FR2880063A1 - Particle filter for motor vehicle, has porous body presenting thermal mass whose value varies along thermal mass longitudinal gradient which is proportional to regeneration temperature longitudinal gradient - Google Patents

Abstract

The filter (16) has a porous body (22) that is longitudinally intercalated between an inlet side (18) and an outlet side (24) in order to be traversed by an exhaust gas (G). The body is constituted by a longitudinal pile of blocks or fabricated in a single block. The body presents a thermal mass whose value varies along a thermal mass longitudinal gradient which is proportional to regeneration temperature longitudinal gradient.

Description

"Particulate filter having a porous body whose mass

  The invention relates to a particulate filter which is intended to be arranged in an exhaust pipe of a combustion engine, in particular of a motor vehicle.

  The invention relates more particularly to a particulate filter intended to be arranged in an exhaust pipe of a combustion engine, in particular of an automobile vehicle, comprising: an upstream inlet face of the exhaust gases comprising particles in suspension ; a downstream exhaust face of the filtered exhaust gases; a porous body which is inserted longitudinally between the inlet face and the outlet face so as to be traversed by the exhaust gases, and which retains particles contained in the exhaust gases, the particulate filter being capable of during a regeneration phase, from a fouled state in which particles are retained in the porous body, to a regenerated state in which the retained particles are removed by combustion, the combustion of the retained particles heating the porous body according to a longitudinal gradient of regeneration temperatures.

  Diesel and petrol engines emit polluting substances such as unburnt hydrocarbons, nitrogen oxides, carbon oxides and, in the case of diesel engines, particles. We know that one of the major concerns of equipment manufacturers and motor vehicle manufacturers is the reduction of pollution resulting from the operation of these engines.

  Various technical solutions have therefore been considered in an attempt to reduce the pollution levels of these engines.

  The treatment of particles emitted by current diesel engines is possible by introducing into the exhaust line of these engines a particle filter as it has already been proposed in the state of the art. These are often adapted to trap the particles or "soot" that are contained in suspension in the exhaust gas of these engines and to burn them during a regeneration phase of the filter.

  Different regeneration strategies are available in the literature, referring for example to the post-fuel injection to reach the soot combustion temperature, or for example to additional heating means Io placed upstream of the particulate filter.

  The regeneration phase starts when the upstream end section of the particulate filter is heated, by the exhaust gas, by a heating system, or by the oxidation of trapped reducing elements, beyond the temperature of the combustion of soot.

  The combustion of particles retained locally in the upstream end section produces a so-called combustion heat. This heat of combustion contributes to raising the local temperature of the upstream face of the porous body to a so-called local regeneration temperature which is greater than or equal to the soot combustion temperature.

  The sum of the regeneration heat, provided by the exhaust gas, the heating system or the oxidation of reducing elements, and the heat of combustion is transmitted, for example by conduction, to a first intermediate section directly downstream of the particulate filter. The local temperature of the first downstream intermediate portion of the porous body then exceeds the soot combustion temperature, causing the combustion of the locally retained particles. This new particle combustion phenomenon provides an additional amount of heat of combustion which raises the temperature of the first downstream intermediate section to a local regeneration temperature which is greater than the local regeneration temperature of the upstream end section of the filter. particles.

  The sum of the regeneration heat, the heat of combustion and the additional heat of combustion is transmitted to a second intermediate section downstream of the particulate filter. The particle combustion phenomenon is reproduced, raising the local temperature of the second downstream intermediate section to a local regeneration temperature which is higher than the local regeneration temperature of the first downstream section.

  The heat flow thus propagates longitudinally by increasing continuously, for example by conduction, to the downstream end portion of the porous body.

  Thus, the porous body is heated according to a longitudinal gradient of regeneration temperatures. The regeneration temperature therefore increases gradually, continuously, moving along the porous body from the upstream face to the downstream face of the particulate filter.

  The porous body must be designed to withstand the thermal shock caused by the temperature rise during regeneration. To increase the thermal shock resistance of the porous body, it is known in particular to increase its thermal mass.

  In known manner, the physical properties of the porous body, such as its thermal mass, also called heat capacity, or its porosity, are homogeneous along the particle filter.

  The overall thermal mass of the porous body is therefore adjusted as a function of the maximum regeneration temperature that appears in the particulate filter, that is to say the regeneration temperature of the downstream end portion of the porous body.

  In order to increase the thermal mass of the porous body, numerous solutions are already known such as reducing the porosity, increasing the density of the porous body, and decreasing the pore size. However, any other lever for producing an evolution of the thermal mass of the particle filter in its length is possible.

