Pollutant abatement device of an internal combustion engine and pollutant abatement system comprising the device

Abstract

Device for the abatement of pollutants of an internal combustion engine comprising an external casing in which a DOC and a bypass duct of the DOC is housed to define a bifurcation for the exhaust gases passing through the device, so that a first flow is intended to cross the DOC and a second flow is intended to bypass the DOC, an injector of urea-based reducing agent arranged at or at a point immediately downstream of the bifurcation and an electric heater arranged annularly with respect to the bypass duct and configured to heat the bypass duct and to be passed by the first exhaust gas flow.

Claims

1. A device for an abatement of pollutants produced by an internal combustion engine comprising an external casing in which a diesel oxidation catalyst (DOC) and a bypass duct of the DOC is housed to define a bifurcation for the exhaust gases passing through the device, so that a first flow of the exhausted gases is intended to pass the DOC and a second flow of the exhausted gases is intended to bypass the DOC, a first injector of an urea-based reducing agent arranged at or at a point immediately downstream of the bifurcation for injecting the urea-based reducing agent in the second flow and an electric heater arranged annularly with respect to the bypass duct and configured to heat the bypass duct and to be passed by the first flow.

2. The device according to claim 1, wherein a rotational solid is defined according to a development axis and the bypass duct is disposed spaced apart from the external casing and is arranged in a coaxial position with the development axis.

3. The device according to claim 1, further comprising an inlet duct of the exhaust gas, arranged to introduce the exhausted gas in an incident manner with respect to a direction identified by the bypass duct and wherein the first injector of the urea-based reducing agent is arranged coaxially with respect to the bypass duct at the bifurcation.

4. The device according to claim 1, wherein the electric heater is configured to heat primarily the bypass duct and secondarily the first flow of the exhausted gases.

5. The device according to claim 1, wherein the electric heater, according to a cross-section of the electric heater, comprises straight and radial fins or folded fins, each in the form of an S, or defines a matrix.

6. An exhaust gas post-treatment system comprising the device according to claim 1, arranged to be a first abatement device encountered by the exhausted gasses.

7. The exhaust gas post-treatment system according to claim 6, further comprising a second abatement device, placed immediately downstream of the first abatement device and comprising a selective catalyst (SCR) and an ammonia abatement (CUC) and a third abatement device, placed immediately downstream of the second abatement device and comprising a DOC and a particle filter (DPF).

8. The exhaust gas post-treatment system according to claim 7, further comprising a fourth abatement device, arranged downstream of the third abatement device and comprising a second injector of the urea-based reducing agent arranged immediately upstream of the fourth abatement device.

9. The exhaust gas post-treatment system according to claim 6, further comprising a second abatement device, arranged immediately downstream of the first abatement device and comprising an SCR on filter (SCRoF).

10. The exhaust gas post-treatment system according to claim 9, further comprising a fourth abatement device, arranged downstream of the second abatement device and comprising a second injector of the urea-based reducing agent arranged immediately upstream of the fourth abatement device.

11. The exhaust gas post-treatment system according to claim 8, wherein the first injector of the urea-based reducing agent is configured to be activated at cold starting and maintained active as long as a temperature of the fourth abatement device is below a first predetermined temperature threshold and wherein the second injector of the urea-based reducing agent is configured to be activated when the temperature of the fourth abatement device exceeds a second predetermined temperature threshold lower than the first predetermined temperature threshold.

12. The exhaust gas post-treatment system according to claim 10, wherein the first injector of the urea-based reducing agent is configured to be activated at cold starting and maintained active as long as a temperature of the fourth abatement device is below a first predetermined temperature threshold and wherein the second injector of the urea-based reducing agent is configured to be activated when the temperature of the fourth abatement device exceeds a second predetermined temperature threshold lower than the first predetermined temperature threshold.

13. A propulsion system comprising a diesel internal combustion engine comprising the device according to claim 1, operatively connected to an exhaust manifold of the diesel internal combustion engine.

14. A propulsion system comprising a diesel internal combustion engine comprising the exhaust gas post-treatment system according to claim 6, operatively connected to an exhaust manifold of the diesel internal combustion engine.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further objects and advantages of the present invention will become clear from the following detailed description of an example of its embodiment (and its variants) and from the attached drawings given purely by way of non-limiting explanation, in which:

(2) FIG. 1 shows a first diagram comprising an internal combustion engine and the exhaust gas abatement device according to a first variant of the present invention;

(3) FIG. 2 shows a further preferred variant of the present invention;

(4) FIG. 3 shows a further preferred variant of the present invention;

(5) FIGS. 4-7 show construction details of an element of the device according to FIGS. 1-3.

(6) The same reference numbers and letters in the figures identify the same elements or components or functions.

(7) It should also be noted that the terms first, second, third, upper, lower and the like can be used here to distinguish various elements. These terms do not imply a spatial, sequential or hierarchical order for the modified elements unless specifically indicated or inferred from the text.

(8) The elements and features illustrated in the various preferred embodiments, including the drawings, can be combined with each other without however departing from the scope of this application as described below.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(9) FIG. 1 shows an example of a diesel cycle internal combustion engine E, hereinafter simply engine E, comprising an intake manifold IP and an exhaust manifold OP.

(10) Preferably, the engine E is supercharged with a turbocharger T comprising a turbine connected to the exhaust manifold and a compressor, driven in rotation by the turbine, arranged on the intake manifold.

