Patent Description:
Among the challenges of the energy transition, reducing CO<NUM> emissions of the transportation sector is one of the most difficult. For post combustion CO<NUM> capture from power plants and process industries, known systems include technologies based on amine absorption, membrane separation, cryogenic separation and adsorption.

Amine absorption for capturing CO<NUM> is commonly used in power plant and process industry including natural gas sweetening (<NPL>). The amine absorption process is energy intensive (<NUM> MJ/kg-CO<NUM>, <NUM>% CO<NUM> in flue gas and <NUM>% CO<NUM> capture), and the cost of CO<NUM> capture is <NUM> $/kWh (<NPL>). For <NUM>% CO<NUM> capture, performance of the amine absorption process and the membrane separation process are similar with about <NUM>% loss in the plant efficiency (<NPL>). For natural gas power plants with <NUM>% CO<NUM> capture using amine absorption, efficiency of the integrated plant decreases by over <NUM>% due to the energy penalty of CO<NUM> capture (<NPL>).

Pressure swing adsorption (PSA) is a well established gas separation technology which has found applications in air separation, hydrogen purification and natural gas industry. Further, temperature swing adsorption (TSA) is a known technology for CO<NUM> capture that requires low grade waste heat which may be available close to the CO<NUM> emission source.

Proll et al. (<NPL>) evaluated a fluidized bed TSA system for CO<NUM> capture from flue gas stream, and in terms of heat transfer, fluidized bed reactor was found better than fixed and moving bed reactors. Gibson et al. (<NPL>) have evaluated several adsorption materials and process designs for CO<NUM> capture from gas fired power plant. Ntiamoah et al. (<NPL>) performed cyclic experiments on single adsorption column, and product (hot) CO<NUM> was used to supply the heat of desorption in the regeneration step. Marx et al. (<NPL>) studied cyclic behaviour and separation performance of TSA for post-combustion CO<NUM> capture.

In the year <NUM>, CO<NUM> emissions due to human activities accounted for about <NUM> percent of greenhouse gas emissions globally (IPCC, <NUM>: Climate Change <NUM>: Mitigation of Climate Change. Contribution of Working Group III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change, Cambridge University Press, Cambridge, U. In <NUM>, transportation sector was accountable for about <NUM> percent of CO<NUM> emissions in USA (EPA report). In <NUM>, according to the European Environment Agency, road transportation sector contributed about <NUM> giga tonnes CO<NUM> emissions. In <NUM>, according to European Automobile Manufacturers Association, <NUM> million commercial vehicles were produced in the European Union. Ligterink (Ligterink N. , Dutch CO2 emission factors for road vehicles, TNO R10499, <NUM>) has reported <NUM> of CO<NUM> emission per liter diesel consumption by heavy duty vehicles.

The above numbers show a huge potential for on board CO<NUM> capture technology for vehicles which would reduce CO<NUM> emissions significantly. There has however been limited research on CO<NUM> capture from vehicles due to mobile nature of source, relatively smaller production rate, discontinuous emissions, and difficulties of on board CO<NUM> storage. For instance, the Amine absorption process is difficult in mobile applications, although it has been proposed in marine applications (<NPL>).

<FIG> shows typical composition of exhaust gas from a diesel engine. CO<NUM> and pollutant emissions are about <NUM>% and <NUM>% (CO, HC, NOx, SO<NUM>, PM) respectively (<NPL>). Diesel engines typically have an efficiency of about <NUM>%, whereby the remaining energy is lost in the cooling system (about <NUM>%) and in exhaust heat (about <NUM>%) (<NPL>).

The temperature of engine exhaust gas normally ranges from <NUM> to <NUM> <NUM>C (<NPL>). The heat of the cooling system can also be recovered at around <NUM> (<NPL>). The waste heat from engine exhaust and cooling system has been used in a Rankine cycle to generate mechanical power for heavy duty trucks (<NPL>) and cruise ships (<NPL>). Sprouse (<NPL>) have reviewed many studies on the use of organic Rankine cycle for the waste heat recovery from the exhaust of internal combustion engine, and claimed <NUM>% improvement in the fuel economy.

