DE202013103888U1 - Device for the chemical and energetic utilization of flue gas - Google Patents

Abstract

Device for the chemical and energetic utilization of flue gas, characterized in that this 1.1. a reprocessing stage and a recycling stage, 1.1.1. the work-up stage from 1.1.1.1. a heat exchanger (1) and 1.1.1.2. four gas treatment reactors (2 to 4) connected in series, 1.1.1.3. and each of the gas treatment reactors (2 to 4) has, in addition to the gas supply and the gas discharge, a device for supplying (Zs1 to Zs4) the reaction mixture, 1.1.1.4. Furthermore, the discharge of the reaction mixture of the first gas treatment reactor (2) is connected to a treatment (6) and 1.1.1.5. the discharges of the reaction mixture of the other gas treatment reactors (3 to 5) are connected to a fertilizer treatment (7), 1.1.1.5.1. The fertilizer treatment (7) has a feed for potassium dihydrogen phosphate (KDHP), a fertilizer discharge (D) and a water discharge (W), 1.2. that the utilization stage consists essentially of a water electrolysis (8), a methane reactor (9) and a combined heat and power plant (CHP), 1.2.1. in which the current (ST) necessary for water electrolysis (8) is supplied from at least one regenerative source, 1.2.2. an oxygen line (O2) connects the water electrolysis (8) directly to the combined heat and power plant (CHP), 1.2.3. a hydrogen line connects the water electrolysis (8) directly to the methane reactor (9), 1.2.4. wherein the methane reactor (9) is connected via a further feed line to the output of the work-up stage, and 1.2.5. one from the methane reactor (9) outgoing Methanleitung the methane produced in the cogeneration plant (CHP) supplies.

Description

The invention relates to a device for the chemical and energetic utilization of flue gas and is for the recovery of flue gas, which comes from power plants, incinerators, combined heat and power plants, gas turbines, the cement industry and other industries suitable. In all processes that generate energy from fossil fuels or organic materials, the carbon contained in it in the form of CO ₂ as a component of the flue gas accumulates. However, since the fuels still contain a variety of other substances, their combustion products and at high combustion temperatures oxides of nitrogen contained in the combustion air are also included in the flue gas.

These countless admixtures make it difficult to continue using the CO ₂ share.

For individual components that have been found to be particularly disturbing, various proposals have already been proposed for chemical and / or physical workup.

The US 8,346,394 B2 proposes a power plant operating system that minimizes the impact of CO ₂ capture and compression on power plant performance by using the power consumption of the CO ₂ capture system to control the plant's net performance.

From the DE 10 2011 010 743 A1 is already known an exhaust system with a mixing device for mixing a introduced into the exhaust gas reducing agent with exhaust gas.

The DE 10 2008 061 258 A1 describes a process for the separation of gaseous components from a gas stream, in particular CO ₂ from the flue gas of a fossil-fired power plant, under atmospheric pressure. The CO ₂ -containing flue gas is supplied with an absorbent liquid to produce a bubble column in a sump volume or in a reaction volume of a filler having absorber and brought into contact therewith. For this purpose, the flue gas, the sump volume or the reaction volume of the absorber is to be supplied by means of at least one self-priming gassing stirrer or a Strahldüsendispergierers and exposed in the absorbent liquid to the action of an ultrasonic generator or Ultraschalldispergierers.

A method for purifying flue gases resulting from the combustion of heavy oil and diesel fuels, in particular for operating watercraft and oil rigs, is disclosed in US Pat DE 10 2010 016 004 A1 described. The sulfur-containing flue gases produced during the combustion of heavy fuel and diesel fuels are passed as combustion residues into a reactor. In this case, soot particles and dusts are to be separated by adsorption or absorption of sorbent in a first step from the gas stream. In a second, subsequent step, sulfur-containing constituents are removed from the gas stream by dry sorption. Finally, the gases are discharged through a chimney.

The WO 2007/073881 A1 discloses a device for mixing a fluid with a large gas flow rate flowing in a gas channel, in particular for introducing a reducing agent into a flue gas containing nitrogen oxides. At least one nozzle lance with a nozzle for the supply of the fluid should ensure, in the case of a short mixing path, that the evaporated, gaseous fractions contained in the jet of jet exiting from the atomizer nozzles enter the flow vortex.

From the EP 0780151 B1 Finally, a method for controlling the oxidation of the sulfites in a flue gas desulfurization process is known in which sulfur oxide-containing waste gas is treated with an absorption liquid containing a calcium compound. An oxygen-containing gas is passed through the absorption liquid containing the resulting calcium sulfite to oxidize the calcium sulfite to form gypsum.

In none of these methods or these devices, the entire complex of ingredients is processed so far that then a recycling of CO _{2 is} possible.

