• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The present invention relates an arrangement for an exhaust system (3) of a combustion engine (2). The arrangement comprises at least one exhaust treatment. component (4) arranged in the exhaust system (3), a first boiler (5a) of a WHR system arranged in an upstream position of the exhaust treatment component (4) in the exhaust system (3), a second boiler (5b) of the WHR system arranged in a downstream position of the exhaust treatment component (4) in the exhaust system (3) and a working medium circuit (13) circulating a working medium in the WHR system, The working medium circuit (13) comprises a first conduit (13a) directing the working medium to the first boiler (5a), a first bypass conduit (13b) directing the working medium past the first boiler (5a), and a first valve device (14) configured to regulate the working medium flow through the first conduit (13a) and the first bypass conduit (13b).(Fig. 1)
    公开号:SE1650498A1
    申请号:SE1650498
    申请日:2016-04-13
    公开日:2017-10-14
    发明作者:Kardos Zoltan;Treutiger Stefan;SEDERHOLM Thomas
    申请人:Scania Cv Ab;
    IPC主号:
    专利说明:

    Arrangement for an exhaust system of a combustion engine BACKGROUND OF THE INVENTION AND PRIOR ART The present invention relates to an arrangement for an eXhaust system of a combustion engine according to the preamble of claim l.
    EXhaust systems of combustion engines such as diesel engines may comprise aplurality of eXhaust treatment components such as, for example, a SCR catalyst(Selective Catalytic Reduction). In order to clean the eXhaust gases from nitrogenoXides, a urea solution is sprayed into the eXhaust line in a position upstream of theSCR catalyst. The urea solution is vaporized by the hot eXhaust gases so that ammoniais formed. The ammonia and nitrogen oXides in the eXhaust gases react With each otherin the SCR catalyst so that nitrogen gas and Water vapor are formed. The efficiency ofa SCR catalyst depends on its temperature. The ability of the SCR catalyst to reducenitrogen oXides is optimal Within a temperature range Which may be about 300-450°C.At lower and higher eXhaust gas temperatures the capacity of the SCR catalyst to reduce nitrogen oXides is reduced.
    WHR system (Waste Heat Recovery System) can be used for recovering Waste thermalenergy and convert it to mechanical energy or electric energy. A WHR system includesa pump Which pressurizes and circulates a Working medium in a closed circuit. Thecircuit comprises a boiler Where the Working medium is heated and evaporated by aheat source such as, for example, exhaust gases. The pressurized and heated gaseousWorking medium eXpands in an eXpander. The eXpander generates mechanical energyWhich can be used to support the engine and apparatuses in a vehicle. Altematively,the eXpander is connected to a generator generating electric energy. The Workingmedium leaving the eXpander is directed to a condenser. The Working medium iscooled down in the condenser to a temperature at Which it condenses. The fuel consumption of a combustion engine can be reduced by means of a WHR-system.
    The eXhaust gases are cooled down in a boiler of a WHR system. In view of this fact,the boiler is arranged in a downstream position of the eXhaust treatment components.ln this position, the eXistence of the boiler does not influence on the operation of theeXhaust treatment components. However, in case when the combustion engine is highloaded during a longer period of time, there is a risk that the eXhaust gases heat theeXhaust treatment components to a high temperature at which the eXhaust treatment components do not provide an optimal treatment of the eXhaust gases.
    SUMMARY OF THE INVENTION The object of the present invention is to provide an arrangement for an eXhaust systemof a combustion engine where an eXhaust treatment component provides a substantiallyoptimal treatment of the eXhaust gases at the same time as a WHR system convertsheat energy from the exhaust gases with a high efficiency during substantially all operating conditions.
    The above mentioned object is achieved by the arrangement according to thecharacterizing part of claim l. The WHR system comprises a first boiler arranged inthe eXhaust system in an upstream position of an eXhaust treatment component and asecond boiler arranged in a downstream position of the eXhaust treatment component.The working medium may be evaporated in the second boiler and superheated in thefirst boiler. Furthermore, the WHR system comprises a first conduit directing Workingmedium to the first boiler, a first bypass conduit directing the Working medium pastthe first boiler, and a first valve device regulating the working medium flow throughthe first conduit and the first bypass conduit. The efficiency of a treatment componentof eXhaust gases is usually optimal within a specific temperature range. By regulationof the first valve device it is possible to direct an adjustable part of the evaporatedworking medium to the first boiler and a remaining part of it past the first boiler.
