阅读说明：本技术 用于对内燃发动机中的高压泵进行预测性维护的报警方法 (Warning method for predictive maintenance of a high-pressure pump in an internal combustion engine ) 是由 P.塞雷基亚 于 2018-11-16 设计创作，主要内容包括：本发明的主题是一种关于包括减压阀的发动机的高压泵的状态的报警方法,阈值压力限定减压阀的开启压力,所述泵将加压燃料供应到配备有压力传感器的室。所述方法包括以下步骤：·当发动机停止时初始化计算机,在该停止期间,阈值压力和第一计数器的值被收集在与所述计算机相关联的存储器中,·测量室中的燃料的压力,·如果室中的燃料的压力高于或等于阈值压力,则将第一计数器递增,·当第一计数器的值超过预定阈值时,触发报警。(The subject of the invention is a method of warning about the condition of a high-pressure pump of an engine comprising a pressure reducing valve, a threshold pressure defining the opening pressure of the pressure reducing valve, said pump supplying pressurized fuel to a chamber equipped with a pressure sensor. The method comprises the following steps: -initializing the computer when the engine is stopped, during which stop the threshold pressure and the value of the first counter are collected in a memory associated with said computer, -measuring the pressure of the fuel in the chamber, -incrementing the first counter if the pressure of the fuel in the chamber is higher than or equal to the threshold pressure, -triggering an alarm when the value of the first counter exceeds a predetermined threshold.)

1. A warning method as to the condition of a high-pressure pump of an engine comprising a pressure reducing valve, a threshold pressure defining a cracking pressure of said pressure reducing valve, said pump supplying pressurized fuel to a chamber equipped with a pressure sensor, characterized in that it comprises the steps of:

initializing a computer when the engine is stopped, during which stop the threshold pressure and a first counter value are collected in a memory associated with the computer,

measuring the pressure of the fuel in the chamber,

incrementing the first counter if the pressure of the fuel in the chamber is greater than or equal to the threshold pressure,

triggering an alarm when the value of the first counter exceeds a predetermined threshold.

2. The alarm method of claim 1, wherein the method is ended when an alarm is triggered, or when a series of predetermined number of measurements each time a reduced pressure value in the chamber is generated.

3. The alarm method according to any one of claims 1 and 2, wherein an alarm is also triggered when a series of predetermined number of measurements each produce a pressure value that increases to exceed the threshold pressure.

4. The warning method according to any one of claims 1 to 3, wherein the threshold pressure stored in the memory is determined at the time of stop of the engine under predetermined conditions by performing the steps of:

continuously measuring the pressure in the chamber, and

storing in a memory the first measured pressure corresponding to a reduction in pressure compared to the pressure measured during the previous pressure measurement, this first measured pressure then being considered as the threshold pressure to be considered for the method according to any one of claims 1 to 3.

5. The alarm method according to claim 4, wherein the predetermined condition for determining the threshold pressure is as follows:

the pressure in the chamber is above a predetermined pressure, an

The temperature of the engine coolant is higher than a predetermined temperature, an

The temperature of the chamber supplied by the pump is below a given temperature, an

The ambient temperature is higher than the predetermined temperature.

6. The warning method according to any one of claims 1 to 5, wherein, under predetermined conditions, the threshold pressure stored in the memory is determined with the engine running by performing the steps of:

introducing into an engine control and management system a setpoint pressure for the chamber supplied by the high pressure pump, the setpoint pressure being higher than a theoretical maximum pressure that triggers the pressure relief valve,

continuously measuring the pressure in the chamber, and

storing in a memory the first measured pressure corresponding to a reduction in pressure compared to the pressure measured during the previous pressure measurement, this first measured pressure then being considered as the threshold pressure to be considered for the method according to any one of claims 1 to 5.

7. The alarm method of claim 6, wherein the predetermined conditions for determining the threshold pressure are as follows:

fuel supply to the cylinder is cut off, and

the temperature of the engine coolant is lower than a predetermined temperature, an

The engine speed is below a predetermined speed, an

The ambient temperature is higher than the predetermined temperature.

8. An engine control and management device, characterized in that it comprises means for implementing each of the steps of the method according to any one of claims 1 to 7.

9. An internal combustion engine, characterized in that it comprises a control and management device according to claim 8.

Technical Field

The invention relates to an alarm method for predictive maintenance of a high-pressure pump in an internal combustion engine.

More particularly, the present invention relates to a fuel pump for supplying an injection common rail of an internal combustion engine. Therefore, the fuel is stored at high pressure in the rail supplying the injectors: therefore, to be able to deliver pressurized fuel into the cylinder, it is necessary to open the injector.

