EP2132489A1

EP2132489A1 - System concept with low energy requirement and improved energy yield

Info

Publication number: EP2132489A1
Application number: EP08717424A
Authority: EP
Inventors: Claus Peter Kluge
Original assignee: Ceramtec GmbH
Current assignee: Ceramtec GmbH
Priority date: 2007-03-06
Filing date: 2008-03-05
Publication date: 2009-12-16
Also published as: JP2010532909A; JP5868295B2; CN101688668B; US9091437B2; AU2008223853B2; DE102008000527A1; CN101790663B; KR20090119780A; JP2010520408A; WO2008107457A1; CN101688668A; AU2008223853A1; JP2013047601A; DE102008000528A1; RU2009136638A; US20100050629A1; US20100047639A1; WO2008107458A1; KR101495504B1; JP5453114B2

Abstract

The invention relates to a method for the environmentally sound disposal of air/solvent mixtures (5) made of combustible gaseous, vaporous or liquid waste products, using a combustion unit (1) for burning the air/solvent mixtures (5) while removing the environmentally compatible exhaust air (2) developing in the combustion unit (1) and the waste heat (3) that is produced. In order to ensure that the air/solvent mixtures (5) can be decomposed without continuously supplying combustible substances, according to the invention the air/solvent mixtures (5) are fed partially or completely to a recovery unit (6) and converted there into a usable form of energy (22, 24, 7), and these mixtures are fed partially or completely to the combustion unit (1) for combustion and thereby during operation the combustion unit (1) is supplied partially or completely with fuel.

Description

Plant concept with lower energy consumption and improved energy yield

The invention relates to a method for the environmentally sound disposal of air / solvent mixtures consisting of combustible gaseous, vapor or liquid waste, with a combustion unit for combustion of the air / solvent mixtures with removal of the resulting in the combustion unit environmentally friendly exhaust air (2) and the waste heat generated.

According to the prior art (see Figures 1 and 2), for example, air / solvent mixtures of thermal afterburning (TNV) must be supplied in order to prevent harmful substances from entering the environment. For reasons of prescribed safety, for example, air / solvent mixtures as they leave the user process must be diluted with air so that no ignitable mixture is formed. This lean air is fed to the thermal afterburning. In some cases, the mixture air is preheated with the waste heat of the subsequent combustion process, before it reaches the combustion chamber of the thermal afterburning.

Preheated or not, the air / solvent mixture enters the combustion chamber and is usually supplied with fuel, e.g. Fuel gas or electric energy fired. Also conceivable are catalytic afterburning.

If, instead of thermal afterburning, a fuel cell (BSZ) is used, then the air / solvent mixture can also be burned, for example, to maintain the operating temperature. The electrical power is generated via a separate circuit of fuel gas or combustible materials.

K \ ausland \ OZ07018 doc The concepts of the prior art require fuel gas to burn combustible materials.

The invention has for its object to improve a method for the environmentally sound disposal of air / solvent mixtures according to the preamble of claim 1 so that the air / solvent mixtures can be decomposed without continuous supply of combustibles.

According to the invention, this object is achieved in that the air / solvent mixtures are partially or completely fed to a recovery unit and converted into a usable form of energy and these are partially or completely supplied to the combustion unit for combustion and thereby during operation, the combustion unit partially or completely by itself Fuel is supplied. Air / solvent mixtures is understood as meaning air and / or inert gas and / or mixtures thereof with combustible or combustible substances (hereinafter also referred to as a mixture).

The usable form of energy according to the invention is preferably electricity, gas, steam or a combustible or combustible condensate. The condensate will be discussed in detail below.

In an inventive embodiment, the air / solvent mixtures in the recovery unit are fed to a Stirling engine and, for example, generates electricity in combination with a generator. The air / solvent mixtures drive the Stirling engine and this the generator.

In another inventive embodiment, the air / solvent mixtures in the recovery unit in a water vapor

K \ ausland \ OZ07018 doc Converted conversion plant to steam and fed the steam into use.

In one embodiment, the steam is supplied to a generator for generating electricity.

In another embodiment, the air / solvent mixtures in the recovery unit are condensed out in a condensation device and the resulting combustible condensate is burned in the combustion unit.

