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sector:energy:fuel_combustion:transport:road_transport:fugitive_emissions_from_gasoline_evaporation [2021/01/26 17:51] – [Table] kotzulla | sector:energy:fuel_combustion:transport:road_transport:fugitive_emissions_from_gasoline_evaporation [2022/03/10 12:10] – [Table] kotzulla | ||
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In category //1.A.3.b v - Road Transport: Gasoline evaporation// | In category //1.A.3.b v - Road Transport: Gasoline evaporation// | ||
- | ^ | + | ^ Category Code ^ Method |
- | | T2 | NS, M | CS, M | | + | | 1.A.3.b v |
+ | ^ ^ NO< | ||
+ | | Key Category: | ||
===== Methodology ===== | ===== Methodology ===== | ||
Line 12: | Line 14: | ||
==== Activity data ==== | ==== Activity data ==== | ||
- | Specific data for gasoline evaporation from road vehicles are generated within TREMOD [((bibcite 1))]. | + | Specific data for gasoline evaporation from road vehicles are generated within TREMOD [(KNOERR2021a)]. |
- The following table provides an overview of annual amounts of gasoline evaported from road vehicles in Germany. | - The following table provides an overview of annual amounts of gasoline evaported from road vehicles in Germany. | ||
__Table 1: Annual amount of gasoline evaporated from road vehicles, in kilotonnes__ | __Table 1: Annual amount of gasoline evaporated from road vehicles, in kilotonnes__ | ||
- | | | + | | |
- | | **PCs** | + | ^ PCs | 10,915 | 9,222 | 8,541 | 7,514 | 7,078 | 6,694 | 6,382 | 6,328 | 6,173 | 6,085 | 5,775 | 5,725 | 5,718 | 5,502 | 5,498 | 5,605 | 5,321 | |
- | | **LDVs** | | + | ^ LDVs |
- | | **Mopeds** | 52 | 34 | 38 | 44 | 45 | 49 | 52 | 60 | | + | ^ Mopeds |
- | | **Motorcycles** | + | ^ Motorcycles |
- | | **Ʃ 1.A.3.b v** | 11, | + | ^ Ʃ 1.A.3.b v |
- | source: TREMOD | + | source: TREMOD |
- | === (Implied) Emission factors === | + | ==== (Implied) Emission factors |
- | Tier3 emission factors representing the effect of mitigation technologies are derived from TREMOD | + | Tier3 emission factors representing the effect of mitigation technologies are derived from TREMOD. |
__Table 2: Overview of implied emission factors per vehcile type, in kg/t__ | __Table 2: Overview of implied emission factors per vehcile type, in kg/t__ | ||
- | | | + | | |
- | | **PCs** | + | ^ PCs | Euro_1_I |
- | | **LDVs** | + | ^ ::: |
- | | **Mopeds** | + | ^ ::: | Euro_3_III |
- | | **Motorcycles** | + | ^ ::: | Euro_4_IV |
+ | ^ ::: | Euro_5_V | ||
+ | ^ ::: | Euro_6ab_VI | ||
+ | ^ ::: | ||
+ | ^ ::: | Euro_6d_temp_VI | ||
+ | ^ ::: | Euro_6d_VI | ||
+ | ^ ::: | pre-Euro | ||
+ | ^ LDVs | Euro_1_I | ||
+ | ^ ::: | Euro_2_II | ||
+ | ^ ::: | Euro_3_III | ||
+ | ^ ::: | Euro_4_IV | ||
+ | ^ ::: | Euro_5_V | ||
+ | ^ ::: | Euro_6ab_VI | ||
+ | ^ ::: | Euro_6c_VI | ||
+ | ^ ::: | Euro_6d_temp_VI | ||
+ | ^ ::: | Euro_6d_VI | ||
+ | ^ ::: | ||
+ | ^ Mopeds | ||
+ | ^ ::: | Euro_2_II | ||
+ | ^ ::: | ||
+ | ^ ::: | Euro_5_V | ||
+ | ^ ::: | pre-Euro | ||
+ | ^ Motorcycles | ||
+ | ^ ::: | Euro_2_II | ||
+ | ^ ::: | Euro_3_III | ||
+ | ^ ::: | Euro_4_IV | ||
+ | ^ ::: | Euro_5_V | ||
+ | ^ ::: | pre-Euro | ||
===== Discussion of emission trends ===== | ===== Discussion of emission trends ===== | ||
- | > **NFR 1.A.3.b v - Gasoline evaporation** is key category for emissions | + | __Table: Outcome |
+ | | for: ^ | ||
+ | | by: | Level & Trend | | ||
- | ++ Non-Methane Volatile Organic Compounds - NMVOC | + | NFR 1.A.3.b v is key source for emissions of Non-Methane Volatile Organic Compounds - NMVOC. |
//(fugitive emissions only; no NMVOC emissions from fuel combustion included)// | //(fugitive emissions only; no NMVOC emissions from fuel combustion included)// | ||
- | [[gallery size=" | + | {{ :sector:energy: |
- | : 1A3bv_AD.png | + | |
- | : 1A3bv_EM_NMVOC.PNG | + | |
- | [[/ | + | |