    The adjustable working medium flow through the first boiler makes it is possible toregulate the temperature of the eXhaust gases and the temperature of the downstreamlocated eXhaust treatment. As long as the exhaust treatment component has atemperature within said optimal temperature range, it is possible to superheat theworking medium in the first boiler in a substantially optimal manner and provide anefficient operation of the WHR system. Furthermore, the higher temperature differencebetween the eXhaust gases and the working medium in the upstream located boiler makes it possible to reduce the total size of the two boilers in relation to the size of one conventional boiler located doWnstream of the eXhaust treatment component. The firstvalve device may comprise a three Way valve. Altematively, the first valve device maycomprise a tWo-Way valve controlling the Working medium floW through the firstconduit and another two Way valve controlling the Working medium floW through the first bypass conduit.
    According to an embodiment of the invention, the Working medium circuit comprises asecond conduit directing the Working medium to the second boiler, a second bypassconduit directing the Working medium past the second boiler, and a second valvedevice configured to regulate the Working medium floW through said second conduitand the second pass conduit. During most operating conditions, the second valvedevice regulates the entire Working medium floW through the second boiler. In thesecases, the WHR system absorbs heat in an optimal manner in the second boiler.HoWever, during operating conditions When the temperature of the eXhaust treatmentcomponent is too high despite the fact that the first valve device regulates the entireWorking medium floW through the first boiler, it is possible to control the second valvedevice such that the Working medium is directed past the second boiler. In this case,unvaporized Working medium is directed to the first boiler. The Working mediumevaporates in the first boiler Where the big temperature difference betWeen the Workingmedium and the eXhaust gases results in a very efficient and easily controlled coolingof the eXhaust gases before they enter the eXhaust treatment component. In general,this measure makes it possible to cool the eXhaust gases and the eXhaust treatmentcomponent to a temperature Within said optimal temperature range. The second valvedevice may comprise a three Way valve. Altematively, the second valve device maycomprise a tWo-Way valve arranged in the second conduit and another tWo Way valve arranged in the second bypass conduit.
    According to an embodiment of the invention, the arrangement comprises a firsteXhaust line of the eXhaust system directing eXhaust gases to the first boiler, a firsteXhaust bypass line directing eXhaust gases past the first boiler, and a first eXhaustvalve device configured to regulate the eXhaust floW through said first eXhaust line andthe first eXhaust bypass line. The heat transfer in the first boiler depends on thetemperature and the floW rate of the Working medium and the temperature and the floWrate of the eXhaust gases. In this case, it is possible to control the proportion of theeXhaust gases to be directed to the first boiler and thus the temperature of the eXhaust gases entering the eXhaust treatment component. The first exhaust valve device may comprise a first butterfly Valve arranged in the first eXhaust line and a second butterflyvalve arranged in the first eXhaust bypass line. Alternatively, the first eXhaust valve device may comprise only one butterfly valve arranged in the first eXhaust bypass line.
    According to an embodiment of the invention, the arrangement comprises a secondeXhaust line of the eXhaust system directing eXhaust gases to the second boiler, asecond eXhaust bypass line directing eXhaust gases past the first boiler, and a secondeXhaust valve device configured to regulate the eXhaust floW through said secondeXhaust line and the second eXhaust bypass line. In this case, it is possible to adjust theproportion of the eXhaust gases to be directed to the second boiler and the heating ofthe Working medium in the second boiler. The second eXhaust valve device may comprise one or several butterfly valves.
    According to an embodiment of the invention, the arrangement comprises a controlunit configured to receive information about at least one operating parameter and tocontrol the first valve device by means of said parameter. Such a control unit may be acomputer unit provided With a suitable software. The control unit may also control oneor several of the second valve device, the first eXhaust valve device and the second eXhaust valve device.
    According to an embodiment of the invention, said control unit is configured to receiveinformation about a parameter related to the temperature of the eXhaust treatmentcomponent and to control the first valve device by means of said parameter. In thiscase, the arrangement may comprise a temperature sensor sensing the temperature ofthe eXhaust treatment component. Alternatively, a temperature sensor may be arrangedin the eXhaust system in a position immediately doWnstream of the eXhaust treatmentcomponent. The eXhaust gases leaving the eXhaust treatment component have a temperature related to the temperature of the eXhaust treatment component.