The waste heat generated in the combustion unit and / or the current is supplied to the recovery unit for condensing the air / solvent mixture according to the invention.

During operation, the method or system concept according to the invention uses largely or exclusively the energy which is contained in the combustible substance which has previously been condensed out of the air / solvent mixture. Only starting up can optionally be carried out with a conventional fuel, such as fuel gas.

In an embodiment according to the invention, the condensate produced in the recovery unit or, in general, the usable forms of energy generated in the recovery unit are conducted into a tank and supplied from there to the combustion unit as required. The tank also serves as a buffer and can be filled with a quantity of flammable substance (fuel) necessary for starting the plant. Another tank may also be used for the intermediate storage of combustible and / or combustible substances or the mixture.

In a development of the invention, the combustion unit is a conventional thermal afterburner and / or a fuel cell system.

K \ ausland \ OZ07018 doc which is generally an energy conversion system which generates heat and / or cold or electrical energy from materials.

In a further embodiment of the invention, the recovery unit is an absorption plant, condensation plant, inversion refrigeration plant or adsorption onsanlage.

Preferably, the combustion unit is operated evenly by continuous removal of condensate from the tank.

The condensate in the tank is in one embodiment of non-fossil origin, such as bio-ethanol or bio-butanol.

In a further development of the invention, pure substances of combustible or combustible substances or even mixtures of at least 2 different combustible or combustible substances are processed in the recovery unit, which may also be mixed with non-combustible or non-combustible substances such as water.

It is also possible to operate the combustion unit in partial operation, wherein in addition to the condensate from the tank, fuel gas / fuel and / or electric current and / or supply air is also introduced into the combustion unit for combustion.

In one development of the invention, the combustible or combustible substances are completely or almost completely removed from the mixture or the air / solvent mixture, and the residual gas component is supplied from the mixture to the supply air of the combustion unit.

K \ ausland \ OZ07018 doc In an inventive embodiment, the amount of heat or waste heat produced in the combustion unit is used partially or completely to operate a Stirling engine.

The energy converted in the Stirling engine is preferably used for driving purposes. The Stirling engine can also drive a generator that generates electrical energy. Thus, the air / solvent mixture in the recovery unit is converted to electricity as a usable form of energy. This stream can then be reintroduced into the combustion unit for combustion of the air / solvent mixture.

In another application, the amount of heat produced in the combustion unit is used partially or completely to generate water vapor.

The resulting water vapor can then be used again for driving purposes.

In an inventive embodiment, the water vapor drives a generator which generates electrical energy, i. Electricity generated.

The resulting water vapor can also be used for sterilization purposes.

In a preferred inventive embodiment, the thermal energy supplied from the combustion unit of the recovery unit is distributed in the recovery unit to various types of use. This means that in the recovery unit different usable forms of energy are generated.

In the recovery unit, in one embodiment, different types of use are cascaded or operated in combination.

K \ ausland \ OZ07018 doc During operation, the method or system concept according to the invention uses largely or exclusively the energy which is contained in the combustible substance, which has previously been condensed out, for example, from the air / solvent mixture. Only the starting can optionally be done with a conventional fuel gas, or provided in the system as a buffer tank can be filled with a necessary to start the system amount of combustible material.

With the waste heat produced in the combustion unit during combustion, it is now possible, e.g. an inversion cooling system or an adsorption system are operated, which condenses the required for own operation fuel from the air / solvent mixture as part of the process or Anlagenkon- concept. From an environmental point of view, this would eliminate the need for fossil fuel gas.

If this process or system concept is operated with thermal afterburning, the combustible liquid substance is removed from the tank and treated with air to form an ignitable mixture in the combustion unit. After ignition, the combustible substance may burn and become carbon dioxide and water, and the released energy is used in the above-mentioned recovery unit to carry out the substance extraction or condensation.

If, instead of a thermal afterburning, a fuel cell is used, it is possible to extract electrical energy from the substance in addition to the waste heat.

The invention will be described with reference to figures.