The object of the invention is therefore to propose a device for the chemical and energetic utilization of flue gas, obtained in the end products as pure CO ₂ in a mixture with nitrogen and an agriculturally usable fertilizer salt. The aim is to demonstrate a possibility that the CO _{2 is used} for temporary storage of the electrical energy generated from sunlight and wind power.

This is according to the invention with a device according to the features of the main claim 1 and the method of using the device according to the main claim 2 solved. In the further method claims further useful embodiments of the method are proposed.

A device according to the invention consists of a reprocessing stage and a recycling stage. This can be flue gas (RG) that out Power plants, incinerators, combined heat and power plants, gas turbines, the cement industry and other industries.

The work-up stage consists of a heat exchanger ( 1 ) and four gas treatment reactors ( 2 to 4 ), which are connected in a row, composed.

In the heat exchanger ( 1 ), the flue gas (RG) is cooled down to the temperature necessary for the further process steps.

Gas treatment reactors ( 2 to 4 ) have in addition to the gas supply and the gas discharge per a means for supplying (Zs1 to Zs4) of the required reaction mixture.

In the first gas treatment reactor ( 2 ), the flue gas (RG) is treated by means of an aqueous solution of diamonium glycol salt (Zs1). As a result, the organic components and fine dust, which are loaded with carcinogenic substances, especially with polycyclic aromatic hydrocarbons, phenols, dioxins, furans and formaldehydes, removed by organic scrubbing. The first gas treatment reactor ( 2 ) is for the derivation of the reaction mixture with a treatment ( 6 ) connected. In this, the gas treatment reactor ( 2 ) used Diamoniumglykolsalz (Zs1) using the heat exchanger ( 1 ) waste heat from the waste sludge (AS) separately.

A recycle line recycles unused diamonium glycol salt to feed (Zs1).

In the second gas treatment reactor ( 3 ) are then converted with an aqueous solution of potassium hydroxide and urea (Zs2) in the flue gas (RG) nitrogen compounds to nitrate salts (N).

In the third gas treatment reactor ( 4 ) are then the sulfur compounds contained in the flue gas (RG) with an aqueous solution of calcium phosphate and urea (Zs3) in sulfate salts (S) involved. Furthermore, in the fourth gas treatment reactor ( 5 ) the halogen compounds contained in the flue gas (RG) with an aqueous solution of ammonium salts and urea (Zs4) in halogen salts (H).

The derivatives of the spent reaction mixtures of the other gas treatment reactors ( 3 to 5 ) are treated with a fertilizer preparation ( 7 ) connected. Here finally nitrate salt (N), sulfate salt (S) and halogen salt solutions (H) from the gas treatment reactors from water (H ₂ O) are separated and with the addition of potassium dihydrogen phosphate (KDHP), which is added to stabilize the pH of the fertilizer salt , recycled to fertilizer.

Fertilizer salt and water are removed separately via a fertilizer discharge (D) and a water discharge (W).

The subsequent recycling stage consists essentially of a water electrolysis ( 8th ), a methane reactor ( 9 ) and a combined heat and power plant (CHP).

The for water electrolysis ( 8th ) required power (ST) is supplied from at least one regenerative source. This can be skimmed especially current not required power from these sources.

In the water electrolysis ( 8th ) becomes process water, which is used, for example, in fertilizer 7 ), decomposed into oxygen (O ₂ ) and hydrogen (H ₂ ). The oxygen is supplied via an oxygen line (O ₂ ) directly to the combined heat and power plant (CHP).

The hydrogen (H ₂ ) passes through a hydrogen line (H ₂ ) from the water electrolysis ( 8th ) directly into the methane reactor ( 9 ).

Via another supply line, the methane reactor ( 9 ) supplied in the purification process purified flue gas (N ₂ + CO ₂ ).

In this methane reactor ( 9 ) is synthesized under the supply of hydrogen and CO ₂ methane. The heat required for methane synthesis comes from special solar panels ( 13 ) which generate temperatures of 350 to 450 ° C.

Methane (CH ₄ ) and oxygen (O ₂ ) can now be stored at short notice. In times of higher power consumption, it is possible to use the produced methane with the water electrolysis ( 8th ) formed oxygen (O ₂ ) in a cogeneration plant (CHP) electric power and heat are generated.

The invention will be described below with reference to the drawings 1 and 2 be explained in an embodiment.

Showing:

1 a schematic representation of the processing stage and

2 a schematic representation of the utilization stage.

The facility consists of a refurbishment stage and a recycling stage.

The work-up stage consists of a heat exchanger 1 and four gas treatment reactors 2 to 4 , which are connected in a row, composed.

In the heat exchanger 1 the flue gas RG is cooled down to the temperature necessary for the further process steps.

The gas treatment reactors 2 to 4 have in addition to the gas supply and the gas discharge per a means for supplying Zs1 to Zs4 of the required reaction mixture.

In the first gas treatment reactor 2 For example, the organic components and fine dusts are removed from the flue gas RG by means of an aqueous solution of diamonium glycol salt Zs1.