  However, the ability of the porous body to accumulate particles is proportional to its porosity.

  By decreasing the porosity all along the porous body to adjust the thermal mass of the porous body to the maximum regeneration temperature, thus decreases the capacity of accumulation.

  In order to solve this problem and to optimize the particle accumulation capacity of the porous body, the invention proposes a particulate filter of the type described above, characterized in that the thermal mass of the porous body is not homogeneous according to the longitudinal direction, its value varying according to a longitudinal gradient of thermal mass which is a function of the longitudinal gradient of regeneration temperatures.

  According to other characteristics of the invention: the longitudinal gradient of thermal mass is proportional to the longitudinal gradient of regeneration temperatures; the thermal mass of the porous body increases gradually from the upstream face to the downstream face; the thermal mass of the porous body increases continuously along the porous body; the porosity of the porous body is not homogeneous in the longitudinal direction and its value varies according to a longitudinal gradient of porosity which is inversely proportional to the thermal mass gradient; the porosity of the porous body gradually decreases from the front face to the back face; the porosity decreases continuously along the porous body; the porous body is made in a single block; - The porous body is formed by a longitudinal stack of separate blocks.

  Other characteristics and advantages will become apparent upon reading the detailed description which follows for the understanding of which reference will be made to the appended drawings in which: FIG. 1 schematically represents an exhaust duct in which a filter is arranged; with particles according to the invention; FIG. 2 is a graph comprising two curves which respectively represent the local porosity and the local thermal mass of a section of the porous body as a function of the longitudinal distance of said section relative to the inlet face of the particle filter.

  A direction of flow of the upstream to downstream fluids which is oriented longitudinally from left to right will be adopted in the remainder of the description with reference to FIG.

  FIG. 1 shows an exhaust duct 10 of a combustion engine 12, for example a diesel engine of a motor vehicle. The exhaust duct 12 is intended to drive the exhaust gas "G" produced by the engine 12 to the atmosphere via a discharge end 14.

  A particulate filter 16 is arranged in the exhaust pipe 10. It has an upstream exhaust gas inlet face 18 "G" and a downstream exhaust gas exit face 20 "G".

  A porous body 22 is inserted longitudinally between the inlet face 18 and the outlet face 24 so as to be traversed by the exhaust gas "G".

  The porous body 22 can be made by a longitudinal stack of several blocks or it can be made in a single block, for example ceramic, metal or composite material.

  The porous body 22 is intended to retain particles "P", or soot, which are contained in suspension in the exhaust gas "G" at their output from the engine 12. After passing through the porous body 22, the exhaust gases "G" thus filtered are then released into the atmosphere via the exhaust duct 10 via the discharge end 14.

  When the porous body 22 is in a fouled state, or even obstructed, by the accumulation of particles "P", the flow of the exhaust gas "G" in the exhaust pipe 10 undergoes pressure drops. The operation of the motor 12 may then be affected.

  It is therefore known to subject a regeneration phase to the particulate filter 16 to remove the retained particles. During this regeneration phase, the particulate filter 16 moves from the fouled state in which particles "P" are retained in the porous body 22, to a regenerated state in which the retained particles are removed by combustion.

  The combustion of the particles "P" is for example spontaneously triggered when the porous body 22 is heated beyond the combustion temperature of the soot Tc, for example beyond 600 C. Thus, the exhaust gas "G" can for example be heated downstream of the particulate filter 16. The porous body 22 is heated by conduction on contact with the exhaust gas "G".

  The inlet face 18 of the particulate filter 16 being the first to come into contact with the exhaust gas "G", it is through this face that the regeneration phase begins.

  As explained above, the combustion of the "P" particles retained heats the porous body 22 according to a longitudinal "GTR" gradient of regeneration temperatures. The regeneration temperature here increases continuously from the inlet face 18 to the outlet face 20.

  In order to improve the ability of the particulate filter 16 to retain and / or accumulate the "P" particles without reducing its life, the porous body 22 according to the invention has physical properties that are not homogeneous in the longitudinal direction. .

  Thus, the thermal mass of the porous body 22 is not homogeneous in the longitudinal direction. As shown in FIG. 2, the value of the thermal mass varies according to a longitudinal "GMT" gradient of thermal mass which is proportional to the longitudinal gradient of regeneration temperatures "GTR". In the example shown in Figure 2, the thermal mass gradient "GMT" is linear, the invention however applies to gradients "GMT" that have other forms, such as parabolic gradients.

  In the graph shown in FIG. 2, the abscissa corresponds to the longitudinal distance between any point of the porous body 22 and the inlet face 18. The ordinate represents the value of the thermal mass of said point.