Figure 1 shows the state of the art, i. a schematic diagram of a process for the environmentally sound disposal of air / solvent mixtures 5, which consist of combustible

K \ ausland \ OZ07018 doc Ren waste or liquid waste materials consist, with a combustion unit 1 with removal of the resulting in the combustion unit 1 environmentally friendly exhaust air 2 and the generated waste heat 3 and / or stream. 4

The combustion unit 1 is here a thermal post-combustion plant 9, into which an air / solvent mixture 5 is introduced. The air / solvent mixture 5 has been diluted with air so far that no ignitable mixture is present. This lean air is fed to the thermal afterburning. For combustion, a fuel / fuel gas 11 and / or electrical energy 12, ie, electricity are introduced into the afterburner 9. From the after-combustion unit 9, the exhaust air 2 (CO ₂ / H ₂ O) and the waste heat 3 are discharged. It is also known to use the waste heat 3 for preheating the air / solvent mixture 1.

FIG. 2 also shows the state of the art, except that a fuel cell system 10 is used here as the combustion unit 1, into which an air / solvent mixture 5 is introduced. The air / solvent mixture 5 has also been diluted with air so far that there is no ignitable mixture. This lean air is supplied to the fuel cell system 10. In the fuel cell system 10, a fuel / fuel gas 11, hydrogen 13 and / or electrical energy 12, i. Electricity introduced. From the fuel cell system 10, the exhaust air 2, the waste heat 3 and 4 stream are discharged.

Figure 3 describes the inventive coupling of combustion unit 1 and recovery unit 6, wherein the combustion unit 1 performs a conversion of the air / solvent mixture 5 in heat energy and exhaust air or exhaust gas. The combustion unit 1 supplies the recovery unit 6 with waste heat recovered from the combustible or combustible matter.

K \ ausland \ OZ07018 doc One part of the air / solvent mixture 5 is thus introduced directly into the combustion unit 1 and another part or the remainder is introduced into the recovery unit where it is converted into usable forms of energy and these are then introduced into the combustion unit for maintaining the combustion ie the combustion process.

The recovery unit 6 separates the air / solvent mixture 5. The combustible or combustible material (e.g., the condensate 7) is transferred to a tank 8 from which, in turn, the combustion unit 1 can remove the fuel necessary for operation.

In the recovery unit 6 so the air / solvent mixture 5 is introduced and condensed out there. The condensate 7 is passed into a tank 8. In addition to the air / solvent mixture 5 6 exhaust air 2 and / or waste heat 3 is introduced into the recovery unit, which is obtained in the combustion unit 1. This is, possibly supplemented by electrical energy 12, used for the conversion or condensation. The exhaust air 17 accumulating in the recovery unit 6 is e.g. removed from the recovery unit 6 and introduced into the combustion unit.

In the tank 8, the condensate 7 is stored until it is introduced as a liquid combustible substance 15 in the combustion unit 1 or another use 14 is supplied. Optionally, a further material conversion 16 can also be carried out in a corresponding converter, with the material conversion 16 being able to be supplied with electrical energy or process heat.

The combustion unit 1 is in this embodiment, a thermal afterburner 9, in which the liquid combustible material 15 is burned. In addition to supporting the combustion process, fuel / fuel gas 11 and / or electrical energy 12 can be introduced into combustion unit 1.

K \ ausland \ OZ07018 doc be directed. The exhaust air 2 and waste heat 3 of the combustion process is transferred to the recovery unit 6, where it is used for the condensation of the air / solvent mixture 5. The exhaust gas 18 (CO ₂ / H ₂ O) is discharged.

FIG. 4 describes the coupling according to the invention of combustion unit 1, in this case a fuel cell system 10, and recovery unit 6, wherein combustion unit 1 converts the substance or liquid combustible substance 15 into electrical energy 12 or thermal energy 3 or exhaust air 2 or exhaust gas 18. The combustion unit 1 supplies the recovery unit 6 with waste heat 3 or exhaust air 2, which has been obtained from the combustible or combustible substance 15. Furthermore, the incinerator 1 can provide electrical energy 12 for the operation of the plant or for other consumers.

The recovery unit 6 separates the air / solvent mixture 5. The combustible or combustible substance or the condensate 7 is transferred into a tank 8, from which in turn the combustion unit 1 can remove the fuel necessary for the operation.

