FR2752617A1 - Gas flow visualisation device for combustion chamber of car engine - Google Patents

Abstract

The device (3) includes two electrodes (32) inserted in the combustion chamber (20) of a car engine (10). The electrodes are connected to a high voltage pulse generator (36) so that electrical discharge arcs are generated between the electrodes. The ionised gas between the electrodes generates a plasma flow which is observed with a camera (38) and an image acquisition device (40).

Description

 The invention relates to a method of visualizing a gas flow, in particular allowing the estimation of the speed of the flow.

 The invention also relates to the application of such a method to the visualization of a gas flow in a combustion chamber of an internal combustion engine of a motor vehicle.

 There are numerous methods which make it possible to obtain information relating to a gas flow inside an enclosure. However, most of the known methods only allow local velocity of the flow to be obtained in a very punctual manner, without always providing information as to the orientation of this local velocity.

 There are also methods which make it possible to more precisely determine a field of velocity of the flow inside the enclosure, but these generally call for devices which are complex to implement.

 It is particularly difficult to determine the circulation of fluid inside a combustion chamber of a motor vehicle engine. Indeed, if we want the measurement to be truly representative, it is necessary to operate on a fully equipped engine cylinder, that is to say in which move both the piston and the intake and exhaust so as to recreate the flow prevailing inside the combustion chamber in normal use.

 It is therefore necessary that the device which makes it possible to measure these flows disturb as little as possible the operation of the various mobile elements and the flow proper.

 As we know, in internal combustion engines, it is particularly important to control well, and therefore to know well, the flow conditions of the fuel mixture just before the combustion of the mixture begins, either spontaneously in an engine diesel, either in a controlled manner by a spark.

 Indeed, the nature of the flow depends on the quality of the mixing of the fuel mixture and therefore the quality of the propagation of the flame at the first moments of combustion.

 These parameters are particularly important for increasing the efficiency of the engine and for reducing the emission of pollutants.

 The object of the invention is therefore to propose a method making it possible in particular to estimate the speed of the gas flow by visualization which is of the smallest possible size and of the simplest possible implementation.

 To this end, the invention provides a method of visualizing a gas flow, characterized in that it consists in creating a channel of ionized gas particles by causing the formation of a first electric arc which propagates substantially along an axis connecting the ends of two electrodes which extend inside the enclosure, then to form at least a second electric arc, before the ionized particles have returned to their initial stable state, so that they form a preferential propagation path for the second arc, and in that there are provided means for acquiring a series of images of the electric arcs which make it possible to determine the displacement of the ionized particles between the formation of each of the arcs .

According to other features of the invention
- the first ionization electric arc of the particles is followed by a series of arcs offset each by a time interval less than the time of return to the initial stable state of the ionized particles
- two series of image acquisition are provided corresponding to two different orientations relative to the enclosure of the axis connecting the ends of the electrodes
- It is applied to the study of the gas flow in a combustion chamber of an internal combustion engine of a motor vehicle, and in that the engine is driven in rotation by an annex device
- the electrodes are carried by a support which is arranged in place of a spark plug or glow plug so that the electrodes penetrate inside the combustion chamber
- the image acquisition means are arranged behind a porthole which is arranged in place of a spark or glow plug
the porthole and the electrodes are carried by the same support which is arranged in place of a spark or glow plug, and the axis of the field of vision of image acquisition means extends between the two electrodes.

Other characteristics and advantages of the invention will appear on reading the following detailed description for the understanding of which reference will be made to the accompanying drawings in which
- Figure 1 is a partial schematic sectional view of an internal combustion engine of a motor vehicle
- Figure 2 is a schematic view in longitudinal section of a device allowing the implementation of the method according to the invention for studying the gas flow inside the combustion chamber of the engine of Figure I
- Figure 3 is a view in the direction F of Figure 1 illustrating the arrangement of the device of Figure 2 in the combustion chamber of Figure I
- Figure 4 is a schematic view illustrating the assembly of the device allowing the implementation of the method according to the invention; ; and
- Figures 5, 6 and 7 are schematic representations which illustrate three displays obtained using the method according to the invention and corresponding to three different types of flows.