    According to an embodiment of the invention, said control unit may be configured toreceive information about the temperature of the eXhaust gases in a position upstreamof the eXhaust treatment component and to control the first valve device by means ofsaid information. In this case, the arrangement may comprise a temperature sensorsensing the temperature of the eXhaust gases in a position upstream of the first boileror doWnstream of the first boiler. The control unit may regulate the first valve device such that the eXhaust gases receive a cooling in the first boiler to a temperature Within said optimal temperature range in Which the exhaust treatment component has an optimal efficiency.
    According to an embodiment of the invention, said control unit may be configured toreceive information about the exhaust floW rate in the exhaust system and to controlthe first valve device by means of said information. The control unit may, for example,receive information from an engine control unit about the exhaust gas floW in theexhaust system. A high exhaust floW in the exhaust system results in a higher heat transfer rate in the first boiler and the second boiler than a loW exhaust floW.
    According to an embodiment of the invention, said control unit may be configured toreceive information about an operating parameter of the WHR system and to controlthe first valve device by means of said information. The control unit may for examplereceive information about the evaporation temperature of Working medium, thesuperheating of the Working medium, the condensation temperature of Working medium and the supercooling of the Working medium.
    According to an embodiment of the invention, the exhaust treatment component is aSCR catalyst. The ability of a SCR catalyst to reduce nitrogen oxides is optimal Withina temperature range Which may be about 300-450°C. At loWer and higher exhaust gastemperatures the capacity of the SCR catalyst to reduce nitrogen oxides is reduced.The exhaust gases are used to vaporize a urea solution before they enter the SCRcatalyst. As a consequence, the temperature of the exhaust gases in a positiondoWnstream of the SCR catalyst can be considerably loWer the temperature of theexhaust gases in a position upstream of the SCR catalyst. ln this case, it is preferable touse the first boiler Which is located upstream of the SCR catalyst in an optimal manner.Alternatively or in combination, the exhaust treatment component may include anoxidation catalytic converter DOC, a particulate filter DPF, or an ammonia slip catalytic converter ASC.
    BRIEF DESCRIPTION OF THE DRAWING ln the folloWing a preferred embodiment of the invention is described, as an example, With reference to the attached draWing, in Which: Fig. l shoWs an arrangement for an exhaust system of a combustion engine.
    DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT OF THEINVENTION Fig. l shows a schematically disclosed vehicle l powered by a superchargedcombustion engine 2. The combustion engine 2 may be a diesel engine. The vehicle lmay be a heavy vehicle. The vehicle l comprises an exhaust system 3 receivingexhaust gases from the combustion engine 2. A schematically disclosed exhausttreatment component 4 is arranged in the exhaust system 3. The exhaust treatmentcomponent 4 may, for example, be one or more of the following exhaust treatmentcomponents namely an oxidation catalytic converter DOC, a particulate filter DPF, aSCR catalytic converter and an ammonia slip catalytic converter ASC. The efficiencyof the exhaust treatment component 4 depends on its temperature. The ability of, forexample, a SCR catalyst to reduce nitrogen oxides may be optimal Within thetemperature range 300-450°C. At higher and lower temperatures the capacity of the SCR catalyst to reduce nitrogen oxides is reduced.
    The exhaust system 3 comprises a first exhaust line 3a and a first bypass line 3barranged in parallel. The first exhaust line 3a and the first bypass line 3b are arrangedin a position upstream of the exhaust treatment components 4. The first exhaust line 3ais provided With a first boiler Sa of a WHR system. A first exhaust valve 6 regulatesthe exhaust floW through the first exhaust line 3a and the first bypass line 3b. Theexhaust system 3 comprises a second exhaust line 3c and a second bypass line 3darranged in parallel. The second exhaust line 3c and the second bypass line 3d arearranged in a position doWnstream of the exhaust treatment component 4. The secondexhaust line 3c is provided With a second boiler 5b of the WHR system. A secondexhaust valve 7 regulates the exhaust floW through the second exhaust line 3c and athird exhaust valve 8 regulates the exhaust floW through the second bypass line 3d. Atemperature sensor 9 senses the temperature of the exhaust gases in exhaust system 3in a position doWnstream of the first exhaust line 3a and the first bypass line 3b andupstream of the exhaust treatment component 4. Thus, the temperature sensor 9 sensesthe temperature of the exhaust gases entering the exhaust treatment component 4. Atemperature sensor ll senses the temperature of at least one of the exhaust treatmentcomponents 4. A control unit l0 receives information from the temperature sensors 9,ll and controls the first exhaust valve 6, the second exhaust valve 7 and the third eXhaust Valve 8 by means of these information. The eXhaust valves 6, 7, 8 may be butterfly valves.