Since its maximum level of over 11,000 kilotonnes in 1990, the amount of evaporated gasoline is decreasing - and so are the related NMVOC emissions. The amounts of evaporated gasoline are connected directly with those of gasoline consumed. Here, the decrease becomes sharper from 2000 onwards following a growing switch from gasoline to diesel oil especially in passenger cars. Here, the annual amounts of NMVOC emissions from evaporation not only depend directly on the amount of evaporated gasoline but also on the number of vehicles equipped with mitigation technologies. Thus, the decrease is sharpest straight after 1990 and since then slowing down. | Since its maximum level of over 11,000 kilotonnes in 1990, the amount of evaporated gasoline is decreasing - and so are the related NMVOC emissions. The amounts of evaporated gasoline are connected directly with those of gasoline consumed. Here, the decrease becomes sharper from 2000 onwards following a growing switch from gasoline to diesel oil especially in passenger cars. Here, the annual amounts of NMVOC emissions from evaporation not only depend directly on the amount of evaporated gasoline but also on the number of vehicles equipped with mitigation technologies. Thus, the decrease is sharpest straight after 1990 and since then slowing down. | ||
- | |||
- | > **NOTE:** Due to defectively revised emission factors, the **emission estimates** provided in the NFR tables **are incorrect until 1993**. Here, the EFs for 1990 to 1993 have not been adapted to the revised values for all years as of 1994. As it is not possible to provide an artificially corretected chart for the //emission estimates//, | ||
===== Recalculations ===== | ===== Recalculations ===== | ||
- | Due to a broad revision of the TREMOD model carried out to keep in line with the new HBEFA 4.1, **activity | + | **Activity |
__Table 3: Revised annual amounts of evaporated gasoline, in kilotonnes__ | __Table 3: Revised annual amounts of evaporated gasoline, in kilotonnes__ | ||
- | | | + | | |
- | ^ Submission 2021 | + | ^ current submission |
- | ^ Submission 2020 | + | ^ previous submission |
- | ^ absolute change | + | ^ absolute change |
- | ^ relative change | + | ^ relative change |
- | In addition, the NMVOC **emission factors** applied were revised for all years. | + | In addition, the NMVOC **emission factors** applied were revised for several |
- | __Table 4: Revised implied emission factors for NMVOC emissions from evaporated gasoline, in kg/t__ | + | As a result, NMVOC emissions from gasoline evaporation were re-estimated as follows: |
- | + | ||
- | | | **1990** | + | |
- | | **PASSENGER CARS** | + | |
- | ^ Submission 2021 | | | | | | | | | | | | | | | | | | | + | |
- | ^ Submission 2020 | | | | | | | | | | | | | | | | | | | + | |
- | ^ absolute change | + | |
- | ^ relative change | + | |
- | | **LIGHT-DUTY VEHICLES** | + | |
- | ^ Submission 2021 | | | | | | | | | | | | | | | | | | | + | |
- | ^ Submission 2020 | | | | | | | | | | | | | | | | | | | + | |
- | ^ absolute change | + | |
- | ^ relative change | + | |
- | | **MOTORCYCLES** | + | |
- | ^ Submission 2021 | | | | | | | | | | | | | | | | | | | + | |
- | ^ Submission 2020 | | | | | | | | | | | | | | | | | | | + | |
- | ^ absolute change | + | |
- | ^ relative change | + | |
- | | **MOPEDS** | + | |
- | ^ Submission 2021 | | | | | | | | | | | | | | | | | | | + | |
- | ^ Submission 2020 | | | | | | | | | | | | | | | | | | | + | |
- | ^ absolute change | + | |
- | ^ relative change | + | |
- | + | ||
- | As a result, | + | |
__Table 6: Re-estimated NMVOC emissions, in kilotonnes__ | __Table 6: Re-estimated NMVOC emissions, in kilotonnes__ | ||
- | | | + | | |
- | ^ Submission 2021 | + | ^ current submission |
- | ^ Submission 2020 | + | ^ previous submission |
- | ^ absolute change | + | ^ absolute change |
- | ^ relative change | + | ^ relative change |
<WRAP center round info 60%> | <WRAP center round info 60%> | ||
- | For specific information on recalculated emission estimates for Base Year and 2018, please see the pollutant specific recalculation tables following chapter [[general: | + | For specific information on recalculated emission estimates for Base Year and 2019, please see the pollutant specific recalculation tables following chapter [[general: |
</ | </ | ||
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Besides a routine revision of the underlying model, no specific improvements are planned. | Besides a routine revision of the underlying model, no specific improvements are planned. | ||
- | ===== FAQs ===== | ||
- | |||
- | ------ | ||
- | [[bibliography]] | + | [(KNOERR2021a> |
- | : 1 : Knörr et al. (2019a): Knörr, W., Heidt, C., Gores, S., & Bergk, F.: ifeu Institute for Energy and Environmental Research (Institut für Energie- und Umweltforschung Heidelberg gGmbH, ifeu): Fortschreibung des Daten- und Rechenmodells: | + | |
- | [[/ | + |