 FIG. 1 shows an internal combustion engine 10 of a motor vehicle comprising in particular a cylinder head 12 and an engine block 14 between which a cylinder head gasket is arranged 16. A cylinder 18 of axis Al is arranged in the engine block 14 while a combustion chamber 20, formed in the cylinder head 12, covers the upper end of the cylinder 18.

 In known manner, supply 22 and exhaust 24 conduits are formed in the cylinder head 12 and open into the combustion chamber 20 through valves 26, 28 with controlled opening.

 In the exemplary embodiment which is represented in FIG. 1, the internal combustion engine 10 is an engine of the spark-ignition type so that there is provided in the cylinder head 12 a threaded orifice which allows the mounting of a spark plug 30.

To determine the gas circulation inside the combustion chamber 20 of the engine in operation,
The use of the method according to the invention, which will be described below, requires that the motor be rotated not by its own means but by an additional device. One can for example drive the output shaft of the motor in rotation, which causes the reciprocating movement of the pistons in the cylinders and the opening and closing movements of the valves 26, 28.

 FIGS. 2 and 4 show the device 31 which makes it possible to implement the method according to the invention.

 The method according to the invention requires installing in the enclosure in which it is desired to determine the characteristics of a flow, that is to say in this case in the combustion chamber 20, two electrodes 32 whose ends lower 34 are arranged inside the enclosure. The electrodes 32 are connected to a pulsed high voltage generator 36 which makes it possible to cause the triggering between the two ends 34 of the electrodes 32 of an electric arc or spark.

 The method firstly comprises the step of causing the propagation of a first spark El between the two electrodes 32.

 This first spark El is caused to form in a relatively homogeneous gaseous medium from the point of view of its electrical characteristics so that it forms along the shortest path between the two ends 34 of the electrodes 32, that is to say say substantially along an axis XX connecting the ends 34 of the electrodes 32.

 Due to the passage of electrical energy between the electrodes 32, there is created between the two ends 34 thereof a channel in which the gaseous particles are ionized to form a plasma. These particles are therefore in an unstable physical state.

 If the ends 34 of the electrodes 32 are observed, the passage of the first electric arc therefore results in a very intense strip of light substantially rectilinear along the axis X-X separating the two electrodes.

 According to the method of the invention, the high voltage generator 36 is then controlled to cause the propagation of a second spark E2 between the electrodes 32, before the ionized particles of the plasma channel created by the first spark El have had time to return to their stable state.

 In this way, these ionized particles form, for the second spark E2, a preferential path from one electrode 32 to the other.

 However, these ionized particles 32 are subjected to a displacement due to the gas flow inside the enclosure. In the time interval between the two sparks, each of these particles will therefore have been displaced by a certain distance, depending on the direction and intensity of the local velocity of the flow.

 In this way, the second spark propagates no longer in a straight line along the axis X-X joining the two electrodes 32, but along a channel whose geometry is controlled by the gas flow.

 This second spark is itself reflected by a light band then representing the shape of the channel of the ionized particles, after the deformation thereof caused by the flow.

 In this way, it suffices to provide a camera 38 and an image acquisition device 40 which make it possible to compare the configuration of the ionized channel during the passage of the first spark and during the passage of the second spark, to deduce therefrom displacement of the particles in the time interval separating the passage of the two sparks.

 The device 31 which is shown more particularly in FIGS. 2 and 4 makes it possible to implement this method in a simple and efficient manner in an internal combustion engine.

 To this end, the electrodes 32 are carried by a support 42 intended to be mounted on the engine, in place of the spark plug 30. The support 32 therefore comprises a threaded lower end 44 which is axially traversed by the electrodes 32 whose lower ends 34 protrude beyond the lower end 44 of the support 42, inside the combustion chamber 20.

 Advantageously, the camera 38 and the image acquisition device 40 are arranged outside the engine and are intended to observe the sparks created between the two electrodes 32 through a window provided in the support 42 of the electrodes 32 .

 To this end, the support 42 has a central recess 46 closed at its lower end by a translucent window 48, for example made of quartz.

 In the embodiment shown in FIG. 2, the window 48 is arranged inside the lower end 44 of the support 42 and it is crossed by the two electrodes 32.

 Thus, by arranging the camera 38 axially above the window 48, it will be capable of capturing the image of an electric spark created inside the combustion chamber 20 between the two electrodes 32.

