FR3005998A1 - DEVICE FOR DETERMINING ABSOLUTE PRESSURE IN A THERMAL MOTOR CYLINDER - Google Patents

Abstract

The invention relates to a device for determining the absolute pressure in a cylinder (2) of a heat engine (1) having a cylinder head, said cylinder (2) comprising a piston (4) movable, able to delimit a combustion chamber (6) of variable volume, said device comprising at least a first sensor implanted in said cylinder head for measuring a relative pressure in said combustion chamber (6) during a motor cycle. The main characteristic of a device according to the invention is that it comprises at least a second pressure sensor (7) whose position in the cylinder (2) allows a measurement of the absolute pressure in the chamber (6). only when the volume of said chamber (6) tends to a maximum value, the pressure measurements obtained with each first sensor and with each second sensor (7) being combined to determine the absolute pressure in the combustion chamber (6). ) during a complete motor cycle.

Description

The invention relates to a device for determining the absolute pressure in a cylinder of a heat engine and to the associated determination method. A heat engine, or internal combustion engine, comprises at least one combustion chamber whose volume is variable depending on the position of a piston sliding inside thereof, during a motor cycle. The variation of the position of the piston causes a variation of the volume of the chamber, and therefore of the pressure prevailing inside it. In the context of the development of combustion systems in such engines, it is essential to know the evolution of the pressure in each chamber 15 during an engine cycle, whether it be a two-stroke engine or a four-stroke engine, and whatever the nature of the fuel used. In order to meet this need, pressure sensors adapted to high pressure levels of up to 250 bar in certain applications are installed in a cylinder head of the engine, and thus return a signal making it possible to know a relative pressure in the engine. the combustion chamber. Such sensors may for example be of the piezoelectric type. If in most cases this relative pressure is sufficient to analyze the results, it may be necessary to know the absolute pressure in a combustion chamber, for example to determine the air mass enclosed, or to make a calculation. precise release of energy produced in said chamber. However, the range of previous sensors does not allow access to this absolute pressure. One method commonly used to determine this absolute pressure involves the use of an additional sensor, measuring the gas pressure in an intake duct or an engine exhaust duct. The pressure level in this type of duct being much lower than that of the combustion chamber, it is then possible to use absolute pressure measuring sensors, such as, for example, piezoresistive sensors. This method consists in choosing a particular instant, for which the pressure in the intake duct is equal to the pressure in the chamber, and then calculating the correction to be made to the overall measurement of the relative pressure in the combustion chamber, for obtain the absolute pressure in said chamber. By way of example, on a four-stroke engine, it is generally chosen to match the relative pressure in the combustion chamber to the absolute pressure measured in the intake duct, during the intake phase for which a valve intake is open and allows the gas to pass freely from said conduit to said chamber with an equalization of the pressures between the conduit and the chamber. It should be noted that this mapping is more specifically performed at the time corresponding to the bottom dead center (PMB) of the piston. This method has the disadvantage of being approximate insofar as it does not take into account neither the pressure drops at the passage of the valve, nor the acoustic phenomena in the ducts, corresponding to variations in the instantaneous pressure. An absolute pressure determination device according to the invention makes it possible to determine the absolute pressure in a combustion chamber of a heat engine during a cycle of said engine, by overcoming the drawbacks of the state of the art. The invention relates to a device for determining the absolute pressure in a cylinder of a heat engine having a cylinder head, said cylinder comprising a movable piston, able to define a combustion chamber of variable volume, said device comprising at least one first sensor implanted in said cylinder head for measuring a relative pressure in said combustion chamber during a motor cycle.

The main characteristic of a device according to the invention is that it comprises at least a second pressure sensor, whose position in the cylinder allows a measurement of the absolute pressure in the combustion chamber only when the volume of said chamber tends to a maximum value, the pressure measurements obtained with each first sensor and with each second sensor being combined to determine the absolute pressure in the combustion chamber during a complete engine cycle. Indeed, as generally the second pressure sensor is not dimensioned to be able to measure the maximum absolute pressure levels reached during a complete engine cycle, the principle of the device according to the invention is to create an absolute pressure reference on a restricted pressure range thanks to the second sensor, then to reset on this reference the curve of variation of the relative pressure obtained with the first sensor over a whole engine cycle, to obtain the absolute pressure in the combustion chamber at each moment of a motor cycle. It is recalled that the volume of the combustion chamber is variable during a motor cycle, by means of the sliding of the piston in the cylinder. According to a preferred embodiment of a device according to the invention, the second sensor is positioned in the cylinder so as to undergo at least one occultation phase by the piston and at least one phase where it is no longer obscured by the piston during a motor cycle. Thus, when the piston is placed in front of the second sensor, it can not take any measurement of absolute pressure. Preferably, the expression "tends towards a maximum value" means that the volume of the chamber is at least equal to 90% of its maximum volume. Advantageously, a determination device according to the invention comprises a single first sensor and a single second sensor per combustion chamber. Indeed, an engine generally comprises several cylinders, and the determination device according to the invention is reproduced for each combustion chamber thus defined.