Documents <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT> describe various aspects of known CO<NUM> capture systems or temperature swing adsorption devices, in which <CIT> describes an engine power system with a recirculation of exhaust gas to a compressor stage of a turbine and CO<NUM> capture, <CIT> describes a device for adsorbing CO2 by temperature swing adsorption, <CIT> describes a process for producing and processing a synthesis gas stream and separating out CO2 from this gas stream, <CIT> describes an adsorber vessel, <CIT> describes a temperature swing adsorptions system, and <CIT> describes a CO<NUM> recovery device of an internal combustion engine.

An object of the present invention to provide a system for CO<NUM> capture from exhaust gas produced by an internal combustion engine adapted for mobile applications.

It is advantageous to provide a system for CO<NUM> capture from exhaust gas produced by an internal combustion engine that is efficient and economical.

It is advantageous to provide a system for CO<NUM> capture from exhaust gas produced by an internal combustion engine that is compact.

Objects of this invention have been achieved by providing the system according to claim <NUM>.

The invention advantageously combines an organic Rankine cycle (ORC) with temperature swing adsorption (TSA) to capture the CO<NUM> from a combustion engine exhaust stream, utilizing the waste heat of the combustion engine.

In an embodiment, Amine doped metal-organic frameworks (MOFs) adsorbents are selected for CO<NUM> capture, as they show good performance in the presence of water (Huck et al.

According to embodiments of the invention, adsorbent materials may include metal organic frameworks (Mg, Zn, Al or Fe MOF), zeolitic imidazolate frameworks (ZIF-<NUM>, ZIF-<NUM>), amine functionalized porous polymer networks (PPN-<NUM>-CH2-DETA, PPN-<NUM>-CH2-TETA), amine infused silica (PEI-silica), amine loaded MCM-<NUM> (PEI-MCM-<NUM>), mmen-M2(dobpdc) framework, zeolites (Zeolite-<NUM> A).

Part of the mechanical power produced by the ORC may advantageously be used to generate cold utility using CO<NUM>-based heat pump, for instance by using a turbo-compressor driven by the exhaust gas stream. This cold utility may be used to remove heat of adsorption and condense the water from engine exhaust stream.

Part of the mechanical power generated by the ORC may be used to compress and liquify the produced CO<NUM>, for instance by using a turbo-compressor driven by the exhaust gas stream.

The CO<NUM> capture system advantageously does not require any external power and thus has energy self sufficiency. In other words, TSA with turbo-compressors according to embodiments of the invention is an attractive choice for CO<NUM> capture from vehicles without any energy penalty. The CO<NUM> capture system for truck exhaust stream according to embodiments of the invention may advantageously capture up to <NUM>% of the emitted CO<NUM> (i.e., <NUM> CO<NUM> per liter of diesel consumption). In addition, the captured CO<NUM> can advantageously be utilized as a carbon source for producing new fuel (methane or liquid fuels) by integrating hydrogen produced from renewable energy resources.

Disclosed herein is a system for CO<NUM> capture from a combustion engine comprising an exhaust gas flow circuit having an inlet end fluidly connected to an exhaust of the combustion engine, a heat exchanger circuit, a primary exhaust gas heat exchanger for transferring heat from exhaust gas to fluid in the heat exchanger circuit, at least one compressor for compressing fluid in a section of the heat exchanger circuit, the compressor driven by thermal expansion of heat exchanger circuit fluid from the primary exhaust gas heat exchanger, and a CO<NUM> temperature swing adsorption (TSA) reactor fluidly connected to an outlet end of the exhaust gas flow circuit. The TSA reactor includes at least an adsorption reactor unit and a desorption reactor unit, the heat exchanger circuit comprising a heating section for heating the desorption unit and a cooling section for cooling the adsorption unit.

In an advantageous embodiment, the fluid in the heat exchanger circuit is, or contains primarily, CO<NUM>.

In an advantageous embodiment, the system further comprises at least a second compressor driven by thermal expansion of heat exchanger circuit fluid from the primary exhaust gas heat exchanger (H1), the second compressor fluidly connected to an outlet of the desorption reactor unit (D2) for compressing CO<NUM> output by the desorption unit.

In an embodiment, the heat exchanger circuit is fluidly connected to a CO<NUM> output flow circuit of the TSA reactor and the heat exchanger circuit contains CO<NUM> outputted from the TSA reactor.