In the recovery unit 6 so the air / solvent mixture 5 is introduced and condensed out there. The condensate 7 is passed into a tank 8. In addition to the air / solvent mixture 5, exhaust air 2 and / or waste heat 3, which is obtained in the combustion unit 1, is introduced into the recovery unit 6. This is, possibly supplemented by electrical energy 12, used for the conversion or condensation. The exhaust air 17 obtained in the recovery unit 6, possibly including a remainder of the air / solvent mixture 5, is removed from the recovery unit 6 and can optionally be supplied to the fuel cell system 10.

K \ ausland \ OZ07018 doc In the tank 8, the condensate 7 is stored until it is introduced as a liquid combustible substance 15 in the combustion unit 1 or another use 14 is supplied.

In this embodiment, the combustion unit 1 is a fuel cell system 10 in which the liquid combustible substance 15 is burned. In addition to supporting the combustion process, fuel / fuel gas 11 and / or electrical energy 12 and / or supply air 19 can be introduced into combustion unit 1. The exhaust air 2 and waste heat 3 of the combustion process is transferred to the recovery unit 6, where it is used for the condensation of the air / solvent mixture 5. The exhaust gas 18 (CO ₂ / H ₂ O) is discharged.

FIG. 5 schematically shows the recovery plant 6, or into which usable forms of energy the introduced air / solvent mixture 5 is converted. The air / solvent mixture 5, optionally electrical energy 12 and / or exhaust air 2 and waste heat 3 from the combustion unit are introduced as input into the recovery plant 6.

In the recovery plant 6, the air / solvent mixture 5 is then converted, e.g. for driving a Stirling engine 20, which in turn drives a generator 21 for generating power 22. In another or additional application form, the air / solvent mixture 5 is converted into steam 24 in a steam conversion unit 23, and the steam 24 is put to use. In another or additional application form, the air / solvent mixture 5 is condensed out in a condenser 26 and the resulting combustible condensate 7, for example. passed into the combustion unit and burned there or partially fed to another form of use.

K \ ausland \ OZ07018 doc In the following, features of the method according to the invention, hereinafter also referred to as the system concept, will be described.

1. The plant concept is used for the environmentally sound disposal of mixtures of air and combustible or combustible substances and avoids the use of additional fuel gas for the combustion of combustible or combustible substances.

2. The plant concept is characterized in that a coupling of combustion unit and recovery unit is made. Combustion units can be, for example, conventional thermal afterburning plants or fuel cell plants of the most diverse designs or, in general, energy conversion systems which generate heat or cold or electrical energy from materials. Recovery units may be, for example, absorption plants, condensation plants, inversion refrigeration plants, adsorption plants.

3. The combustion unit is not dependent on the constant concentration of combustible substances in the air mixture, but can be operated evenly by the continuous removal of combustible substances from the tank.

4. Due to the continuous removal of combustible substances from the tank, the plant can also be operated when the supply of

Air / solvent mixture or condensate or flammable liquid should be interrupted.

5. By using a fuel cell system, in addition to the waste heat and electric power can be obtained from the combustible material.

K \ ausland \ OZ07018 doc 6. The combustible substance from the tank does not have to be completely recycled via the plant concept, but can optionally be used partly for other applications.

7. The substance stored in the tank by the recovery unit may not be of fossil origin either. One example is bioethanol.

8. The essential feature of the coupling of the combustion unit with the recovery unit is the transfer of waste heat in exhaust air or exhaust gas. Depending on the combustion unit used, electrical current can also be included in the coupling.

9. The characteristic of the coupling of the recovery unit with the combustion unit is the transfer of combustible or combustible materials.

10. The process may be used to process pure substances from combustible or combustible substances or mixtures of at least 2 different combustible or combustible substances.

11. The process may be used to process pure substances of combustible or combustible substances or mixtures of at least 2 different combustible or combustible substances mixed with non-combustible or non-combustible substances such as water.

K \ ausland \ OZ07018 doc

Claims

claims

Process for the environmentally sound disposal of air / solvent mixtures (5), consisting of combustible gaseous, vaporous or liquid waste, with a combustion unit (1) for the combustion of the air / solvent mixtures (5) with removal in the

Combustion unit (1) resulting environmentally friendly exhaust air (2) and the generated waste heat (3), characterized in that the air / solvent mixtures (5) partially or completely fed to a recovery unit (6) and there in a usable form of energy (22, 24, 7 ) and these are partially or completely supplied to the combustion unit (1) for combustion, and thereby during operation of the combustion unit (1) is supplied partially or completely by itself with fuel.