  It can be seen that the thermal mass of the porous body 22 is minimal here at the inlet face 18 and increases continuously to a maximum value which is situated at the outlet face 20.

  This thermal mass gradient "GMT" makes it possible to bring numerous advantages to the particulate filter 16. Thus, the inlet face 18 of the porous body 22 has a thermal inertia lower than that of the outlet face 20. inlet 18 is thus likely to quickly reach the combustion temperature of soot or any other elements trapped in the particulate filter. The initiation of the regeneration phase is therefore also fast.

  The high thermal mass of the outlet face 20, on the other hand, makes it possible to absorb the heat caused by the regeneration phase without causing degradations of the porous body 22 such as cracks or fusions.

  According to another aspect of the invention, the local value of the thermal mass of the porous body 22 is determined in particular by its local porosity. The porosity of the porous body 22 depends in particular on the average pore diameter and the pore density. The local thermal mass of the porous body is inversely proportional to its local porosity.

  In the example shown in FIG. 2, the value of the porosity in the porous body 22 varies according to a longitudinal "GP" gradient of porosity which is inversely proportional to the "GMT" thermal mass gradient.

  With reference to FIG. 2, it can be seen that the porosity of the porous body 22 is maximum here at the inlet face 18 and it decreases continuously to a minimum value which is situated at the level of the exit 20.

  The amount of "P" particles that the porous body is likely to retain is proportional to the pore density of a diameter slightly smaller than the average particle diameter "P". Thus, by designing the porous body 22 in a manner adapted to the local regeneration temperature, the average density of porosity is improved with respect to a porous body which has uniform porosity over its entire length according to the state of the art. The capacity of the particulate filter 16 to retain the particles "P" is thus improved compared to the state of the art.

  By way of example, the longitudinal gradient of regeneration temperatures "GTR" has been set as increasing along the porous body 22. However, it will be understood that this example is not limiting and that the regeneration temperature gradient "GTR" can take other forms for example depending on the heating system used. The shape of the thermal mass gradient "GMT" and the porosity gradient "GP" then depends on the shape of said regeneration temperature gradient "GTR", as previously described and the thermal mass gradients "GMT" and porosity "GP "are not necessarily linear.

  The "GMT" thermal mass gradient of the porous body 22 may also be determined as a function of a gradient of a property influencing the thermal mass of the porous body 22 other than the porosity.

Claims (9)

  Particle filter (16) intended to be arranged in an exhaust pipe (10) of a combustion engine (12), in particular a motor vehicle, comprising s - an upstream face (18) for entering the exhaust gases. exhaust (G) comprising particles (P) in suspension; - a downstream face (20) of exhaust gas outlet (G) filtered; - a porous body (22) which is inserted longitudinally between the inlet face (18) and the outlet face (20) so as to be traversed by the exhaust gas (G), and which retains particles (P ) contained in the exhaust gas (G); the particulate filter (16) being capable of passing during a regeneration phase, from a fouled state in which particles (P) are retained in the porous body (22), to a regenerated state in which the particles ( P) are removed by combustion, the combustion of the retained particles (P) heating the porous body (22) according to a longitudinal gradient of regeneration temperatures (GTR), characterized in that the thermal mass of the porous body (22) is is not homogeneous in the longitudinal direction, its value varying according to a longitudinal gradient of thermal mass (GMT) which is proportional to the longitudinal gradient of regeneration temperatures (GTR).   2. Particle filter (16) according to the preceding claim, characterized in that the longitudinal gradient of thermal mass (GMT) is proportional to the longitudinal gradient of regeneration temperatures (GTR).   3. Particle filter (16) according to any one of the preceding claims, characterized in that the thermal mass of the porous body (22) increases gradually from the upstream face (18) to the downstream face (20).   4. Particle filter (16) according to the preceding claim, characterized in that the thermal mass of the porous body (22) increases continuously along the porous body (22).   5. Particle filter (16) according to any one of the preceding claims, characterized in that the porosity of the porous body (22) is not homogeneous in the longitudinal direction and its value varies according to a longitudinal gradient of porosity (GP ) which is inversely proportional to the thermal mass gradient (GMT).   6. Particulate filter (16) according to the preceding claim, characterized in that the porosity of the porous body (22) decreases gradually from the front to the rear face.   7. Particle filter (16) according to the preceding claim, characterized in that the porosity decreases continuously along the porous body (22).   8. Particle filter according to any one of the preceding claims, characterized in that the porous body (22) is made in a single block.   9. Particle filter according to any one of claims 1 to 7, characterized in that the porous body (22) is formed by a longitudinal stack of separate blocks.