    The vehicle is provided With a WHR- system (Waste Heat Recovery system). TheWHR system comprises a pump 12 Which pressurizes and circulates a Workingmedium in a Working medium circuit 13. The Working medium may be ethanol,R245fa or other kind of Working medium. The Working medium circuit 13 comprises afirst conduit 13a directing the Working medium to the first boiler 5a and a first bypassconduit 13b directing the Working medium past the first boiler 5a. A valve device inthe form of a first three Way valve 14 regulates the Working medium floW through thefirst conduit 13a and the first bypass conduit 13b. The Working medium circuit 13comprises a second conduit 13c directing the Working medium to the second boiler 5band a second bypass conduit 13d directing the Working medium past the second boiler5b. A valve device in the form of a second three Way valve 15 regulates the Working medium floW through the second conduit 13c and the second bypass conduit 13d.
    The pump 12 pressurizes and circulates the Working medium to the second three Wayvalve 15. The second three Way valve 15 regulates the Working medium floW throughthe second conduit 13c and the second bypass conduit 13d. The Working medium maybe heated in a first step by eXhaust gases in the second boiler 5b. The second conduit13c and the second bypass conduit 13d end in a common line of the Working mediumcircuit 13 directing the Working medium to the first three Way valve 14. The first threeWay valve 14 regulates the Working medium floW through the first conduit 13a and thefirst bypass conduit 13b. The Working medium may be heated in a second step byeXhaust gases in the first boiler 5a. In case the Working medium is heated in two steps,it can be evaporated in the second boiler 5b and superheated in the in the first boiler5a. The first conduit line 13a and the first bypass conduit 13b end in a common line of the Working medium circuit 13 directing the Working medium to an eXpander 16.
    The Working medium eXpands in the eXpander 16. The eXpander 16 generates a rotarymotion Which may be transn1itted, via a mechanical transmission 17, to a shaft of adrive train of the vehicle 1. Alternatively, the eXpander 16 may be connected to agenerator transforn1ing mechanical energy into electrical energy. The electrical energymay be stored in e. g. a battery. After the Working medium has passed through theeXpander 16, it is directed to a condenser 18. The Working medium is cooled in the condenser 18 by, for example, coolant circulated in a cooling system in the vehicle.
    The Working medium is directed from the condenser 18 to a receiver 19. Finally, the Working medium is directed from the receiver 19 back to the pump 12.
    During operation of the combustion engine 2, the control unit 10 receives substantiallycontinuously information from the sensor 11 about the temperature of the eXhausttreatment component 4, information from the sensor 9 about the temperature of theeXhaust treatment component 4 and information 20 about the eXhaust gas floW rate inthe eXhaust system 3. The control unit 10 may also receive information from operatingparameters of the WHR system. The control unit 10 verifies if the temperature of theeXhaust treatment component 4 is Within a temperature range in Which the eXhaust treatment component 4 provide an optimal treatment of the eXhaust gases.
    During operating conditions When the eXhaust treatment component 4 has a lowertemperature than said optimal temperature range, it is desired to increase thetemperature of eXhaust treatment component 4 in order to achieve an optimal treatmentof the eXhaust gases. ln this case, the control unit 10 initiates a movement of the firsteXhaust valve 6 to a fully open position such that substantially the entire the eXhaustgas floW rate in the exhaust system 3 Will floW through the first bypass line 3b and pastthe first boiler Sa. Furthermore, the control unit 10 controls the first three Way valve 14such that it directs the Working medium in the WHR system to the first bypass conduitl3b and thus past the first boiler Sa. ln this case, the eXhaust gases Will not be cooled atall by the WHR system before they enter the eXhaust treatment component 4. Ingeneral, the uncooled eXhaust gases Will increase the temperature of the eXhausttreatment component to a temperature Within said optimal temperature range relatively quickly. ln order to use the WHR system in an optimal manner during the above mentionedoperating conditions, the control unit 10 initiates a movement of the second eXhaustvalve 7 to a fully open position and a movement of the third exhaust valve 8 to aclosed position such that the entire eXhaust floW rate Will floW through the secondboiler 5b. Furthermore, the control unit 10 controls the second three Way valve 15 suchthat it directs the entire Working medium floW rate through the first conduit 13a andthe second boiler 5b. ln this case, the eXhaust gases heat the Working medium in thesecond boiler 5b. The Working medium leaving the second boiler 5b is evaporated and preferably superheated. In this case, the second boiler 5b is only used.
