A method for wear detection and predictable wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine according to one or more of the preceding claims,

characterized in that the functions of the actuators are continuously monitored and recorded during the test.

6. Method for wear detection and predictable wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine according to one or more of the preceding claims,

characterized in that several motion profiles are defined for generating reference data.

7. method for wear detection and predictable wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine according to one or more of the preceding claims,

characterized in that the reference data are calibrated in the engine control unit.

8. A method for wear detection and predictable wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine according to one or more of the preceding claims,

characterized in that the control unit calculates and predicts the current state or the remaining movements per actuator and per movement profile during the operating time, after how many further operating hours the maximum number of movements per actuator will be reached.

9. method for wear detection and predictable wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine according to one or more of the preceding claims,

characterized in that the time series analysis method is used in combination with the exponential smoothing method for the wear forecast.

10. A method for wear detection and predictable wear forecast of electromechanical actuators at the operating time of a machine with an internal combustion engine according to one or more of the preceding claims,

characterized in that the forecast of the remaining movements or the remaining operating time is compared with the standard maintenance interval of the internal combustion engine. If a regular maintenance interval cannot be reached due to the fact that the remaining operating time is less than the difference between the time of the regular maintenance interval and the remaining operating time, the time of the electromechanical actuators to be observed is communicated with a timely maintenance notice. If the regular maintenance interval can be reached in time, the status is communicated that the electromechanical actuators should be replaced during the next regular maintenance. Shouldn't be on time maintenance of the electromechanical actuators, a diagnostic status is activated and communicated.