US2011185726A1PendingUtilityA1

Energy separation and recovery system for mobile application

Assignee: CLEANPOWER TECHNOLOGY INCPriority: Feb 4, 2010Filed: Feb 4, 2010Published: Aug 4, 2011
Est. expiryFeb 4, 2030(~3.6 yrs left)· nominal 20-yr term from priority
F01K 23/10F01N 5/02F28D 15/0266F28D 21/0003F02G 5/02
42
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Claims

Abstract

An energy separation and recovery system wherein exhaust heat from an automotive engine source which might otherwise be wasted is employed in conjunction with a heat exchanger and a super heater to generate steam in a substantially closed-loop system wherein the heat supply is an open system. The superheated steam is transmitted to an engine to generate power which may be used to supply electrical energy. The electrical energy may be employed external to the system or may be used to assist the motive engine in providing motive power to the vehicle. Stepped diameter tubing carries water, or other vaporizable fluids, through the heat exchanger into the super heater while simultaneously exposing the carried water or fluid to incrementally higher temperature heated gas. Variable bellows, attached operatively to end plates accommodate the differential expansion of the tubing. The energy generation system includes a control module to permit the generation of steam and electricity at such times as there is sufficient heat to permit the generation of superheated steam. The energy separation and recovery system may, alternatively, be employed to provide the power to an engine or other device or may provide an energy source to an alternative power consumption device, such as a refrigeration unit on a vehicle or a cold plate system.

Claims

exact text as granted — not AI-modified
1 . An energy separation and recovery system to recover thermal energy from a provided by an automotive power source comprising a thermal energy transfer core for transferring the thermal energy from the waste energy source to a fluid, vaporizable energy capture medium, the energy capture medium being introduced into the separation and recovery system at a point furthermost from the entrance point of the thermal waste energy, said capture medium being conveyed through a series of interconnected tubes within the separation and recovery system to absorb incrementally the thermal waste energy, wherein the thermal energy transfer core comprises a first energy transfer array disposed towards the furthermost point from the entrance point of the thermal waste energy and a second energy transfer array disposed between the entrance point of the thermal waste energy and the first energy transfer array, the first and second energy transfer arrays being connected to permit continuous flow of the capture medium from the first to the second energy transfer arrays, said first energy transfer array separating sufficient waste energy to vaporize the capture medium and said second energy transfer array separating sufficient energy from the thermal waste energy to superheat the vaporized capture medium. 
     
     
         2 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 1  wherein the recovered energy provides power to a refrigeration unit associated with the mobile power source. 
     
     
         3 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 1  wherein the thermal waste energy consists of a gas which flows in direction opposite to the capture medium. 
     
     
         4 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 1  wherein the first transfer array is comprised of a plurality of tubes parallel to one another. 
     
     
         5 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 4  wherein second transfer array is comprised of a plurality of tubes parallel to one another. 
     
     
         6 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 5  wherein the first and second transfer arrays each have the longitudinal axis of each tube disposed substantially perpendicular to the direction of flow of the thermal waste energy gas. 
     
     
         7 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 6  wherein the first and second transfer arrays are disposed so as to minimize the back pressure upon the thermal waste energy gas. 
     
     
         8 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 6  wherein successive tubes are connected by a virtual pipe bend assembly. 
     
     
         9 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 6  wherein a plurality of successive tubes are connected by means of a head comprise of at least one virtual pipe bend assembly. 
     
     
         10 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 6  wherein the plurality of tubes are rigidly affixed to a tube plate to maintain them in substantially parallel alignment. 
     
     
         11 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 10  wherein the heads are attached to the tube plates and the head and tube plate assembly is flexibly attached to the heat exchanger casing to permit differential expansion of the tubes without loss of energy captured by the fluid capture medium or loss of fluid. 
     
     
         12 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 10  wherein the head and tube assembly is flexibly attached by a bellows arrangement attached between the assembly and the heat exchange casing. 
     
     
         13 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 10  wherein the heads and tube plates may be comprised of materials having different rates of expansion to further seal upon application of heat transfer from the energy capture fluid. 
     
     
         14 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 4  wherein the first transfer array having affixed to at least one tube thereof a vortex fin disposed proximate to the rearmost section of the tube to promote turbulent flow of the thermal waste energy gas. 
     
     
         15 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 14  wherein the turbulent flow thereby permits substantially uniform heat transfer across the first array. 
     
     
         16 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 14  wherein the turbulent flow increases the heat transfer from the gas to the rear of the tube. 
     
     
         17 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 4  wherein the first transfer array having affixed to a plurality of tubes a fin array by thermal brazing or other technique to maximize heat transfer there between. 
     
     
         18 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 5  wherein a dryer is interposed between the first and second transfer arrays. 
     
     
         19 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 1  wherein the recovered energy provides power to the automotive power source. 
     
     
         20 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 19  wherein the recovered energy provides power by driving at least one power element of the power source. 
     
     
         21 . An energy separation and recovery system to recover thermal energy from an automotive power source as claimed in  claim 1  wherein system provides emission control capabilities for the automotive power source. 
     