Background

For the injection to work properly, it is necessary to keep the pressure in the injection rail as constant as possible. The high-pressure pump used to pressurize the rail is equipped with a pressure relief valve (or pressure relief valve PRV). When the fuel pressure becomes too high, the valve is triggered (opened).

In an engine, if the high-pressure fuel pump has failed, or even if it is operating in a degraded mode, it is clear that the overall operation of the engine is affected. In particular, if the pressure in the injection rail is not the nominal pressure, the injection of fuel into the engine does not occur under the optimal operating conditions expected for the engine, and therefore the fuel burns abnormally in the cylinder and does not achieve the expected performance (both in terms of delivered torque and pollution).

Disclosure of Invention

It is therefore an object of the present invention to avoid such situations and thus to avoid malfunctions due to failure of the high-pressure pump provided for the fuel.

It has been assumed and observed that when the pressure reducing valve of a high pressure fuel pump is activated too frequently, the efficiency of the corresponding pump decreases and the pump is no longer able to deliver the desired flow and/or pressure. Therefore, the engine has to run in degraded mode and the pump must be replaced. When the engine is running, the opening pressure of the Pressure Reducing Valve (PRV) is never or rarely reached, as it is a safety pressure reducing valve that is not expected to operate frequently when the engine is running. Frequent opening of the valve can be considered destructive due to frequent stress loads placed on the spring. On the other hand, when the engine is shut down, there is typically an increase in pressure in the high pressure rail (fuel chamber) due to the fact that engine cooling has ceased, due to a temporary temperature rise that occurs before the engine cools down. These openings of the pressure relief valve are counted according to the method of the pending application.

It is therefore another object of the present invention to determine an impending failure of a pump and/or to provide a warning of incurring pump replacement before the pump fails (or before it begins to operate less efficiently).

Furthermore, the engine control means is not aware of the exact pressure at which the pressure relief valve is triggered. This is because this pressure is dependent on the manufacturing tolerances of the pressure relief valve and therefore is not known in advance by the engine controller.

It is therefore another object of the present invention to determine the pressure that triggers the opening of the pressure relief valve.

To this end, the invention proposes a method of warning about the condition of a high-pressure pump of an engine comprising a pressure reducing valve, a threshold pressure defining the opening pressure of the pressure reducing valve, said pump supplying pressurized fuel to a chamber equipped with a pressure sensor, characterized in that it comprises the steps of:

initializing a computer when the engine is stopped, during which stop the threshold pressure and the value of a first counter are collected in a memory associated with the computer,

measuring the pressure of the fuel in the chamber,

if the pressure of the fuel in the chamber is greater than or equal to a threshold pressure, incrementing a first counter,

when the value of the first counter exceeds a predetermined threshold, an alarm is triggered.

Thus, the method makes it possible to predetermine when a high-pressure pump needs to be replaced and typically before the pump fails. Not all faults are avoidable (especially sudden failures), but most faults are avoidable.

The method ends, for example, when an alarm is triggered, or when a series of predetermined number of measurements each time a reduced pressure value in the chamber is generated.

The alarm method as defined hereinabove may also provide that an alarm is also triggered when a series of predetermined number of measurements each time a pressure value is generated that increases to exceed the threshold pressure. In that case, a fault is detected (rather than predicted).

In order to render the counting of the number of openings of the pressure reducing valve more accurate, the opening pressure value of the valve may be perfected, for example. For example, provision may be made for determining the threshold pressure stored in the memory at the time of engine stop, under predetermined conditions, by carrying out the following steps:

continuously measuring the pressure in the chamber, and

storing in a memory a first measured pressure corresponding to a reduction of the pressure compared to the pressure measured during the previous pressure measurement, this first measured pressure then being considered as the threshold pressure to be considered for the method as described above.

In a preferred embodiment, in this way of determining the opening pressure of the pressure reducing valve, it is possible to specify the predetermined conditions for determining the threshold pressure as follows:

the pressure in the chamber is above a predetermined pressure, and

the temperature of the engine coolant is higher than a predetermined temperature, an

The temperature of the chamber supplied by the pump is lower than a given temperature, an

The ambient temperature is higher than the predetermined temperature.

Alternatively or cumulatively, under predetermined conditions, the threshold pressure stored in the memory may be determined with the engine running by performing the following steps:

introducing into the engine control and management system a set-point pressure for the chamber supplied by the high-pressure pump, which is higher than the theoretical maximum pressure that triggers the pressure-reducing valve,

continuously measuring the pressure in the chamber, and

a first measured pressure is stored in the memory, which first measured pressure corresponds to a reduction of the pressure compared to the pressure measured during the previous pressure measurement, this first measured pressure then being considered as the threshold pressure to be considered for the above alarm method.