2. The method according to claim 1, characterized in that the usable form of energy stream (22), gas, steam (24) or a combustible condensate

(7).

3. The method according to claim 2, characterized in that the air / solvent mixtures (5) in the recovery unit (6) a Stirling engine (20) supplied and, for example, in combination with a generator (21) current (22) is generated.

4. The method according to claim 2, characterized in that the air / solvent mixtures (5) in the recovery unit (6) in a steam conversion system (23) to steam (24) are converted and the steam (24) is fed to a use.

K \ ausland \ OZ07018 doc

5. The method according to claim 4, characterized in that the steam (24) is supplied to a generator (21) for generating electricity (22).

6. The method according to claim 1 or 2, characterized in that the air / solvent mixtures (5) in the recovery unit (6) in a

Condensation device (26) are condensed out and the resulting combustible condensate (7) in the combustion unit (1) is burned.

7. The method according to claim 6, characterized in that in the combustion unit (1) generated waste heat (3) and / or the stream (4), the recovery unit (6) for condensing the air / solvent mixture (5) is supplied.

8. The method according to claim 6 or 7, characterized in that in the recovery unit (6) generated condensate (7) is passed into a tank (8) and from there as needed to the combustion unit (1) is supplied.

9. The method according to any one of claims 6 to 8, characterized in that the combustion unit (1) is a conventional thermal afterburner system (9) and / or a fuel cell system (10) or generally an energy conversion system, which consists of materials heat and / or cold or generates electrical energy.

10.Verfahren according to any one of claims 6 to 9, characterized in that the recovery unit (6) is an absorption plant, condensation plant, inversion refrigeration plant or adsorption plant.

K \ ausland \ OZ07018 doc

11. The method according to any one of claims 6 to 10, characterized in that the combustion unit (1) by continuous removal of condensate (7) from the tank (8) is operated evenly.

12. The method according to any one of claims 6 to 11, characterized in that the condensate (7) in the tank (8) is not of fossil origin, such as biological

Ethanol or bio-butanol.

13. The method according to any one of claims 6 to 12, characterized in that in the recovery unit (6) pure substances of combustible o- flammable substances or mixtures of at least 2 different combustible or combustible materials are processed, which also with incombustible or non-combustible substances such as water may be mixed.

14. The method according to any one of claims 1 to 13, characterized in that the combustion unit (1) is operated in partial operation, wherein in addition to the condensate (7) from the tank (8) and fuel gas / fuel (11) and / or electric current (12) and / or supply air (19) for combustion in the combustion unit (1) is initiated.

15. The method according to any one of claims 1 to 9, characterized in that from the air / solvent mixture (5) the combustible or combustible substances are completely or almost completely removed and the

Residual gas from the mixture (5) of the supply air (19) of the combustion unit (1) is supplied.

16. The method according to any one of claims 1 to 15, characterized in that in the combustion unit (1) resulting amount of heat partially.

K \ ausland \ OZ07018 doc wise or completely used to operate a Stirling engine (20).

17. The method according to claim 16, characterized in that in the Stirling engine (20) converted energy is used for driving purposes.

18. The method according to claim 16 or 17, characterized in that the

Stirling engine (20) drives a generator (21) which generates electrical energy (22).

19. The method according to any one of claims 1 to 18, characterized in that in the combustion unit (1) resulting amount of heat partially or completely used to produce water vapor (24).

20. The method according to claim 19, characterized in that the resulting water vapor (24) is used for driving purposes.

21. The method according to claim 19 or 20, characterized in that the water vapor (24) drives a generator (21), which generates electrical energy e- (22).

22. The method according to claim 19, characterized in that the resulting water vapor (24) is used for sterilization purposes.

23. The method according to any one of claims 1 to 22, characterized in that from the combustion unit (1) of the recovery unit (6) supplied heat energy in the recovery unit (6) is distributed in different ways of use.

K \ ausland \ OZ07018 doc

24. The method according to claim 23, characterized in that in the recovery unit (6) different types of use are cascaded or operated in combination.

K \ ausland \ OZ07018 doc