In the treatment 6 this will be in the gas treatment reactor 2 used Diamoniumglykolsalz Zs1 using the heat exchanger 1 accumulating waste heat separated from the waste sludge AS.

A recycle line recycles unused diamonium glycol salt to feed Zs1.

In the following gas treatment reactors 3 to 5 Subsequently, with aqueous solutions of potassium hydroxide, calcium phosphate and ammonium salts and urea, the nitrogen compounds contained in the flue gas RG to nitrate salts N, the sulfur compounds to sulfate salts S and the halogen compounds to halogen salts H converted.

The derivatives of the spent reaction mixtures of the gas treatment reactors 3 to 5 are with a fertilizer treatment 7 connected. Here, nitrate salt solutions N, sulfate salt solutions S and halogen salt solutions H from the gas treatment reactors are finally separated from the water H ₂ O and treated with the addition of potassium dihydrogen phosphate KDHP, which is added to the fertilizer salt to stabilize the pH to fertilizer.

Fertilizer salt and water are discharged separately via a fertilizer discharge D and a water discharge W.

The purified flue gas is fed to the subsequent recycling stage. This consists essentially of a water electrolysis 8th , a methane reactor 9 and a combined heat and power plant CHP.

The water electrolysis 8th necessary electricity ST is provided by wind power and photovoltaic systems.

In the water electrolysis 8th Water is decomposed into oxygen O ₂ and hydrogen H ₂ . The oxygen is supplied via an oxygen line O ₂ directly to the combined heat and power plant CHP.

The hydrogen H ₂ passes through a hydrogen line H ₂ from the electrolysis of water 8th into the methane reactor 9 in that it is reacted with the purified flue gas N ₂ + CO ₂ to methane. The heat needed for methane synthesis comes from special solar panels 13 that produce temperatures from 350 to 450 ° C.

Methane CH ₄ and oxygen O ₂ can now be stored at short notice. In times of higher power consumption can from the produced methane with that in the water electrolysis 8th formed oxygen O ₂ in a combined heat and power plant CHP electric power and heat are generated.

LIST OF REFERENCE NUMBERS

1

 heat exchangers

 10

 power generator

 13

 solar panel

 2

 Gas treatment reactor

 3

 Gas treatment reactor

4

 Gas treatment reactor

 5

 Gas treatment reactor

 6

 processing

 7

 manure treatment

 8th

 water electrolysis

 9

 methane reactor

 AS

 waste sludge

CHP

 CHP

 D

 Düngemittelaustrag

 H

 Halogen salt solutions

H ₂

 hydrogen

 H2O

 water

KDHP

potassium

 N

 nitrate salt

N ₂ + CO ₂

 flue gas

O ₂

 oxygen

RG

 flue gas

S

 sulfate salt

ST

 electricity

 W

 water drainage

 Z s1

 feed

 Z s1

 Diamoniumglykolsalz

Z s2

 urea

 Zs3

 urea

 Zs4

 urea

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 8346394 B2 [0004]
• DE 102011010743 A1 [0005]
• DE 102008061258 A1 [0006]
• DE 102010016004 A1 [0007]
• WO 2007/073881 A1 [0008]
• EP 0780151 B1 [0009]

Claims (1)

Device for the chemical and energetic utilization of flue gas, characterized in that this 1.1. a reprocessing stage and a recycling stage, 1.1.1. the work-up stage from 1.1.1.1. a heat exchanger ( 1 ) and 1.1.1.2. four gas treatment reactors connected in series ( 2 to 4 ), 1.1.1.3. and each of the gas treatment reactors ( 2 to 4 ) in addition to the gas supply and the gas discharge means for supplying (Zs1 to Zs4) of the reaction mixture, 1.1.1.4. Furthermore, the discharge of the reaction mixture of the first gas treatment reactor ( 2 ) with a preparation ( 6 ) and 1.1.1.5. the derivatives of the reaction mixture of the other gas treatment reactors ( 3 to 5 ) are treated with a fertilizer preparation ( 7 ), 1.1.1.5.1. fertilizer processing ( 7 ) a feed for potassium dihydrogen phosphate (KDHP), a fertilizer discharge (D) and a water discharge (W), 1.2. that the utilization stage consists essentially of a water electrolysis ( 8th ), a methane reactor ( 9 ) and a combined heat and power plant (CHP), 1.2.1. in which the water electrolysis ( 8th ) necessary electricity (ST) is supplied from at least one regenerative source, 1.2.2. an oxygen line (O ₂ ) connects the water electrolysis ( 8th ) directly with the combined heat and power plant (CHP), 1.2.3. a hydrogen line connects the water electrolysis ( 8th ) directly with the methane reactor ( 9 1.2.4. the methane reactor ( 9 ) is connected via a further supply line to the output of the processing stage and 1.2.5. one from the methane reactor ( 9 ) outgoing methane feeds the methane produced in it to the combined heat and power plant (CHP).

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