In an embodiment, fluid in the heat exchanger circuit is independent of a CO<NUM> output flow circuit of the TSA reactor.

In an advantageous embodiment, the compressors are turbocompressors.

In an advantageous embodiment, the TSA reactor further comprises a preheating unit and a precooling unit, a heating section of the heat exchanger circuit passing through the preheating unit and the desorption unit to heat these units to cause the adsorbed CO<NUM> to be extracted from the adsorbent, and a cooling section of the heat exchanger circuit passes through the precooling unit and the adsorption unit D4 to cool these units below the temperature at which the adsorbent adsorbs the CO<NUM> in the exhaust gas stream.

In an advantageous embodiment, the exhaust gas flow circuit comprises a gas-liquid separator upstream of the TSA reactor to extract water from the exhaust gas stream.

In an advantageous embodiment, a cooling section of the heat exchanger circuit comprises an expansion valve to lower the temperature and pressure of the heat exchanger circuit gas outputted from a preheating unit of the TSA reactor.

In an advantageous embodiment, the system comprises a CO<NUM> storage tank for collection and storage of outputted CO<NUM>.

In an advantageous embodiment, the outputted CO<NUM> is compressed at its storage pressure by one of said compressors.

In an advantageous embodiment, the outputted CO<NUM> is compressed by constant volume heating operation of the desorption reactor unit.

In an advantageous embodiment, the TSA reactor comprises an amine doped MOFs adsorbent.

In an advantageous embodiment, the TSA comprises adsorbent material on the surface of a fixed bed in each of said reactor units.

In an advantageous embodiment, the reactor units are interconnected by fluid flow circuits and valves that may be operated to successively cycle the reactor units through different states from adsorption, preheating, desorption and precooling.

The invention will now be described with reference to the accompanying drawings, which by way of example illustrate embodiments of the present invention and in which:.

<FIG> illustrates an integrated CO<NUM> capture system, based on <NUM> liter diesel consumption in an internal combustion engine. First of all, diesel engine exhaust based on <NUM> liter of diesel consumption is analyzed for CO<NUM> capture. The TSA system is calculated using PPN-<NUM>-CH<NUM>TETA as an adsorbent (Huck et al. <FIG> shows enthalpy-temperature profiles for exhaust cooling, adsorption cooling, desorption heating and product CO<NUM> compression. The exhaust stream contains <NUM> MJ/l-diesel waste heat, heating and desorption step requires <NUM> MJ/l-diesel heat, <NUM> MJ/l-diesel heat has to be removed during cooling and adsorption step, and <NUM> MJ/l-diesel heat has to be removed for CO<NUM> compression and liquefaction.

<FIG> shows simple heat and mass flows for CO<NUM> capture system, based on <NUM> liter diesel consumption. <NUM> liter diesel contains <NUM> MJ energy, which is divided into three parts by the internal combustion engine: <NUM> MJ as mechanical power to drive the vehicle, <NUM> MJ as waste heat in exhaust gas, and <NUM> MJ as heat removed using coolant. The exhaust gas stream is cooled down to <NUM> <NUM>C, and water is condensed and removed. The cooled exhaust stream (saturated with water at <NUM> <NUM>C) goes to the adsorption bed, where CO<NUM> is attached to the adsorbent. Finally, CO<NUM> is desorbed from the adsorbent at high temperature, and then compressed and liquefied.

Table <NUM> also presents exergetic analysis of internal combustion engine (Al-Najem and Diab, <NUM>; Kul and Kahraman, <NUM>). The CO<NUM> capture system according to embodiments of the invention is thus feasible from the exergetic point of view (Table <NUM> and <FIG>). In total, <NUM> MJ of net exergy is available. Assuming a <NUM>% efficiency, therefore there is a potential to produce the equivalent of <NUM> MJ of mechanical power for the CO<NUM> capture and storage system. Assuming an isentropic efficiency of <NUM>% for the compressors, this value can be compared with the compression power needed to produce CO<NUM> in the liquid form (compression at <NUM> bar): <NUM> MJ or compressed CO<NUM> at <NUM> bar: <NUM> MJ. For <NUM> liter diesel consumption in an internal combustion engine, <NUM> CO<NUM> is captured by the system, which has a volume of <NUM> liters (as liquid CO<NUM> product) or <NUM> liters (as compressed CO<NUM> product).