In this variant of the alarm method, the predetermined conditions for determining the threshold pressure may be as follows:

fuel supply to the cylinder is cut off, and

the temperature of the engine coolant is lower than a predetermined temperature, an

The engine speed is below a predetermined speed, an

The ambient temperature is higher than the predetermined temperature.

The invention also relates to:

an engine control and management device comprising means for implementing each of the steps of the method described hereinbefore, and/or

An engine comprising such a control and management device.

Drawings

The details and advantages of the invention will become more clearly apparent from the following description, which is supported by the accompanying schematic drawings:

figure 1 illustrates a view in longitudinal section of a pressure relief valve,

FIG. 2 is a flow chart of a preferred embodiment of the alarm method,

FIG. 3 is a flow chart of a preferred embodiment of how to determine the threshold pressure used in the flow chart of FIG. 2, an

FIG. 4 is a flow chart of a preferred embodiment of another way of determining the threshold pressure used in the flow chart of FIG. 2.

Detailed Description

Fig. 1 illustrates, purely by way of non-limiting illustration, a pressure reducing valve (known from the prior art) that can be used in combination with a high-pressure pump intended to pump fuel (for example, gasoline) into an internal combustion engine (for example, an engine for a motor vehicle). The high pressure pump delivers high pressure fuel to a chamber (also commonly referred to as a rail) for supplying the injectors. The chamber is common to several injectors. Thus, the injectors are always under pressure and all that is required is to open them in order to supply the corresponding cylinders with fuel.

The high-pressure pump is associated with a pressure reducing valve illustrated in fig. 1, for example. Such valves are also known by their abbreviation PRV, which stands for pressure relief valve (full name for pressure reducing valve). The high pressure outlet of the pump supplies fuel to a conduit 2 formed in a valve body 4. The valve ball 6 closes the conduit 2. The ball is preloaded into a position in which the duct 2 is closed by a hollow stem 8 in which a seat 10 is formed which houses the ball 6 and a spring 12 which bears against a head 14 of the stem 8. When the stem 8 is removed from the valve body 4, it opens a passage to the discharge conduit 16 for the fuel initially in the conduit 2.

In order to open the decompression chamber, the fuel coming from the high-pressure pump needs to exert a force on the ball 6 and on the head 14 of the stem 8 that is higher than the force exerted on these elements by the spring and by the fuel in the decompression chamber.

The fuel exerts a pressure on the valve ball 6 and the head 14 and a force related to the viscosity of the fuel. The opposite to these forces is: on the one hand by the spring 12 and on the other hand by the fuel located on one side of the discharge conduit 16. The force exerted by the spring 12 is the force exerted by the spring in its rest position and the force exerted by the compression of the spring (which is equal to the change in the spring stiffness times the spring length). The forces exerted by the fuel are the pressure and the force related to the viscosity of the fuel. Since the pressure on one side of the discharge conduit is substantially constant, the opening of the pressure reducing valve will substantially depend on the pressure of the fuel in the conduit 2 (i.e. the pressure of the fuel delivered by the high pressure pump).

FIG. 2 illustrates a preferred embodiment of a method for creating an alarm prior to failure of a high pressure fuel pump in an engine and under certain failure modes. The flow chart is intended to be run by one of the computers present in the engine for engine control and management.

In the flow charts of fig. 2 to 4, the letter N is used for "no", and the letter Y is used for "yes".

The first decision block (fig. 2) "STOP" relates to the state of the engine. This method does not work as long as the engine is running. It starts when the engine is stopped. To determine whether the engine is running, it is possible to see whether the engine ignition switch is open or closed, or to see the speed of the engine.

When an engine stop is detected, several parameters are initialized:

setting the increment n to 0,

the pressure of the fuel acting on the pressure reducing valve is measured and this measured value FUPmes is stored in memory as the initial fuel pressure value FUP 0. The continuous fuel pressure measurement will be referred to hereinafter as FUPn, where n is incremented at each measurement,

the increment ctrprrv counting the number of activations of the pressure reducing valve is collected in a memory in which it was recorded the last time the method was implemented. Therefore, CTRPRV takes the value CTRPRVmemo already stored in the memory. When the method is first run in the engine, ctrprrvmemo may for example be set to 0 (any other value may be chosen as well),

fig. 3 and 4 illustrate two methods that allow learning of this value, at the end of such learning, the determined value prvsetmo is stored in memory, when learning is not performed, the value prvsetmo corresponds to the theoretical maximum at which the pressure relief valve will open, for example, if it were to be opened for pressures P0 ± α by configuring the pressure relief valve, prvsetmo would be initialized, for example, to P0+ α, or to a value a few bars higher than this value,

the delta PRV KO is initialized to 0. As the pressure continues to increase, the increase will be used to detect a failure of the pump even though the relief valve trigger pressure has been reached, and

the delta ctrFUPdec is initialized to 0. In most cases, i.e. when no alarm is issued, this increment will be used to end the method.