    During operating conditions When the exhaust treatment component 4 has a highertemperature than said optimal temperature range, it is desired to decrease thetemperature of the eXhaust treatment component 4. ln this case, it is suitable to use thefirst boiler Sa of the WHR system in an optimal manner. Thus, the control unit 10initiates a movement of the first eXhaust valve 6 to a closed position such that theentire eXhaust gas floW rate in the eXhaust system 3 Will floW through the first eXhaustline 3a and through the first boiler Sa. Furthermore, the control unit l0 controls thefirst three Way valve l4 such that it regulates the entire Working medium floW rate inthe WHR system to the first conduit l3a and thus through the first boiler Sa. ln thiscase, the Working medium may be evaporated in the second boiler Sb and superheatedin the first boiler Sa. The superheating of the Working medium in the first boilerreduces the temperature of the eXhaust gases entering the eXhaust treatment component4. This measure may reduce the temperature of the eXhaust gases and the temperatureof the eXhaust treatment component 4 to a temperature Within said optimal temperature range.
    The above mentioned cooling of the eXhaust gases in the first boiler Sa is not alWayssufficient to reduce the temperature of the eXhaust gases to an acceptable temperaturebefore they enter the eXhaust treatment component 4. ln order to further increase thecooling of the eXhaust gases in the first boiler Sa, the control unit l0 initiates amovement of the second three Way valve lS to a position in Which it directs theWorking medium, via the second bypass conduit l3d, past the second boiler Sb. In thiscase, unvaporized Working medium is directed to the first boiler Sa. The hot eXhaustgases heat the Working medium in the first boiler such that it Will be evaporated andsuperheated before it leaves the first boiler Sa. ln this case, it is many times possible todecrease the temperature of the eXhaust gases and the temperature of the eXhaust gasesand the temperature of the treatment component 4 relatively rapidly to a temperature Within said optimal temperature range.
    During operating conditions When the exhaust treatment component 4 already has atemperature Within the optimal temperature range, the primary object is to maintain thetemperature of the eXhaust treatment component 4 Within said temperature range. Asecondary object is to use the WHR system in an optimal manner. ln this case, thecontrol unit l0 may control the second three Way valve lS such that the entire Workingmedium floW is regulated through second conduit l3c and the second boiler Sb. The control unit l0 initiates a movement of the second eXhaust valve 7 to a fully open position and a movement of the third eXhaust Valve 8 to a closed position such that theentire eXhaust floW rate Will floW through the second boiler Sb. The Working mediumobtains a heating by the eXhaust gases in the second boiler Sb to a temperature at Which it evaporates.
    Furthermore, the control unit 10 initiate a movement of the first eXhaust Valve 6 to amore or less open position such that a part of the eXhaust gas floW rate Will floWthrough the first exhaust line 3a and the first boiler Sa and a remaining part of theeXhaust gas floW rate Will floW through the first bypass line 3b. Furthermore, thecontrol unit l0 controls the first three Way Valve l4 such that it directs a suitable partof the evaporated Working medium in the WHR system to the first conduit line l3a andthrough the first boiler Sa and a remaining part of the evaporated Working medium tothe bypass conduit l3b. The heat transfer in the first boiler Sa is related to the floW rateand the temperatures of the Working medium and the floW rate and the temperature ofthe eXhaust gases. ln this case, it is suitable to cool the eXhaust gases to a loWestpossible temperature in the first boiler Sa at Which the temperature of the eXhaust treatment component 4 is maintained Within the optimal temperature range.
    The invention is not restricted to the described embodiment but may be Varied freely Within the scope of the claims.