(11) The engine can be equipped with an EGR valve for exhaust gas recirculation.

(12) According to the present invention, the exhaust gas abatement system comprises a first device indicated as ATS1 arranged as the first component of the ATS that the exhaust gas meets in the usual outflow from the engine E to the external environment.

(13) The first device ATS1 comprising at least one DOC and an exhaust gas bypass duct BP to define a bifurcation for the exhaust gases, so that a first flow F1 is intended to pass the DOC matrix and a second flow F2 bypasses the DOC matrix.

(14) The first and second flow mix together in the terminal part of the device before leaving it to enter a possible second ATS2 device, etc.

(15) The injector J of the urea-based reducing agent is arranged at or at a point immediately downstream of the bifurcation.

(16) Furthermore, the bypass duct is inserted in an electric heater H configured to heat the bypass duct and to be passed by the first flow F1 of exhaust gas.

(17) In this way, the heater performs the double function of heating the bypass duct and indirectly the second exhaust gas flow F2 and directly the first exhaust gas flow F1.

(18) The first ATS1 device is preferably designed as a rotational solid in which the BP bypass duct is arranged well away from the perimeter walls of the envelope and is preferably arranged coaxially with respect to the rotation axis of the entire device.

(19) The first device ATS1 comprises an inlet duct IN of the exhausted gas, arranged to enter the exhausted gas in an incident manner with respect to the aforementioned axial direction and the reducing agent injector is arranged coaxially with respect to the bypass duct at the bifurcation.

(20) From the figures it can be seen that the first device ATS1 comprises a sort of bell which closes a base of the rotational solid and in the top of the bell there is the injector J of the urea-based reducing agent, while in a lateral position of the bell there is formed the exhaust gas inlet duct IN.

(21) The injector tip is arranged so that the urea-based reducing agent spray is completely injected into the second flow F2 of exhausted gas.

(22) The bypass duct comprises a first proximal portion to the injector J and a second proximal portion with the terminal portion OUT of the ATS1 device.

(23) The first portion of the bypass duct is inserted into and in contact with an electric heater H. This is arranged primarily to heat the bypass duct and secondly to heat the first exhaust gas stream.

(24) FIGS. 4-7 show a cross-sectional view of the heater H according to different embodiment examples.

(25) For example, FIGS. 4 and 5 show a matrix heater, while solutions 6 and 7 show a finned heater, in particular in FIG. 6 the straight fins are radial, while in FIG. 7 the fins are folded, each to form an S.

(26) FIG. 1 shows further ATS2 and ATS3 components arranged in succession downstream of the first ATS1 device.

(27) The second ATS2 device placed immediately downstream of the first ATS1 device includes an SCR and a CUC to exploit the preheated gas mixture containing the right proportions of NH3, NO and NO.sub.2 in order to maximize the conversion efficiency of the SCR itself, during the first stages of engine start-up.

(28) Downstream of the SCR and CUC there is a DOC/DPF loaded with platinum and/or palladium capable of retaining the solid particles per se known.

(29) According to FIG. 2, which represents a variant of the diagram of FIG. 1, downstream of the third device ATS3 there is a fourth device ATS4 comprising an SCR followed by a CUC and immediately upstream of the fourth device ATS4 there is a second injector J2 of the urea-based reducing agent.

(30) Preferably, the second injector J2 and consequently the fourth device ATS4 are activated after sufficient heating of the same fourth component ATS4.

(31) Preferably, when the fourth component is fully operational, the first injector J of urea-based reducing agent is deactivated, so as to favour the spontaneous regeneration of the DPF contained in the third ATS3 device due to the NO.sub.2 effect.

(32) FIG. 3 shows another preferred variant of the invention in which there are additional ATS23 and ATS4 components arranged in succession downstream of the first ATS1 device.

(33) The second device ATS23 does not coincide with the second device ATS2 of the previous figures, although arranged, as ATS2, immediately downstream of the first device ATS1. The ATS23 device includes a component known as SCRoF, from the acronym SCR on Filter, which is an SCR having filtering capacity for the particulate contained in the exhaust gases.

(34) In this way it is possible to exploit the same component both to maximize the conversion efficiency of the SCR by the mixture of preheated gas and containing the right proportions of NH3, NO and NO.sub.2 and to filter the solid particles of particulate matter.

(35) Downstream of the SCRoF there is a third device corresponding to the fourth ATS4 in FIG. 2. It includes an SCR and a CUC, also equipped with a second injector J2 of urea-based reducing agent. Also in this case the activation of the second injector is expected when the temperature of ATS4 is sufficient.

(36) Also in this case, it is advantageous to deactivate the first injector when the ATS4 component is completely efficient, in order to favour the spontaneous regeneration of carbon residues in the SCRoF filter by NO.sub.2.

(37) This means that a condition of simultaneous operation of both injectors can be foreseen.

(38) Therefore, the first injector J of urea-based reducing agent is configured to activate at cold start and be kept active until the temperature of the fourth device ATS4 is below a first predetermined temperature threshold and in which the second injector J2 of urea-based reducing agent is configured to activate when the temperature of the fourth ATS4 device exceeds a second predetermined temperature threshold lower than the first temperature threshold.

(39) Implementation variants of the described non-limiting example are possible, without however departing from the scope of protection of the present invention, including all the equivalent embodiments for a person skilled in the art, to the content of the claims.

(40) From the above description, the person skilled in the art is able to realize the object of the invention without introducing further construction details.