The above analysis shows that it is possible to generate the heat and the work that is needed to capture the CO<NUM> of exhaust gases of a combustion engine using energy available in the exhaust gases, which is particularly advantageous for mobile applications, such as for CO<NUM> capture from the exhaust of a diesel engine on a truck, bus or boat.

The CO<NUM> capture system according to embodiments of the invention combines heat pumping, cooling and Rankine cycle integration. It is advantageous to produce a cooling capacity at a temperature lower than the <NUM> for the adsorption step of a temperature swing adsorption (TSA) process, especially in mobile applications where environmental temperature may exceed the optimal temperature for efficient adsorption of CO<NUM>.

Referring to the figures, in particular <FIG> and <FIG>, a CO<NUM> capture system <NUM> for capturing CO<NUM> from the exhaust of an internal combustion (IC) engine <NUM>, according to embodiments of the invention, comprises an exhaust gas flow circuit <NUM>, a temperature swing adsorption reactor <NUM>, a heat exchanger circuit <NUM>, a CO<NUM> output flow circuit <NUM>, and one or more turbines or compressors <NUM>, which may advantageously be in the form of turbocompressors TC1, TC2.

Turbocompressors may be mechanically connected together via a common shaft or a fixed or variable transmission mechanism. The turbocompressors TC1, TC2 may also be connected to electrical generators. In a variant, turbocompressors TC1, TC2 may be not be mechanically coupled together, but only electrically coupled, for instance the electrical energy from a generator coupled to a turbocompressor being used to drive a motor coupled to another turbocompressor.

The exhaust gas flow circuit <NUM> is connected at an inlet end to the exhaust of the IC engine <NUM> and at an outlet end to the TSA, and passes through a primary exhaust gas heat exchanger H1 to transfer waste heat from the exhaust gas to a heating section 12b of heat exchanger circuit.

The heating section 12b contains gas, and may be fluidly connected to said one or more turbocompressors. Expansion of the gas in the heating section 12b due to the heat transfer in the primary heat exchanger drives the one or more turbocompressors TC1, TC2. The gas contained in the heat exchanger circuit may in advantageous embodiments be CO<NUM>.

In certain embodiments for instance as illustrated in <FIG> and <FIG>, the fluid in the heat exchanger circuit is independent of the TSA reactor CO<NUM> output flow circuit <NUM>.

In certain other embodiments as illustrated in <FIG>, <FIG> <FIG> and <FIG>, the heat exchanger circuit <NUM> is fluidly connected to the TSA reactor CO<NUM> output flow circuit <NUM>, and the heat exchanger circuit <NUM> contains CO<NUM> outputted from the TSA reactor <NUM>.

The TSA reactor comprises an adsorption unit D4, a preheating unit D1, a desorption unit D2, and a precooling unit D3. The heating section 12b of the heat exchanger circuit passes through the preheating unit D1 and the desorption unit D2 to heat these units to cause the adsorbed CO<NUM> to be extracted from the adsorbent. The cooling section 12a of the heat exchanger circuit passes through the precooling unit D3 and the adsorption unit D4 to cool these units below the temperature at which the adsorbent adsorbs the CO<NUM> in the exhaust gas stream. In certain embodiments, the temperature of the adsorption unit D4 for adsorption is preferably around <NUM> or less.

The cooling section 12a of the heat exchanger circuit <NUM> may comprise an expansion valve V1 to lower the temperature and pressure of the heat exchanger circuit gas outputted from the preheating unit D1 of the TSA reactor <NUM>, for recirculation in the adsorption unit D4 and in certain embodiments where the heat exchanger circuit is connected to the CO<NUM> output flow circuit <NUM>, for collection and storage of outputted CO<NUM> in a CO<NUM> storage tank T1.

The exhaust gas flow circuit <NUM> further comprises a gas-liquid separator S1 to extract water from the exhaust gas stream. Preferably, the gas-liquid separator S1 is positioned upstream of the TSA reactor <NUM>, and comprises a condenser for condensing water in the exhaust gas stream before the exhaust gas stream enters the adsorption unit D4. The condensed water may be fed into a water storage tank (not shown), or allowed to flow into the environment.

