Integrated Automotive Reformer and Catalytic Converter and Method for Reforming Fuel

Abstract

An integrated catalyst reformer is described, including a housing which surrounds and defines at least two individualized and adjacent chambers. The first chamber is intended for the catalytic conversion of exhaust gases from the MCI and at least one second chamber intended for reforming fuel, ethanol or others, and the heat generated in the first chamber is transferred to the second chamber by thermal conduction. The first chamber is connected, upstream, to the exhaust manifold of the MCI from the inlet nozzle and is connected to the exhaust of the vehicle from the outlet nozzle, while the plenum of the first chamber is filled with a catalytic mesh. The second chamber includes a plenum filled with a catalytic mesh; an intake nozzle intended to receive both ambient air and the fuel to be reformed; and an exhaust nozzle, connected upstream of the intake manifold, so as to allow the reformed fuel to be aspirated.

Claims

1. An integrated catalyst reformer, comprising a housing which surrounds and defines two individual and adjacent chambers, the first chamber being intended for the catalytic conversion of exhaust gases from the MCI and the second chamber destined to reform the fuel, and the heat generated in the first chamber is transferred to the second chamber by thermal conduction, the second chamber comprises a plenum filled with a catalytic mesh; an intake nozzle intended to receive both ambient air and the fuel to be reformed; and an exhaust nozzle, connected upstream of the intake manifold, so as to allow the reformed fuel to be aspirated, a fuel injector, arranged upstream of the intake nozzle, to inject the fuel to be reformed into the second chamber, and a thermally insulating cover surrounding, totally or partially, the first chamber and the second chamber.

2. The catalyst reformer, according to claim 1, wherein the first chamber is connected, upstream, to the MCI exhaust collector from the inlet nozzle; be connected to the exhaust of the vehicle from the outlet nozzle; and the plenum of the first chamber is filled with a catalytic mesh.

3. (canceled)

4. (canceled)

5. (canceled)

6. The catalyst reformer, according to claim 1, wherein the first chamber surrounds the second chamber.

7. The catalyst reformer, according to claim 1, wherein the second chamber surrounds the first chamber.

8. The catalyst reformer, according to claim 1, comprising two second chambers, each of the second chambers being laterally disposed with respect to the first chamber.

9. The catalyst reformer, according to claim 8, wherein each of the second chambers comprises a plenum filled with a catalytic mesh; an intake nozzle intended to receive both ambient air and the fuel to be reformed; an exhaust nozzle, connected upstream of the intake manifold; and a fuel injector, arranged upstream of the intake nozzle, to inject the fuel to be reformed into the respective second chamber.

10. A fuel reforming method, of the type to be carried out by an integrated catalyst reformer as defined in claim 1, wherein the step of reforming via catalyst the fuel from the heat generated by the catalytic conversion of the exhaust gases of the MCI and also the heat normally rejected in the exhaust.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] The present invention will be better understood in light of the detailed description of a preferred embodiment, which is supported and illustrated from the attached figures, brought for the mere purpose of illustration and guidance, but not limiting the scope of the invention, in which:

[0018] FIG. 1 is a schematic view of an internal combustion engine illustrating the elements directly related to the system of the present invention;

[0019] FIG. 2 is a schematic view of an embodiment of the catalyst reformer system according to the invention;

[0020] FIG. 3 is a schematic view of a second embodiment of the catalyst reformer system, according to the invention, in which two fuel reformers are provided, one on each side of the catalyst; and

[0021] FIG. 4 is a schematic view of a third embodiment of the catalyst reformer system, according to the invention, in which the reformer is positioned in the central part of the automotive catalyst, with the reformer being completely involved radially.

DESCRIPTION OF THE INVENTION

[0022] According to the attached figures, with (10) is indicated a reformer catalyst system or device, according to the invention, intended to be coupled to an internal combustion engine (1), or ICE, of a motor vehicle. With particular reference to FIG. 1, the MCI (1) comprises a block (2) which defines, inside, the cylinders (3). Said cylinders (3) are fed by an Air/Fuel mixture in a stoichiometric relation, which can be formed upstream of the intake manifold (4) in indirect injection systems, or inside each cylinder (3), in systems direct injection. For this purpose, an ECU (5), or electronic center, is responsible for providing the admission of a certain amount of fuel, through the injectors (9), according to the driver's requests and the flow of fresh air that is being admitted. In the systemfunction of the negative pressure in the inlet and position of the throttle (6).

