RU2008131292A

RU2008131292A - METHOD FOR HEATING AND / OR EVAPORATION OF THE ORGANIC ENVIRONMENT AND HEAT EXCHANGE UNIT FOR REMOVING HEAT FROM A HOT GAS FLOW

Info

Publication number: RU2008131292A
Application number: RU2008131292/06A
Authority: RU
Inventors: Юха ХУОТАРИ (FI); Юха Хуотари; Юха ХОНКАТУКИА (FI); Юха Хонкатукиа
Original assignee: Вяртсиля Биопауэр Ой (Fi); Вяртсиля Биопауэр Ой
Priority date: 2005-12-30
Filing date: 2006-11-10
Publication date: 2010-02-10
Also published as: WO2007077293A1; CA2632275C; CA2632275A1; EP1966559A4; FI20055718A0; RU2403522C2; FI120557B; EP1966559A1; EP1966559B1; UA92777C2; FI20055718L

Abstract

1. Способ нагрева и/или испарения органической среды путем переноса теплоты из потока газа в органическую среду, при котором органическую среду пропускают через несколько последовательных теплообменников (21, 22, 23, 24), расположенных в потоке газа, и поток газа охлаждают от начальной температуры до конечной температуры, и при этом теплоту переносят в первый теплообменник (21) в направлении потока органической среды для охлаждения потока газа до его конечной температуры, отличающийся тем, что теплоту переносят во второй теплообменник (22) для начала охлаждения потока газа от его начальной температуры. ! 2. Способ по п.1, отличающийся тем, что органическая среда течет сначала через первый (21) теплообменник, а затем через второй (22) теплообменник. ! 3. Способ по п.1, отличающийся тем, что последний теплообменник (24) работает в первую очередь в соответствии с принципом параллельных потоков. ! 4. Способ по п.3, отличающийся тем, что все теплообменники после первого (21) теплообменника работают в основном как теплообменники с параллельными потоками. ! 5. Теплообменный блок для извлечения теплоты из потока горячего газа в поток среды, содержащий охватывающую конструкцию (30 31, 31'), впуск (25') для газа, в котором газ течет по существу в вертикальном направлении, и выпускное отверстие (36) для газа, в котором охватывающая конструкция теплообменного блока охватывает несколько теплообменников (21, 22, 23, 24), снабженных по существу газонепроницаемой стенкой и расположенных по меньшей мере частично один в другом относительно продольной оси (26) охватывающей конструкции, так, что поток газа каждый раз проходит в пространстве, образованном двумя распол1. A method of heating and / or evaporation of an organic medium by transferring heat from a gas stream to an organic medium, in which the organic medium is passed through several successive heat exchangers (21, 22, 23, 24) located in the gas stream, and the gas stream is cooled from the initial temperature to the final temperature, and at the same time the heat is transferred to the first heat exchanger (21) in the direction of the flow of the organic medium to cool the gas stream to its final temperature, characterized in that the heat is transferred to the second heat exchanger (22) to start cooling the gas stream from its initial temperature. ! 2. A method according to claim 1, characterized in that the organic medium flows first through the first (21) heat exchanger and then through the second (22) heat exchanger. ! 3. A method according to claim 1, characterized in that the last heat exchanger (24) operates primarily according to the parallel flow principle. ! 4. A method according to claim 3, characterized in that all heat exchangers downstream of the first (21) heat exchanger operate essentially as parallel flow heat exchangers. ! 5. A heat exchange unit for extracting heat from a hot gas stream into a medium stream, comprising an enclosing structure (30 31, 31 '), a gas inlet (25') in which the gas flows in a substantially vertical direction, and an outlet (36) for gas, in which the enclosing structure of the heat exchange unit encloses several heat exchangers (21, 22, 23, 24) provided with a substantially gas-tight wall and located at least partially one in the other relative to the longitudinal axis (26) of the enclosing structure, so that the gas flow each time it passes through the space formed by two locations

Claims

1. The method of heating and / or evaporation of an organic medium by transferring heat from a gas stream to an organic medium, in which the organic medium is passed through several successive heat exchangers (21, 22, 23, 24) located in the gas stream, and the gas stream is cooled from the initial temperature to a final temperature, and the heat is transferred to the first heat exchanger (21) in the direction of the flow of the organic medium to cool the gas stream to its final temperature, characterized in that the heat is transferred to the second heat exchanger (22) for ala cooling gas flow from its initial temperature.

2. The method according to claim 1, characterized in that the organic medium flows first through the first (21) heat exchanger, and then through the second (22) heat exchanger.

3. The method according to claim 1, characterized in that the last heat exchanger (24) works primarily in accordance with the principle of parallel flows.

4. The method according to claim 3, characterized in that all the heat exchangers after the first (21) heat exchanger work mainly as heat exchangers with parallel flows.

5. A heat exchange unit for extracting heat from a hot gas stream into a medium stream comprising a female structure (30 31, 31 '), a gas inlet (25') in which gas flows in a substantially vertical direction, and an outlet (36) for gas, in which the enclosing structure of the heat exchanger unit covers several heat exchangers (21, 22, 23, 24) provided with a substantially gas-tight wall and located at least partially in one another relative to the longitudinal axis (26) of the enclosing structure, so that the gas flow every time about is enclosed in a space formed by two heat exchangers arranged one inside the other, characterized in that the female structure comprises a bottom section (31 '), on which the heat exchangers are mainly supported by the supporting structure (32), and that the supporting structure comprises a surface (28) with openings in at least one of the heat exchangers for passing through the gas stream from the first side of the heat exchanger to its second side.

6. Block according to claim 5, characterized in that the supporting structure is made of a cooling structure (32), in which the flow of the heat exchanger flows.

7. Block according to claim 6, characterized in that the heat exchangers are spiral tubular heat exchangers (20) and that the cooling structure of the supporting structure comprises a tap made in the form of a flow elbow from a tubular spiral.

8. The block according to claim 5, characterized in that the surface (28) with the holes is located so that it passes some distance from the inner surface from the bottom section of the enclosing structure, so that in the area above the bottom section an ash space (39) is formed, passing from the inner surface of the bottom section to the lower edge of the surface with holes.

9. The block of claim 8, characterized in that the sum of the cross sections of the individual holes forming a surface with holes is greater than the total cross-sectional area of the annular space.

10. The block according to claim 8, characterized in that it contains several pipes (38) for removing ash, which are made with the possibility of opening in the ash space (39).

11. The block according to claim 10, characterized in that the ash removal pipe (38) comprises a substantially gas-tight channel, hermetically passing into the supporting structure of the heat exchanger.

12. The unit according to claims 5-8, configured to heat and / or vaporize the organic medium, characterized in that the last of the heat exchangers located one inside the other is configured to be the first heat exchanger (21) in the medium stream, and the first of heat exchangers located one inside the other, made with the possibility of being the second heat exchanger (22) in the fluid stream.