Preferably, the second sensor is implanted in a wall delimiting the combustion chamber, so that it can take measurements of the absolute pressure only after the withdrawal of the piston, when the volume of said chamber tends to a value Max. Indeed, during a complete engine cycle, the piston is slid into the cylinder between a first extreme position for which the volume of the combustion chamber is maximum, and a second extreme position for which said volume is minimum. Thus, the location of the second sensor in the cylinder is chosen so that it is obscured by the piston as it moves between the second end position and a position close to the first end position. Preferably, the second sensor is placed near the position of the piston at the bottom dead center. In this manner, said second piston can acquire absolute pressure measurements in the combustion chamber only when the piston is in a position corresponding to the bottom dead center. For this configuration, the volume of said chamber is maximum. Advantageously, each first sensor is a piezoelectric sensor. Advantageously, each second sensor is a piezoresistive sensor. The subject of the invention is a method for determining the absolute pressure in a cylinder of a heat engine on a complete engine cycle, from a device according to the invention. The main characteristic of a determination method according to the invention is that it comprises the following steps: a step of measuring the relative pressure in the combustion chamber during a complete engine cycle, a step of measuring the pressure in the combustion chamber during the phases of the engine cycle for which the volume of said chamber tends towards a maximum value, a step of shifting of the curve representative of the measurements of the relative pressure in the combustion chamber during a motor cycle, of in such a way as to make the values of the relative pressure measured by the first sensor coincide with the values of the absolute pressure measured with the second sensor on the phases of the motor cycle for which the two types of measurements are possible. In this way, the measurement of the absolute pressure in the combustion chamber by means of the second sensor when the volume of said chamber tends to a maximum value, serves as a reference point to match the measurement of the relative pressure by the first one. sensor for the same volume of said chamber. The curve of the variation of the relative pressure over a whole engine cycle is thus shifted, the resulting curve being perfectly representative of the variation of the absolute pressure in the combustion chamber during an entire engine cycle. A device for determining the absolute pressure in a combustion chamber of a heat engine according to the invention has the advantage of being simple to implement while remaining small in size. It also has the advantage of offering reliable and accurate measurements by means of sensors that have been extensively tested and conveniently positioned in an engine cylinder. It finally has the advantage of being able to be arranged in any type of heat engine, having at least one cylinder, and whatever the size and geometry of said cylinder. The following is a detailed description of a preferred embodiment of a device according to the invention and the associated method with reference to FIGS. 1 to 4. FIG. 1 is a view in axial section of FIG. a cylinder of a heat engine in which is mounted a device according to the invention, Figure 2 is an example of a curve illustrating the variation of the relative pressure in a combustion chamber according to the position of the piston, Figure 3 is an example of a curve illustrating the variation of the absolute pressure measured in a combustion chamber as a function of the position of the piston, the volume of said chamber tending towards a maximum value, FIG. 4 is an example of three curves illustrating the variation of the relative pressure in a combustion chamber according to the position of the piston, the absolute pressure measured in a combustion chamber when its volume tends to a maximum value, as well as the absolute pressure ue according to the position of said piston. With reference to FIG. 1, a heat engine 1, for example a motor vehicle engine, comprises at least one cylinder 2 delimited by a hollow cylindrical wall 3 and in which is able to slide a piston 4 connected to a crankshaft by means of The sliding piston 4 and the wall 3 of the cylinder 2 delimit a combustion chamber 6, the volume of which varies according to the position of the piston 4 in the cylinder 2. During a motor cycle, the piston 4 can move between a first extreme position corresponding to the bottom dead point (PMB) and for which the volume of the chamber 6 is maximum, and a second extreme position corresponding to the top dead center (TDC) and for which the volume of said chamber 6 is minimal. A device according to the invention for determining the absolute pressure in a combustion chamber 6 of a heat engine during an entire engine cycle comprises at least a first piezoelectric sensor capable of carrying out measurements. pressure beyond 250bar and at least a second sensor 7 piezoresistive type. Each first sensor (not shown in the figure) is located in a cylinder head of the engine 1 and makes it possible to measure the relative pressure in the combustion chamber 6 during an entire engine cycle.

FIG. 2 illustrates an example of the variation of the relative pressure, measured by the first sensor in a combustion chamber 6 during a motor cycle, as a function of the position of the piston 4 in the cylinder 2, translated into crankshaft angle. It can be seen in this example that the maximum pressure in the chamber 6 can reach up to about 160bars.