Further heat exchangers for the exhaust gas stream, in particular an additional exhaust gas heat exchanger H4 in the exhaust gas stream after the primary exhaust gas heat exchanger H1 may be provided to further cool down the exhaust gas stream prior to entry in the TSA reactor <NUM>.

The heat exchanger circuit comprises a heat exchanger H2 between the outlet of the precooling unit D3 of the TSA reactor and the compressor <NUM>, for instance in the form of a heat exchanger H2, prior to compression of the heat exchanger circuit gas by the compressor <NUM>. The heat exchanger H2 after the outlet of the precooling unit D3 of the TSA reactor allows to cool down the heat exchanger circuit gas that is heated in the TSA, prior to recirculation in the cooling section 12a.

The heat exchanger circuit comprises a heat exchanger H3 at the outlet of the preheating unit D1 of the TSA reactor, for instance in the form of condenser H3, to cool down the heat exchanger circuit gas exiting the hot section of the TSA, prior to recirculation in the cooling section 12a.

Exhaust gas stream after cooling down via heat exchangers H1, H4 to a temperature adapted for adsorption by the adsorbent of the TSA reactor, flows into the adsorption unit D4 of the TSA reactor. A large percentage of the CO<NUM> in the exhaust gas stream, for instance around <NUM>% of the CO<NUM>, is adsorbed by the adsorbent in the adsorption unit D4 and the remaining gases may be output into the environment.

In an advantageous embodiment (illustrated in <FIG>), the adsorbent material is on the surface of a fixed bed in each of a plurality of reactor chambers D1-D4 that are interconnected by a gas flow circuits and valves that may be operated to rotate the function of each of the reactor chambers successively from adsorption, to preheating, to desorption, to precooling. Thus each reactor chamber is at a different successive temperature state and each reactor chamber acts in successive rotation as the adsorption unit D4, preheating unit D1, desorption unit D2, and precooling unit D3.

In a variant, the adsorbent material is on particles forming a fluidized bed that flows from one reactor chamber D1-D4 to the next (embodiment illustrated in <FIG>), the reactor chambers interconnected by fluidized bed flow circuits and valves that may be operated to control flow of the fluidized bed between each of the reactor chambers successively from adsorption, to preheating, to desorption, to precooling. Thus each reactor chamber is at a different successive temperature state and acts as one of the adsorption unit D4, preheating unit D1, desorption unit D2, or precooling unit D3.

The TSA reactor comprises at least two reactors to function successively as adsorption and desorption reactors, whereby the precooling and preheating units may be omitted or integrated within the respective adsorption and desorption reactors.

Preferably, the TSA reactor comprises at least four reactor units such that at least two reactor units during a cycle act as precooling, respectively preheating reactors to improve the efficiency and yield of adsorption and desorption of CO<NUM>. In variants, more than four reactors may however be provided to have additional precooling and preheating reactor units. In variants however, the TSA reactor may comprise three reactor units, for instance an adsorption unit, a preheating & desorption unit, and a cooling unit, whereby the preheating and desorption can be incorporated in a single reactor unit.

Referring now to the particular embodiments illustrated in <FIG>, starting with the embodiment of <FIG>. This embodiment presents a system that combines a temperature swing adsorption reactor <NUM> to capture the CO<NUM> from the exhaust stream of an internal combustion or Stirling engine <NUM> with a turbo-compressor <NUM> to produce liquid CO<NUM>.

The atmospheric temperature swing adsorption system <NUM> comprises at least two stages: (D2) desorption of CO2 from the adsorbent, and (D4) adsorption of CO2 from the exhaust gases.

In a preferred embodiment, the atmospheric temperature swing adsorption system <NUM> comprises four stages: (D1) adsorbent preheating, (D2) desorption of CO<NUM> from the adsorbent, (D3) adsorbent precooling, and (D4) adsorption of CO<NUM> from the exhaust gases.

In a variant, the atmospheric temperature swing adsorption system <NUM> comprises three stages: (D2) desorption of CO<NUM> from the adsorbent (including adsorbent preheating), (D3) adsorbent precooling, and (D4) adsorption of CO<NUM> from the exhaust gases.