[0023] After combustion of the Air/Fuel mixture thus admitted, the exhaust gases are discharged from the exhaust manifold (7), downstream of which a lambda probe (not shown) is provided to determine the residual amount of O.sub.2 in the exhaust gases and thus determine the combustion quality, this information is sent to the ECU (5) and used to regulate the Air/Fuel mixture to be admitted.

[0024] In conventional systems, the exhaust gases are then conducted through the exhaust (8) of the vehicle, not without passing a catalyst, or catalytic converter, responsible for treating the exhaust gases in order to eliminate the most harmful chemical forms, such as, for example, carbon monoxide which is oxidized to form CO.sub.2, hydrocarbons which are also oxidized to form CO.sub.2 and H.sub.2O. Another reaction conventionally performed on the catalyst is the catalytic reduction of NOx emitted in the forms of N.sub.2 and O.sub.2. Also as known, despite the need for a minimum initial temperature for such catalytic reactions to occur, these reactions are exothermic.

[0025] In this way, the present invention comprises a catalytic system, or catalyst reformer device (10) that integrates a catalyst into a fuel reformer, particularly fuel ethanol, or fuel mixtures containing ethanol, in order to maximize the use of the heat generated by the automotive catalyst, or catalytic converter, by a fuel reformer. Despite the fact that the present description makes specific reference to ethanol as a fuel, it is clear to technicians in the sector that the same concepts and constructions of the catalyst reformer of the invention can also be implemented for other fuels, such as methanol, natural gas or compressed natural gas (CNG), gasoline and diesel.

[0026] As particularly illustrated in the embodiment of FIG. 2, the device (10) of the invention is externally defined by a housing (11) which surrounds and defines two individual and adjacent chambers, the first chamber (12) being intended for catalytic conversion of the exhaust gases from the MCI and the second chamber (13) destined to reform the fuel alcohol.

[0027] More specifically, the first chamber (12) is connected, upstream, to said exhaust manifold (7) of the MCI from the inlet nozzle (14). The plenum of the first chamber (12) is filled with a catalytic mesh so that, when the exhaust gases from the MCI flow through it, the catalysts dispersed in this mesh catalyze the reactions of oxidation or reduction of the components of the exhaust gases to the less harmful ways, indicated above, such processed and minimized gases are then exhausted from the device from the exhaust (8) downstream, which connects to the outlet nozzle (15).

[0028] As these reactions are exothermic, the entire internal environment of the first chamber (12) is heated and, therefore, so is the second chamber (13) by heat transfer.

[0029] With regard specifically to said second chamber (13), it comprises a plenum filled with a catalytic mesh similar to the mesh of the first chamber, that is, it may be palladium, platinum, rhodium, silver and/or other appropriate catalysts. The intake nozzle (16) of the second chamber (13) is designed to receive both ambient air (alternatively a fraction of the exhaust gas) and the ethanol to be reformed. Preferably, the ambient air is filtered, via filter (20) before entering the intake nozzle (16). Said feeding nozzle (16) can be connected in order to receive a flow of fresh ambient air, locally combined with a flow of vaporized fuel alcohol through a fuel injector (17) specific for this purpose. In this embodiment, said fuel injector (17) is connected to the fuel pump outlet (not shown), or directly to a specific outlet of the fuel gallery (not shown) on which the fuel injectors (9) are mounted. cylinder feed (3). Alternatively, said inlet nozzle (16) can also receive a partial flow of exhaust gases, which comprises chemical species of interest for the catalytic reactions to be carried out in the catalytic mesh.

[0030] In the plenum of the second chamber (13) the flow of the mixture between ethanol and ambient air, and eventually the exhaust gases, is catalyzed. Such reactions are possible due to the fact that the plenum of the second chamber (13) is properly heated due to the heat transfer that occurs from said first chamber (12) towards the second chamber (13), adjacent to that. As a result of the reactions catalyzed in the second chamber (13), new chemical species (known in the art) are formed depending on the operating temperature of said second chamber (13) and, therefore, the flow of heat emanating from the first chamber (12) to the second chamber (13).