When an engine stop is detected and initialization has been performed, increment n is incremented by one value and a fuel pressure measurement FUPn is taken.

First, the new measurement value is compared with the previously measured value (last measurement value): FUPn-FUPn-1 is greater than or equal to 0.

If a decrease in pressure is observed, the increment ctrFUPdec is incremented. As long as the value of the increment does not exceed the predetermined value N1, a further measurement is taken. When the value N1+1 is reached, the increment ctrprrv is checked, which counts the number of openings of the pressure reducing valve. Typically, the increment is below the threshold N2 for the critical number of openings. In that case, the current value of CTRPRV is stored in memory and becomes the new value CTRPRVmemo to be used for the next run of the method. Step "X" then corresponds to the end of the method. During this step, the request to keep the computer that handles the operation of the method active is terminated, among other things.

On the other hand, if the increment ctrprrv is higher than the threshold N2, an alarm is triggered in step "W". After this step, the current value of CTRPRV is also stored in memory and the method ends, as explained in the previous paragraph.

Consider now an event in which the fuel pressure measurement increases. This is a condition that typically occurs when the engine is stopped. This is because fuel is stored in the rail. Given the temperature of the engine, the temperature in the rail has a tendency to rise, and thus the pressure in the rail increases. In such an event, it is necessary to see if the measured pressure value FUPn exceeds the threshold value PRVset. In parallel, since the pressure is increasing, the increment ctrFUPdec, which sums up the number of measurements that decrease successively, is set to 0.

If the threshold is not reached, a new measurement is made and increment n is incremented.

If the threshold is reached, the pressure relief valve is opened and the increment CTRPRRV is incremented.

Then, increment n is incremented again and additional fuel pressure measurements are taken. If the fuel pressure has dropped below the limit pressure PRVset, a further measurement is started with a new increment n and where the increment PRV KO is set to 0. On the other hand, if the fuel pressure remains above the value PRVset, the increment PRV KO is incremented, which counts successive pressure measurements above the pressure PRVset in a manner similar to the increment ctrFUPdec (which counts successive measurements taken with decreasing pressure). As long as the value of this increment remains below the limit value N3, a further pressure measurement is carried out and PRV KO is incremented as long as the measured pressure remains above the limit pressure PRVset.

If limit N3 is reached (this number is fixed based on the frequency of fuel pressure measurements and the characteristics of the pump and pressure relief valve), an alarm is triggered (step W). This is because, in such a case, the pressure reducing valve remains abnormally closed and is therefore able to perform its function. The anomaly is then signaled by an alarm.

Once the alarm has been triggered, the alarm procedure is terminated. As indicated above, the current value of CTRPRV is stored in memory and the request to keep the computer managing the operation of the method active is terminated (step "X").

Thus, the method makes it possible: on the one hand, an alarm is triggered when the pressure relief valve opens N2 times, and on the other hand, an alarm is triggered when the pressure relief valve of the high-pressure pump is no longer able to perform its function.

Fig. 3 illustrates one way of determining the limit value PRVset, which corresponds to the fuel pressure that triggers the opening of the pressure relief valve. As indicated above, the initial value (engine new) is initially stored in memory and corresponds to the theoretical maximum.

First, it is determined whether a determination of the value of the opening pressure of the pressure relief valve is required ("PRVset") is suitable. If the value has been determined "recently", this need not be done. This is because this value varies with mechanical wear of the parts and with variations in the stiffness value of the spring 12. The conditions for newly determining the value of the opening pressure are predefined according to the criteria to be established. By way of illustrative and non-limiting example only, it is possible to expect a new calibration to be performed every n kilometres, or every six months or a combination of these parameters, for example.

If it is indeed necessary to determine the relief valve opening pressure, this determination can be done only once the external conditions (which will be defined beforehand) themselves are also satisfied. In the case illustrated in fig. 3, it is therefore proposed that the relief valve opening pressure should be redefined if the engine is in an operating mode in which the fuel supply to the cylinders is cut off and the following three conditions are met:

the temperature of the engine coolant is low: for example (illustrative and non-limiting, as with all values in this description) below 40 ℃;

the engine speed is low (e.g. below 3000 rpm for so-called gasoline engines);

ambient temperature is low (e.g., below 10 ℃).