A primary exhaust gas heat exchanger H1 recovers the heat of the exhaust gases to heat CO<NUM> fluid in the heat exchanger circuit <NUM>, which is pumped by a pump P1 as a liquid at supercritical pressure, and heated up to supercritical conditions.

The supercritical heat exchange fluid may be divided into two flows that are fed into two turbocompressors <NUM>. The first turbocompressor TC1 is used to compress the CO<NUM> extracted from the adsorbent to the CO<NUM> storage pressure. Excess of work of the first turbocompressor TC1 may be supplied to drive a generator (not shown).

The second turbocompressor TC2 may be used to compress the CO<NUM> evaporated in the heat exchangers H5, H6, D4, D3 and H2. Excess work of the second turbocompressor TC2 may be supplied to drive a generator (not shown).

One or two heat exchangers, that uses the outlet streams of the turbines of the turbocompressors, are used to supply heat of desorption of the captured CO<NUM> (D2) and later preheating of the adsorbent (D1).

A heat exchanger H3 acts as a condenser to condense the compressed CO<NUM> by heat exchange with the environment.

The gas liquid separator S1 separates the condensed water from the combustion gases.

The expansion valve V1 expands the liquid CO<NUM> to a lower pressure, which has suitable temperature for the adsorption unit.

A heat exchanger acting as an evaporator H5 produces cold that is used to cool down the combustion gases to a low temperature. The cold combustion gases are fed to the adsorbent unit D4.

An additional evaporator H6 may be provided to generate additional cooling for various auxiliary purposes, such as vehicle cabin cooling.

One or two heat exchangers cool the adsorbent bed (D4) followed by the precooling of the adsorbent bed (D3) which leaves the desorption step (D2).

The storage tank T1 stores the captured CO<NUM> in the liquid form at the outlet of condenser H3. High pressure compressed CO<NUM> gas storage can be used as an alternative for liquid CO<NUM> storage.

In a variant, as illustrated in <FIG>, a gas liquid separator S2 in the heat exchanger circuit at the outlet of valve V1 may be provided to produce liquid CO<NUM> product.

In a variant, as illustrated in <FIG>, the system comprises a separate flow circuit for recovering CO<NUM> from the adsorbent using a heat exchanger coupled to ambient (environmental) temperature and fed into a liquid storage tank T2.

In a variant, as illustrated in <FIG>, CO<NUM> compression can also be realised by constant volume heating operation of the desorption reactor unit D2 instead of using the turbocompressor TC1.

In an embodiment, as illustrated in <FIG>, waste heat available from the engine cooling system can be used as an additional source of heat for the system.

In a variant, as illustrated in <FIG>, heat exchanger circuits 12a and 12b have different fluids.

The CO<NUM> capture system is designed for <NUM> day operation of heavy duty truck for delivery in a city, which travels <NUM> in <NUM> hours (<NUM> liters diesel/<NUM>, Delgado et al. The diesel engine emits <NUM> of CO<NUM> by consuming <NUM> liters diesel, and <NUM> of CO<NUM> (<NUM>% capture) should be captured and stored by the CO<NUM> capture system. The working capacity (or CO<NUM> loading) of the adsorbent material is <NUM>-CO<NUM>/kg-adsorbent (Verdegaal et al. Finally, <NUM> adsorption-desorption cycle time has been assumed (Gibson et al.

CO<NUM> is captured, compressed, liquefied and stored in a storage tank. The diesel engine consumes <NUM> liters diesel per hour that means <NUM> CO<NUM> should be captured per hour (<NUM> liter diesel = <NUM> CO<NUM> emission ≃ <NUM>% or <NUM> CO<NUM> capture, see <FIG>). Hence, the capture system requires <NUM> (<NUM> liters) adsorbent. Further, the mass of storage tank is <NUM> (typical liquid CO<NUM> cylinders) to store <NUM> (~<NUM> liters) liquid CO<NUM>. The capture system has been simulated in flowsheeting software Belsim Vali. CO<NUM> based Rankine cycle (<NUM> and <NUM> bar) is used to extract heat from the exhaust gas stream, and to produce the mechanical power in a turbine. This mechanical power is used in CO<NUM> based heat pump (<NUM> and <NUM> bar) to generate cold utility for removing heat of adsorption from bed and precooling of bed from desorption temperature to adsorption temperature. Further, heat rejected from CO<NUM> based Rankine cycle is used for supplying heat of desorption and preheating of bed from adsorption temperature to desorption temperature. Finally, a compressor is used to compress the product CO<NUM> after the desorption step. The mechanical power generated using turbine is sufficient to run compressor for CO<NUM> based heat pump and compressor for product CO<NUM>.