[0031] Table 1 below presents information from the art and compiled in order to correlate the compounds of interest, with the catalyst necessary for the production of these compounds of interest and the operational temperatures necessary for the catalytic system to be able to synthesize said compounds of interest.

TABLE-US-00001 TABLE 1 Paper Element Catalytic Temp. Kinetics and Mechanism of Ethanol Dehydration on ?-Al.sub.2O.sub.3: Ethylene, diethyl ?-Al.sub.2O.sub.3 (?-Alumina) 488 K = The Critical Role of Dimer Inhibition 215? C. Kinetics, Characterization and Mechanism for the Selective Diethyl ether Aluminophosphate- 200? C.- Dehydration of Ethanol to Diethyl Ether over Solid Acid alumina (APA) 300? C. Catalysts catalysts Ethanol Dehydration on silica-aluminas: Active sites and Diethyl ether, Silica-Aluminas Several ethylene/diethyl ether selectivities ethylene (Several Temperatures combinations) Heterobimetallic Zeolite, InV-ZSM-5, Enables Efficient Diethyl ether, Zeolite catalysts 350? C. Conversion of Biomass Derived Ethanol to Renewable ethylene (V-ZSM-S) Hydrocarbons Dimethyl ether, diethyl ether & ethylene from alcohols over Dimethyl ether, Tungstophosphoric 200? C. tungstophosphoric acid based mesoporous catalysts diethyl ether & sodium silicate (TPA) ethylene from alcohols Diethyl ether cracking and ethanol dehydration: Acid Diethyl ether Zeolites, alumina 180? C.- catalysis and reaction paths and silica alumina 300? C. Dehydration of ethanol over zeolites, silica alumina and Ethanol, diethyl Zeolites, alumina 180? C.- alumina: Lewis acidity, Br?nsted acidity and confinement ether and silica alumina 200? C. effects Alumina-Platinum Catalyst in the Reductive Dehydration of Ethanol and Alumina - platinum 250? C.- Ethanol and Diethyl Ether to Alkanes Diethyl Ether to catalyst 400? C. Alkanes A study of commercial transition aluminas and of their Ethanol Alumina 350? C. catalytic activity Thermodynamic Analysis of Ethanol Processors for Fuel Cell Hydrogen (H2) Alumina - platinum 550? C.- Applications catalyst 700? C.

[0032] As can be easily understood by technicians in the sector, the chemical species obtained from the catalytic reactions promoted in the plenum of the second chamber (13) lead to the synthesis of compounds with greater energy efficiency compared to fuel ethanol. As is well known, the energy yield of a chemical compound is directly linked to the amount of chemical bonds existing in its molecule.

[0033] In this way, such synthesized compounds flow from the exhaust nozzle (18) of the second chamber (13), and are then directed to, or upstream of, the intake manifold (4), subsequently distributed in the cylinders (3) of the MCI (1). More specifically, said exhaust nozzle (18) is connected at a point in the supply system, upstream from the intake manifold (4) and downstream from the butterfly valve (6) and, in particular, in a depression region; in this way, the reformed fuel is, in fact, aspirated by the vehicle's fuel system.

[0034] Other considerations in relation to the system of the invention include the need to introduce ethanol fuel into the plenum of the second chamber (13) in a pulverized form, and more preferably pulverized and preheated, in order to facilitate evaporation and increase the reform rate. this, mainly in the initial stages after starting the motor (1). To this end, the alcoholic fuel injected by said fuel injector (17) may comprise an electric fuel preheating system (cold start system), similar to that used in the fuel injector(s) (9) of fuel from the cylinders (3), and/or can be heated using the heat of the MCI exhaust gases, transferred by convection between the respective pipes. Similarly, the ambient air, or alternatively the mixture of ambient air and a fraction of the exhaust gas, which is introduced into the reformer can be electrically preheated, and/or can be heated using the heat from the MCI exhaust gases transferred by contact between the respective pipes. It should be noted that preheating is essential to increase the guarantee of fuel evaporation, specifically ethanol, when injected into the reformer chamber, which is also heated. The electric pre-heating system for ethanol and ambient air can remain activated, while the MCI exhaust is still not hot enough to transfer heat to these two fluids at the start of the cold operation of the MCI.