 Preferably, the camera 38 is connected to an image acquisition, storage, processing and analysis device 40 which makes it possible for example to obtain, on the same representation, the image of the passage of the first spark and that of from the passage of the second spark to directly deduce therefrom the relative displacement of the ionized particles between the instants of passage of these two sparks.

 FIGS. 5 to 7 show schematically three examples of such types of representations in which the images of the passage, not of two sparks but of four successive sparks, are superimposed, each shifted in time by a duration less than the time it takes for the particles to return to their stable electrical state.

 Thus, in the three cases, the passage of the first spark El which extends in a substantially rectilinear fashion along the axis XX of the electrodes 32 is observed. The traces of successive sparks E2, E3, E4 have also been shown in dashed lines .

 The example shown in FIG. 5 illustrates the type of representation that is likely to be obtained when the gas flow between the two electrodes is a uniform flow substantially perpendicular to the axis XX connecting the electrodes 32, flowing from right to left considering figure 5.

 In the example shown in Figure 6, there is a representation of the sparks El, E2, E3 and E4 when the gas flow is uniformly in an oblique direction relative to the axis X-X connecting the electrodes.

 In FIG. 7, a representation is illustrated which can be obtained when the gas flow in the studied area is disturbed. In this example, it can be seen that, at the level of an electrode 32, shown in the lower position in FIG. 7, the flow is substantially uniform and perpendicular to the axis X-X connecting the two electrodes 32.

 On the contrary, the flow at the level of the electrode 32 shown above in FIG. 7 has undergone a reversal of its velocity field between the passage of the second spark E2 and the third spark E3.

 As can be seen in these FIGS. 5 to 7, the method according to the invention allows qualitative information to be obtained almost immediately as to the gas flow between the two electrodes 32.

 Quantitative information on flow velocities is also available by estimating the displacement, at different points, of the ionized channel between each of the sparks.

Of course, this method gives the best results when the flow is substantially perpendicular to the axis.
XX connecting the two electrodes 32. Also, to have a more complete and more precise result, it is preferable, for the same flow, to carry out two series of image acquisitions by changing the orientation of the XX connecting axis the electrodes 32 with respect to the geometry of the combustion chamber 20. Thus, two measurement series will preferably be carried out by pivoting the axis XX by 90 ".

 The method according to the invention has the advantage of being able to be adapted to any combustion engine with positive ignition without significant modifications thereof.

 The principle of the method according to the invention can even be applied in the case of spontaneous ignition engines, called diesel, by arranging for example the support 42 in place of a glow plug.

Claims (7)

 characterized in that it consists in creating a channel of ionized gaseous particles by causing the formation of a first electric arc (El) which propagates substantially along an axis (XX) connecting the ends (34) of two electrodes (32) which extend inside the enclosure (20), then form at least a second electric arc (E2), before the ionized particles have returned to their initial stable state, so that they form a preferential propagation path for the second arc (E2), and in that provision is made for acquisition means (38, 40) of a series of images of the electric arcs which make it possible to determine the displacement of the particles ionized between the formation of each of the arcs.  1. Method for displaying a gas flow inside an enclosure (20),  2. Method according to claim 1, characterized in that the first electric arc (El) of ionization of the particles is followed by a series of arcs (E2, E3, E4) each shifted by a time interval less than time to return to the initial stable state of the ionized particles.  3. Method according to one of claims 1 or 2, characterized in that two series of image acquisition are provided corresponding to two different orientations relative to the enclosure (20) of the axis (XX) connecting the ends (34) of the electrodes (32).  4. Method according to any one of the preceding claims, characterized in that it is applied to the study of the gas flow in a combustion chamber (20) of an internal combustion engine (10) of a motor vehicle , and in that the motor (10) is rotated by an auxiliary device.  5. Method according to claim 4, characterized in that the electrodes (32) are carried by a support (42) which is arranged in place of a spark plug (30) or preheating so that the electrodes ( 32) enter the interior of the combustion chamber (20).  6. Method according to one of claims 4 or 5, characterized in that the image acquisition means (38, 40) are arranged behind a window (48) which is arranged in place of a candle ignition (30) or preheating.  7. Method according to claim 6 taken in combination with claim 5, characterized in that the window (48) and the electrodes (32) are carried by the same support (42) which is arranged in place of a candle d ignition (30) or preheating, and in that the axis of the field of vision of image acquisition means extends between the two electrodes (32).