<FIG> presents composite and grand composite curves for cooling of exhaust gas stream, heat of adsorption and precooling, heat of desorption and preheating, CO<NUM> based Rankine cycle, CO<NUM> based heat pump, and product CO<NUM> compression. In <FIG>, no external hot utility is required to close the heat balance which shows the feasibility of the capture system. The composite curves provides minimum energy targets that can be used in the heat exchanger network design. The systematic approach for heat exchanger network design may give a network with many heat exchangers. In order to keep the practical constraints in mind, a simplified preliminary design for CO<NUM> capture system is illustrated in <FIG>.

The captured CO<NUM> by the system can be used as feedstock to produce gas or liquid green fuels. For <NUM> day operation of the delivery truck (<NUM> travel in <NUM> hours), <NUM> of CO<NUM> will be captured by the proposed system. Table <NUM> presents the conversion of <NUM> of CO<NUM> into fuel by co-electrolysis using renewable electricity (Wang et al. The renewable electricity for CO<NUM> conversion into green fuels can be provided by the PV panels. For calculating total area of PV panels in Switzerland, <NUM> W/m<NUM> average annual solar irradiation (<NUM> MJ/day/m<NUM>; www. meteoswiss. ch) has been considered in Table <NUM>. Further, solar irradiation to electricity conversion efficiency of <NUM>% has been assumed for the PV panels.

The delivery truck consumes <NUM> liters (<NUM>) diesel per day, or <NUM> MJ energy based on the lower heating value of diesel. Assuming same efficiency of the engine for different fuels, Table <NUM> presents amount of alternate fuel used, CO<NUM> produced, CO<NUM> captured, fuel produced using captured CO<NUM>, renewable energy consumed and PV panel area.

The above examples present a system for CO<NUM> capture from exhaust stream of a truck engine. The system design includes integration of temperature swing adsorption, Rankine cycle, heat pump (i.e., cold generation) and CO<NUM> liquefaction on the delivery truck. The proposed system design advantageously has energy self-sufficiency, as it converts waste heat available in the exhaust stream into mechanical energy to drive the heat pump compressor and product compressor.

The system design is an attractive solution due to its low weight and low volume. For daily operation of a delivery truck, the total mass and volume of the adsorbent beds, storage tank and captured CO<NUM> are for instance about <NUM> and <NUM> liters. Average gross weight of a delivery truck is for instance about <NUM>, and so the added extra weight of the CO<NUM> capture system (adsorbent beds and storage tank) will be about <NUM>% of the gross weight of delivery truck. Further, some additional weight and space will be required for piping, turbo-compressors, micro-channel heat exchangers. In general, more than <NUM><NUM> space is available over the truck cabin. Hence, a temperature swing adsorption based CO<NUM> capture system according to the invention can easily be placed for instance over the truck cabin or in another location on a vehicle.

Claim 1:
System (<NUM>) for CO<NUM> capture from a combustion engine (<NUM>) comprising an exhaust gas flow circuit (<NUM>) having an inlet end fluidly connected to an exhaust of the combustion engine, a heat exchanger circuit (<NUM>), a primary exhaust gas heat exchanger (H1) for transferring heat from exhaust gas to fluid in the heat exchanger circuit, at least one compressor (<NUM>) for compressing fluid in a section of the heat exchanger circuit, the compressor driven by thermal expansion of heat exchanger circuit fluid from the primary exhaust gas heat exchanger (H1), and a CO<NUM> temperature swing adsorption (TSA) reactor (<NUM>) fluidly connected to an outlet end of the exhaust gas flow circuit, the TSA reactor including at least an adsorption reactor unit (D4) and a desorption reactor unit (D2), characterized in that the heat exchanger circuit comprising a heating section (12b) for heating the desorption unit (D2) and a cooling section (12a) for cooling the adsorption unit (D4).