[0035] As the temperatures of the compounds from the reform can be high, this energetically increased fraction can pass through a heat exchanger (19) before being introduced into the MCI intake system. Likewise, it is convenient to include an impurity filter (22) before the entry of the compounds from the reform in the MCI intake system.

[0036] In an alternative embodiment, the catalytic reforming system of the invention can be timed in relation to the start of the MCI, in order to start the reform of the fuel only after having reached (estimated heating time of the MCI) the minimum operational conditions for the fuel reform.

[0037] In an alternative embodiment, the catalytic reforming system of the invention can be conditioned to the identification of a functional parameter of the MCI, such as the coolant temperature and/or ambient air temperature (cold engine identification).

[0038] In another embodiment alternative, two second chambers (13) are provided, each of the second chambers (13) being laterally disposed in relation to the first chamber (12). Each of the second chambers (13) comprises a plenum filled with a catalytic mesh; an intake nozzle (16) Intended to receive both ambient air and the fuel to be reformed; an exhaust nozzle (18), connected upstream of the intake manifold (4); and a fuel injector (17), arranged upstream of the intake nozzle (16), to inject the fuel to be reformed into the respective second chamber (13). As FIG. 3 illustrates this solution in which two reformers, that is two second chambers (13) are arranged on opposite sides in relation to the catalyst, or first chamber (12). Each of the second chambers (13) of the reformer, in this case, has a respective intake nozzle (16) and respective injector (17). In this solution there is an increase in relation to the heat exchange from the first chamber (12) to the second chamber (13).

[0039] Also alternatively, the first chamber (12) surrounds the second chamber (13); or the second chamber (13) surrounds the first chamber (12). In this construction alternative, illustrated in FIG. 4, the second chamber (13) is cylindrical and completely surrounds the first chamber (12) so that a very significant portion of the heat produced by the first chamber (12) is exclusively directed to the second camera (13). In a variant of this solution (not shown) an inversion is foreseen between the said chambers of FIG. 4, that is, with the second cylindrical chamber (13) being completely surrounded by the first chamber (12), also cylindrical. In this situation it is possible to obtain a more precise control in relation to the percentage of heat emanated from the first chamber and that is directed to the second chamber (13). In addition, the first chamber (12) can surround the second chamber (13), which also results in better use of the heat released by the first chamber (12) by the second chamber (13).

[0040] In another embodiment, the catalyst reformer device (10) of the invention is externally coated with a thermal insulating cover (23), also in order to allow a more precise control between the amount of heat generated in the first chamber (12) and transferred to the second chamber (13). Furthermore, said thermally insulating cover (23) may completely or partially surround the first chamber (12) and the second chamber (13).

[0041] In another non-illustrated embodiment, the reformer catalyst device (10) of the invention, when foreseen to be installed in a turbo-powered MCI (1), or provided with a supercharger-type super-feed system, the exhaust nozzle (18) is connected at a point in the feed system upstream of the turbocharger or supercharger.

[0042] In an alternative embodiment (see FIG. 1), an air filter (20) is provided in order to prevent the ambient air from introducing foreign elements and thus compromising the environment of the plenum of the second chamber (13), as well as the reactions catalysts in this conducted.

[0043] In another alternative implementation, a heat exchanger integrated with a filter at the outlet of the reformed products is foreseen, in order to prevent the new fuels from entering the supply system at an excessively high temperature and accompanied by solid impurities.

[0044] In a last alternative, and aiming to increase the production of H 2 in the reformer, a water reservoir (21) is also provided in order to inject water vapor inside the second chamber (13). In this case, said water reservoir (21) is intended to increase the amount of water originally foreseen in the ethanol fuel, which may not be enough to guarantee a sufficient production of H 2 in the reformer. In addition, and in the event that other fuels other than fuel ethyl alcohol are reformed, this extra supply of water will guarantee the necessary raw material for the production of gaseous hydrogen.

[0045] Finally, the method of the present invention comprises the step of reforming the fuel via catalyst from the heat generated by the catalytic conversion of exhaust gases from the MCI and also from the heat normally rejected in this same exhaust system (1).