The second sensor 7 is implanted in the cylinder 2 near the position of the piston 4 corresponding to the PMB, that is to say the position of the piston 4 for which the volume of the combustion chamber 6 tends towards a maximum value and therefore for which the pressure inside said chamber 6 tends to a minimum value. In this way, when the piston 4 is in a position corresponding to the PMB, it allows the second sensor 7 to make absolute pressure measurements in the combustion chamber 6, and, as soon as it moves from this position to to reach a position corresponding to the PMH, it occults virtually instantaneously said second sensor 7 by preventing it from making absolute pressure measurements in said chamber 6. With such a mounting configuration, the second sensor 7 can only perform measurements when the pressure in the chamber 6 is low and therefore not likely to damage said sensor 7, since the piston 4 is interposed by protecting it. FIG. 3 illustrates an example of the variation of the absolute pressure, measured by the second sensor 7 in a combustion chamber 6 when the position of the piston 4 in the cylinder 2 varies around its end position corresponding to the PMB. The pressure levels reached in the chamber 6 around this extreme position are lower and only rise to a few bars.

Referring to FIG. 4, a device according to the invention makes it possible to carry out a method for determining the absolute pressure in a combustion chamber 6 of a heat engine 1 during a complete engine cycle, said method comprising the three stages major: a step of measuring the relative pressure in the combustion chamber 6 during a complete motor cycle by means of the first piezoelectric sensor, the variation of this pressure during said cycle being partially represented by the curve 8 on the diagram, a step measuring the absolute pressure in the combustion chamber 6 by means of the second piezoresistive sensor 7 when the piston 4 is in the vicinity of its end position corresponding to the PMB, the variation of this pressure being represented by the curve 9 in the diagram, a shift step of the overall curve 8 representative of the variation of the relative pressure in the combustion chamber 6 su r a complete motor cycle, to make coincide the values of said relative pressure measured by the first sensor and the values of the absolute pressure measured by the second sensor 7 during the same phase of said motor cycle, said overall curve thus shifted giving the variation absolute pressure in the combustion chamber 6 over the entire engine cycle. In this way, the principle of such a method consists in assigning an absolute character to the measurements of the relative pressure obtained in the combustion chamber 6 with the first sensor on a complete motor cycle, by setting the curve representative of these measurements on the a few reference points obtained in terms of absolute pressure with the second sensor 7. It should be noted that the value of the absolute pressure measured in the combustion chamber 6 by the second sensor 7 is less than the relative pressure measured with the first sensor in said chamber 6 during the same phase of the engine cycle, since the relative pressure does not include the pressure drops or acoustic phenomena.

Claims (7)

REVENDICATIONS1. Device for determining the absolute pressure in a cylinder (2) of a heat engine (1) with a cylinder head, said cylinder (2) comprising a piston (4) movable, able to define a combustion chamber (6) of variable volume, said device comprising at least a first sensor implanted in said cylinder head for measuring a relative pressure in said combustion chamber (6) during an engine cycle, characterized in that it comprises at least a second sensor (7) of pressure, whose position in the cylinder (2) allows a measurement of the absolute pressure in the combustion chamber (6) only when the volume of said chamber (6) tends to a maximum value, and in that the measurements of the pressure obtained with each first sensor and with each second sensor (7) are combined to determine the absolute pressure in the combustion chamber (6) during a complete engine cycle. 2. Determination device according to claim 1, characterized in that it comprises a single first sensor and a single second sensor (6) for each combustion chamber (6). 3. Determination device according to any one of claims 1 or 2, characterized in that the second sensor (7) is located in a wall (3) delimiting the combustion chamber (6), so that it can not take measurements of the absolute pressure only after the withdrawal of the piston (4), when the volume of said chamber (6) tends towards a maximum value. 4. Determination device according to claim 3, characterized in that the second sensor (4) is placed near the position of the piston (4) at low dead point. 5. Determination device according to any one of claims 1 to 4, characterized in that each first sensor is a piezoelectric sensor. 6. Determination device according to any one of claims 1 to 5, characterized in that each second sensor (4) is a piezoresistive sensor. 7. A method for determining the absolute pressure in a cylinder (2) of a heat engine (1) on a complete engine cycle from a device according to any one of claims 1 to 6, characterized in that it comprises the following steps: - a step of measuring the relative pressure in the combustion chamber (6) during a complete engine cycle, a step of measuring the absolute pressure in the combustion chamber (6) during the phases of the engine cycle for which the volume of said chamber (6) tends to a maximum value, a step of shifting the curve representative of the measurements of the relative pressure in the combustion chamber (6) during a motor cycle, so as to coincide the values of the relative pressure measured by the first sensor with the absolute pressure values measured with the second sensor (7) on the phases of the motor cycle for which both types of measurements are possible.