In summary, the determination will be made in the case where the engine is cold, at a low rotational speed. The idea is therefore to force the pump to supply fuel to the injection rail and see when the pressure relief valve opens. This plays an important role in the flow chart of fig. 3 as explained hereinafter.

In this fig. 3, when it is necessary to determine the opening value of the pressure reducing valve on the one hand and to satisfy an external parameter on the other hand, the set value of the high-pressure pump is then modified so that it is higher than the opening pressure of the pressure reducing valve, which may be, for example, the pressure P0+ α mentioned above, or a pressure higher than the pressure P0+ α other strategies may be chosen here (for example, taking the last known pressure PRVset and increasing it by 20 bar, etc.).

Once this value is determined (assuming this is FUPdec1 in fig. 3), it is stored in memory and thus becomes PRVsetmemo, which will be used for the next run of the method illustrated in fig. 2. Thus, the value of the opening pressure PRVset is determined, and the learning process may be terminated.

The method illustrated in FIG. 4 is another routine that may be used to determine the opening pressure of a pressure relief valve. This method is not an alternative to the method of fig. 3. Both methods can be implemented in the same engine. As is apparent from the following, these methods cannot be implemented in parallel due to different implementation conditions. Then, depending on the external conditions, one or the other of the two methods may be implemented.

First, it is determined whether a determination of the value of the opening pressure of the pressure relief valve is required ("PRVset") is suitable. These conditions are preferably the same as those listed with reference to fig. 3. Once the predetermined condition has been met, the processor is placed in a standby state to determine which of the conditions of FIG. 3 or FIG. 4 (see below) will be met first.

Therefore, let us assume here that the relief valve opening pressure does need to be determined. In the case illustrated in fig. 4, it is proposed to redefine the relief valve opening pressure if the engine is stopped and if the following four conditions are satisfied:

the temperature of the engine coolant is high: for example (illustrative and non-limiting, as with all values in this description) above 90 ℃;

fuel pressure is already high: for example, above 350 bar;

ambient temperature is high (e.g., above 30 ℃);

the temperature of the fuel in the rail is relatively low (e.g., below 50 ℃).

In summary, the determination will be performed with the engine hot (when the engine exterior is hot and the fuel is not too hot). The idea is then that the fuel pressure will increase (and even increase rather quickly) because it is not very hot, but is placed in a hot environment. Since the fuel pressure is initially quite high, it should then exceed the relief valve opening pressure value. The rise in pressure in the fuel rail is then observed and recorded as soon as a drop in pressure is identified. This drop may be due solely to the opening of the pressure relief valve. This plays an important role in the flow chart of fig. 4 as explained hereinafter.

In this fig. 4, when it is necessary to set the relief valve opening value (determining PRVset) on the one hand and to satisfy the external parameters on the other hand, then a fuel pressure measurement is carried out and the variation of this pressure is monitored in order to determine a first measured pressure value (called FUPdec 1) lower than the previous one. Here again, the strategy may be slightly different. For example, it is possible to select the maximum value of the measured pressure. It is also possible to determine a curve from the measured values (e.g. using the least squares method) and to determine the opening value from the curve.

Once this value is determined (assuming this is FUPdec1 in fig. 4), it is stored in memory and thus becomes PRVsetmemo, which will be used for the next run of the method illustrated in fig. 2. Accordingly, the value of the opening pressure PRVset is determined, and the learning process may be terminated (step X).

The above description therefore makes it possible, firstly, to determine the fuel pressure that triggers the opening of a pressure reducing valve associated with a high-pressure pump intended to pump said fuel in a rail supplying the injectors. Next, an alarm method is proposed in order to be able to provide a warning and to elicit predictive maintenance of the high-pressure fuel pump.

Thus, in most cases, the implementation of the above method makes it possible to avoid a fuel pump failure that leads to a serious failure, i.e. the stopping of the vehicle or at least its operation in a very degraded mode (in which the engine speed and torque are limited). Thanks to the alarm issued, the component can be replaced before the failure occurs and thus such a failure can be avoided.

The learning procedure described and illustrated allows to optimally customize the opening pressure value of the pressure relief valve. In that way, the alarm method can be implemented more efficiently and more accurately. Accurate knowledge of this opening pressure also has great utility in perfecting engine control strategies.

The invention is of course not limited to the embodiments described above and illustrated in the drawings or the variant embodiments mentioned, but also encompasses embodiment variants which are within the capability of a person skilled in the art.