Commission Implementing Decision (EU) 2017/1442 of 31 July 2017 establishing best... (32017D1442)
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Commission Implementing Decision (EU) 2017/1442 of 31 July 2017 establishing best available techniques (BAT) conclusions, under Directive 2010/75/EU of the European Parliament and of the Council, for large combustion plants (notified under document C(2017) 5225) (Text with EEA relevance. )
- COMMISSION IMPLEMENTING DECISION (EU) 2017/1442
- of 31 July 2017
- establishing best available techniques (BAT) conclusions, under Directive 2010/75/EU of the European Parliament and of the Council, for large combustion plants
- (notified under document C(2017) 5225)
- (Text with EEA relevance)
- Article 1
- Article 2
- ANNEX
- BEST AVAILABLE TECHNIQUES (BAT) CONCLUSIONS
- SCOPE
- DEFINITIONS
- ACRONYMS
- GENERAL CONSIDERATIONS
- Best Available Techniques
- Emission levels associated with the best available techniques (BAT-AELs)
- BAT-AELs for emissions to air
- BAT-AELs for emissions to water
- Energy efficiency levels associated with the best available techniques (BAT-AEELs)
- Categorisation of combustion plants/units according to their total rated thermal input
- 1. GENERAL BAT CONCLUSIONS
- 1.1.
- Environmental management systems
- Applicability
- 1.2.
- Monitoring
- 1.3.
- General environmental and combustion performance
- BAT-associated emission levels
- Description
- Description
- 1.4.
- Energy efficiency
- 1.5.
- Water usage and emissions to water
- Description
- Applicability
- 1.6.
- Waste management
- 1.7.
- Noise emissions
- 2. BAT CONCLUSIONS FOR THE COMBUSTION OF SOLID FUELS
- 2.1.
- BAT conclusions for the combustion of coal and/or lignite
- 2.1.1.
- General environmental performance
- 2.1.2.
- Energy efficiency
- 2.1.3.
- NO
- X
- , N
- 2
- O and CO emissions to air
- 2.1.4.
- SO
- X
- , HCl and HF emissions to air
- 2.1.5.
- Dust and particulate-bound metal emissions to air
- 2.1.6.
- Mercury emissions to air
- 2.2.
- BAT conclusions for the combustion of solid biomass and/or peat
- 2.2.1.
- Energy efficiency
- 2.2.2.
- NO
- X
- , N
- 2
- O and CO emissions to air
- 2.2.3.
- SO
- X,
- HCl and HF emissions to air
- 2.2.4.
- Dust and particulate-bound metal emissions to air
- 2.2.5.
- Mercury emissions to air
- 3. BAT CONCLUSIONS FOR THE COMBUSTION OF LIQUID FUELS
- 3.1.
- HFO- and/or gas-oil-fired boilers
- 3.1.1.
- Energy efficiency
- 3.1.2.
- NO
- X
- and CO emissions to air
- 3.1.3.
- SO
- X
- , HCl and HF emissions to air
- 3.1.4.
- Dust and particulate-bound metal emissions to air
- 3.2.
- HFO- and/or gas-oil-fired engines
- 3.2.1.
- Energy efficiency
- 3.2.2.
- NO
- X
- , CO and volatile organic compound emissions to air
- 3.2.3.
- SO
- X
- , HCl and HF emissions to air
- 3.2.4.
- Dust and particulate-bound metal emissions to air
- 3.3.
- Gas-oil-fired gas turbines
- 3.3.1.
- Energy efficiency
- 3.3.2.
- NO
- X
- and CO emissions to air
- 3.3.3.
- SO
- X
- and dust emissions to air
- 4. BAT CONCLUSIONS FOR THE COMBUSTION OF GASEOUS FUELS
- 4.1.
- BAT conclusions for the combustion of natural gas
- 4.1.1.
- Energy efficiency
- 4.1.2.
- NO
- X
- , CO, NMVOC and CH
- 4
- emissions to air
- Description
- Description
- 4.2.
- BAT conclusions for the combustion of iron and steel process gases
- 4.2.1.
- Energy efficiency
- 4.2.2.
- NO
- X
- and CO emissions to air
- 4.2.3.
- SO
- X
- emissions to air
- 4.2.4.
- Dust emissions to air
- 4.3.
- BAT conclusions for the combustion of gaseous and/or liquid fuels on offshore platforms
- 5. BAT CONCLUSIONS FOR MULTI-FUEL-FIRED PLANTS
- 5.1.
- BAT conclusions for the combustion of process fuels from the chemical industry
- 5.1.1.
- General environmental performance
- 5.1.2.
- Energy efficiency
- 5.1.3.
- NO
- X
- and CO emissions to air
- 5.1.4.
- SO
- X
- , HCl and HF emissions to air
- 5.1.5.
- Dust and particulate-bound metal emissions to air
- 5.1.6.
- Emissions of volatile organic compounds and polychlorinated dibenzo-dioxins and -furans to air
- 6. BAT CONCLUSIONS FOR THE CO-INCINERATION OF WASTE
- 6.1.1.
- General environmental performance
- 6.1.2.
- Energy efficiency
- 6.1.3.
- NO
- X
- and CO emissions to air
- 6.1.4.
- SO
- X
- , HCl and HF emissions to air
- 6.1.5.
- Dust and particulate-bound metal emissions to air
- 6.1.6.
- Mercury emissions to air
- 6.1.7.
- Emissions of volatile organic compounds and polychlorinated dibenzo-dioxins and -furans to air
- 7. BAT CONCLUSIONS FOR GASIFICATION
- 7.1.1.
- Energy efficiency
- 7.1.2.
- NO
- X
- and CO emissions to air
- 7.1.3.
- SO
- X
- emissions to air
- 7.1.4.
- Dust, particulate-bound metal, ammonia and halogen emissions to air
- 8. DESCRIPTION OF TECHNIQUES
- 8.1.
- General techniques
- 8.2.
- Techniques to increase energy efficiency
- 8.3.
- Techniques to reduce emissions of NO
- X
- and/or CO to air
- 8.4.
- Techniques to reduce emissions of SO
- X
- , HCl and/or HF to air
- 8.5.
- Techniques to reduce emissions to air of dust, metals including mercury, and/or PCDD/F
- 8.6.
- Techniques to reduce emissions to water
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