    权利要求:
    Claims (9)
    [1] 1. An arrangement for an exhaust system (3) of a combustion engine (2), Wherein thearrangement comprises at least one exhaust treatment component (4) arranged in theexhaust system (3), a first boiler (5a) of a WHR system arranged in an upstreamposition of the exhaust treatment component (4) in the exhaust system (3), a secondboiler (5b) of the WHR system arranged in a doWnstream position of the exhausttreatment component (4) in the exhaust system (3) and a Working medium circuit (13)circulating a Working medium in the WHR system, Wherein the Working mediumcircuit (13) comprises a first conduit (13a) directing the Working medium to the firstboiler (5 a), a first bypass conduit (13b) directing the Working medium past the firstboiler (5 a), and a first valve device (14) configured to regulate the Working mediumflow through the first conduit (13a) and the first bypass conduit (13b), characterized inthat the Working medium circuit (13) comprises a second conduit (13c) directing theWorking medium to the second boiler (5b), a second bypass conduit (13d) directing theWorking medium past the second boiler (5b), and a second valve device (15)configured to regulate the Working medium flow through said second conduit (13c)and the second pass conduit (13d) and that the arrangement comprises a control unit(10) configured to receive information about at least one operating parameter related tothe temperature of the exhaust treatment component (4) and to control the first valvedevice (14) and the second valve device (15) by means of said parameter such that theexhaust treatment component (4) receives a temperature (4) Within a specifictemperature range at Which the exhaust treatment component (4) has an optimal efficiency.
    [2] 2. An arrangement according to claim 1, characterized in that it comprises a firstexhaust line (3a) of the exhaust system (3) directing exhaust gases to the first boiler(5a), a first exhaust bypass line (3b) directing exhaust gases past the first boiler (5a),and a first exhaust valve device (6) configured to regulate the exhaust flow through said first exhaust line (3a) and the first exhaust bypass line (3b).
    [3] 3. An arrangement according to claim 1 or 2, characterized in that it comprises asecond exhaust line (3 c) of the exhaust system (3) directing exhaust gases to thesecond boiler (5b), a second exhaust bypass line (3d) directing exhaust gases past the second boiler (5b), and a second exhaust valve device (7, 8) configured to regulate the exhaust flow through said second exhaust line (3 c) and the second exhaust bypass line(3 d).
    [4] 4. An arrangement according to any one of the preceding claims, characterized in thatsaid control unit (10) is conf1gured to receive inforrnation about the exhaust flow ratein the exhaust system (3) and to control the first valve device (14) by means of said inforrnation.
    [5] 5. An arrangement according to any one of the preceding claims, characterized in thatsaid control unit (l0) is conf1gured to receive inforrnation about the temperature of theexhaust treatment component (4) and to control the first valve device (l4) by means of said inforrnation.
    [6] 6. An arrangement according to according to any one of the preceding claims,characterized in that said control unit (l0) is conf1gured to receive inforrnation aboutthe temperature of the exhaust gases in a position upstream the exhaust treatment component (4) and to control the first valve device (l4) by means of said inforrnation.
    [7] 7. An arrangement according to any one of the preceding claims, characterized in thatsaid control unit (l0) is configured to receive inforrnation about an operatingparameter of the WHR system and to control the first valve device (l4) by means of said inforrnation.
    [8] 8. An arrangement according to any one of the preceding claims, characterized in that the exhaust treatment component (4) is a SCR catalyst.
    [9] 9. Vehicle comprising an arrangement according to any one of the preceding claims lto 8.
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    同族专利:
    公开号 | 公开日
    WO2017180041A1|2017-10-19|
    SE541486C2|2019-10-15|
    US20190153904A1|2019-05-23|
    DE112017001279T5|2018-11-29|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    JP2002115505A|2000-10-11|2002-04-19|Honda Motor Co Ltd|Rankine cycle device of internal combustion engine|
    US7275366B2|2004-09-14|2007-10-02|Advanced Cleanup Technologies, Inc.|High thermal efficiency Selective Catalytic Reduction system|
    FR2884555A1|2005-04-13|2006-10-20|Peugeot Citroen Automobiles Sa|Vehicle IC engine energy recuperator has nitrogen oxide trap in exhaust line and Rankine cycle system with loop containing compressor and evaporator|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    SE1650498A|SE541486C2|2016-04-13|2016-04-13|Arrangement for an exhaust system of a combustion engine|SE1650498A| SE541486C2|2016-04-13|2016-04-13|Arrangement for an exhaust system of a combustion engine|
    PCT/SE2017/050315| WO2017180041A1|2016-04-13|2017-03-31|Arrangement for an exhaust system of a combustion engine comprising two whr boilers|
    US16/091,405| US20190153904A1|2016-04-13|2017-03-31|Arrangement for an exhaust system of a combustion engine comprising two whr boilers|
    DE112017001279.1T| DE112017001279T5|2016-04-13|2017-03-31|Arrangement for an exhaust system of an internal combustion engine comprising two WHR boilers|
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