     
         22 . An energy separation and recovery system to recover thermal energy from an automotive power source comprising a thermal energy transfer core for transferring the thermal energy from the waste energy source to a fluid, vaporizable energy capture medium, the energy capture medium being introduced into the thermal energy transfer core of the separation and recovery system at a point furthermost from the entrance point of the thermal waste energy, said capture medium being conveyed through multiple series of tubes within the separation and recovery system to absorb incrementally the thermal waste energy, wherein the thermal energy transfer core comprises at least two first energy transfer arrays disposed towards the furthermost point from the entrance point of the thermal waste energy and at least two second energy transfer arrays disposed between the entrance point of the thermal waste energy and the at least two first energy transfer arrays, one of the first and one of the second energy transfer arrays being connected to form a first recovery unit to permit continuous flow of the capture medium from said one first energy array to said one second energy transfer array of the first recovery unit, and the other first energy transfer array and the other second energy array arrays being connected to form a second recovery unit to permit continuous flow of the capture medium from said other first energy array to said other second energy transfer array of the second recovery unit, each first energy transfer array separating sufficient waste energy to vaporize the capture medium flowing there through and said second energy transfer array separating sufficient energy from the thermal waste energy to superheat the vaporized capture medium flowing there through. 
     
     
         23 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 22  wherein the recovered energy from one of the two recovery units provides power to a refrigeration unit associate with the mobile power source. 
     
     
         24 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 22  wherein the recovered energy from one of the two recovery units provides power to the automotive power source. 
     
     
         25 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 22  wherein the recovered energy from one of the two recovery units provides power to assist in providing motive energy to the mobile device associated with the power source. 
     
     
         26 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 22  wherein the recovered energy from one of the two recovery units provides power by driving at least one of the power elements of the power source. 
     
     
         27 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 22  wherein the recovered energy from one or both of the two recovery units provides power, alternatively and selectively according to the needs of each system, to the automotive power source or provides motive power to the mobile device or drives at least one of the power elements of the power source. 
     
     
         28 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 22  wherein the thermal waste energy consists of a gas which flows in direction opposite to the capture medium. 
     
     
         29 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 22  wherein each of the first transfer arrays is comprised of a plurality of tubes parallel to one another. 
     
     
         30 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 29  wherein each of the second transfer arrays is comprised of a plurality of tubes parallel to one another. 
     
     
         31 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 30  wherein each of the first and second transfer arrays each have the longitudinal axis of each tube disposed substantially perpendicular to the direction of flow of the thermal waste energy gas. 
     
     
         32 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 31  wherein each of the first and second transfer arrays are disposed so as to minimize the back pressure upon the thermal waste energy gas. 
     
     
         33 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 31  wherein successive tubes within each array are connected by a virtual pipe bend assembly. 
     
     
         34 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 31  wherein a plurality of successive tubes for each array are connected by means of a head comprise of at least one virtual pipe bend assembly. 
     
     
         35 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 31  wherein the plurality of tubes are rigidly affixed to a tube plate to maintain them in substantially parallel alignment. 
     
     
         36 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 35  wherein the heads are attached to the tube plates and the head and tube plate assembly is flexibly attached to the heat exchanger casing to permit differential expansion of the tubes without loss of energy captured by the fluid capture medium or loss of fluid. 
     
     
         37 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 35  wherein the head and tube assembly is flexibly attached by a bellows arrangement attached between the assembly and the heat exchange casing. 
     
     
         38 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 35  wherein the heads and tube plates may be comprised of materials having different rates of expansion to further seal upon application of heat transfer from the energy capture fluid. 
     
     
         39 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 29  wherein each first transfer array has affixed to at least one tube thereof a vortex fin disposed proximate to the rearmost section of the tube to promote turbulent flow of the thermal waste energy gas. 
     
     
         40 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 39  wherein the turbulent flow thereby permits substantially uniform heat transfer across each first array. 
     
     
         41 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 39  wherein the turbulent flow increases the heat transfer from the gas to the rear of the tube. 
     
     
         42 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 29  wherein each of the first transfer arrays has affixed to a plurality of tubes a fin array by thermal brazing or other technique to maximize heat transfer there between. 
     
     
         43 . An energy separation and recovery system to recover thermal energy from a thermal waste energy source as claimed in  claim 30  wherein a dryer is interposed between at least one of the first and second transfer arrays. 
     
     
         44 . An energy separation and recovery system to recover thermal energy from a motive power source as claimed in  claim 21  wherein the system further contains at least one additional burner element to flame off emissions. 
     
     
         45 . An energy separation and recovery system to recover thermal energy form a motive power source as claimed in  claim 12  wherein the system in interposed proximate to the motive power source to provide emission control capability for the mobile power source. 
     
     
         46 . An energy separation and recovery system to recover thermal energy form a motive power source as claimed in  claim 16  wherein the system in interposed proximate to the motive power source to provide emission control capability for the mobile power source. 
     
     
         47 . An energy separation and recovery system to recover thermal energy form a motive power source as claimed in  claim 17  wherein the system in interposed proximate to the motive power source to provide emission control capability for the mobile power source. 
     
     
         48 . An energy separation and recovery system to recover thermal energy form a motive power source as claimed in  claim 18  wherein the system in interposed proximate to the motive power source to provide emission control capability for the mobile power source.

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