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1.A.5.b - Other, Mobile (including Military)
In sub-category 1.A.5.b - Other, Mobile (including Military) emissions from landbased, air- and waterborne military vehicles are reported.
|NFR-Code||Name of Category||Method||AD||EF||Key Category Analysis|
|1.A.5.b||Other, Mobile (including Military)||see sub-category details||see below|
|1.A.5.b i||Land-based military transport and machinery||T1, T2||NS||CS, D||-|
|1.A.5.b ii||Military Aviation||T1, T2||NS||CS, D||-|
|1.A.5.b iii||Military Navigation||T1, T2, T3||NS, M||CS, D, M||-|
|Key Category||SO₂||NOₓ||NH₃||NMVOC||CO||BC||Pb||Hg||Cd||Diox||PAH||HCB||TSP||PM₁₀||PM₂ ₅|
For further information on sub-sector specific consumption data, emission factors and emissions as well as further information on emission trends, recalculations and planned improvements, please follow the links above.
Basically, all fuel deliveries to the military are included in the primary fuel delivery data provided by the National Energy Balances (NEB) (AGEB, 2019) 1). As the NEB does not provide specific data for military use, the following additional sources are used:
Military land-based vehicles and aviation:
For the years as of 1995, the official mineral-oil data of the Federal Republic of Germany (Amtliche Mineralöldaten der Bundesrepublik Deutschland), prepared by the Federal Office of Economics and Export Control (BAFA), are used (BAFA, 2019) 2). Provided in units of [1000 t], these amounts have to be converted into [TJ] on the basis of the relevant net calorific values given by 3).
As the official mineral-oil data does not distinguish into fossil and biofuels but does provide amounts for inland deliveries of total diesel and gasoline fuels, no data on the consumption of biodiesel and bioethanol is available directly at the moment. Therefore, activity data for biofuels used in military vehicles are calculated by applying Germany's official annual biofuel shares to the named total deliveries (see also: info on EF).
As there is no consistent NEB data availabe for aviation gasoline, delivery data from 4) is used.
Primarilly, fuel deliveries to military navigation is included in the NEB data provided in NEB lines 6: 'International Deep-Sea Bunkers' and 64: 'Coastal and inland navigation' but cannot be derived directly. Therefore, starting with this submission, fuel use in military navigation is estimated within a specific model used for estimating emissions from German maritime activities (BSH, 2018) 5).
Table 1: Sources for consumption data in 1.A.5.b
|Mode of Military Transport||Specific AD included in:||Sources for specific data||Relevant years|
|Military ground vehicles and mobile machinery, military aviation||NEB line 67 - 'Commerce, Trade, Services and other Consumers'||Special evaluation 1990-1994 carried out by AGEB||1990 - 1994|
|Official oil data, table 7j, column: 'An das Militär', 6)||as of 1995|
|Military Navigation||NEB lines 6 - 'International Deep-Sea Bunkers' and 64 - 'Coastal and Inland Navigation'||AD estimated within 7)||as of 1990|
Table 2: Annual over-all fuel consumption in military vehicles and mobile equipment, in terajoules
source: (BAFA, 2019): Amtliche Mineralöldaten für die Bundesrepublik Deutschland, Table 7j: “an das Militär” (“to the military”) and own estimates for blended biofuels
As the “consumption data” provided here originally represents fuel delivery data, some trends in “annual consumption” are influenced by stock-keeping activities. Here, a clear impact of storage effects can be observed for avgas, where a significantly high amount of 15 TJ was purchased in 2007 followed by zero or very small deliveries.
In addition, based upon the information available to the inventory compilers, no heavy fuel oil is used in national military navigation.
Table 3: Further break-down of annual military fuel consumption, in terajoules
|used in military ground vehicles and machinery|
|used in military aircraft|
|used in military navigation|
source: (BAFA, 2020): Amtliche Mineralöldaten für die Bundesrepublik Deutschland, Table 7j: “an das Militär” (“to the military”); BSH, 2020 (for fuel consumption in military navigation) and own estimates for blended biofuels
Discussion of emission trends
NFR 1.A.5.b is no key category.
Nonetheless, this NFR category shows interesting trends for emissions of Lead (Pb) from leaded gasoline (until 1997) and aviation gasoline:
Until 1997, lead emissions were dominated by the combustion of leaded gasoline in military ground-based vehicles. Therefore, the over-all trend for lead emissions from military vehicles and aircraft is driven mostly by the abolition of leaded gasoline in 1997. Towards this date, the amount of leaded gasoline decreased significantly. After 1997, the only source for lead from mobile fuel combustion is avgas used in military aircraft. As for avgas, the trend of consumption is more or less drecreasing steadily until 2005 but then shows a strong increase for 2006 and '07 (!), followed by no or very small deliveries. As mentioned above, there are no real consumption data available: AD is based on fuel deliveries to the military only. Thus, especially the trends for the use of aviation gasoline and the resulting emissions show this siginificant jumps in 2006 and 07. The party is aware of this issue and will try to solve it as soon as data allows. (see also: FAQ)
The trend for TSP emissions reflects the impact of leaded gasoline at least for 1990 to 1997. For all other years, particulate matter emissions simply follow the trend in over-all fuel consumption.
Regarding sulphur dioxide, emssions not only reflect the trend of fuel consumption but also the impact of fuel-sulphur legislation.
For all other reported pollutants, due to the application of tier1 emission factors, emission trends reported for this sub-category only reflect the trend in fuel deliveries.
Basically, all recalculations result from the implementation of military navigation which was not taken into account before.
Activity data: Here, fuels (diesel oil and biodiesel) used for military navigation have been revised slightly within the underlying BSH model. Furthermore, sthe net calorific values (NCVs) used for transforming the inland deliveries data for diesel oil, gasoline and jet kerosene provided in metric tonnes into terajoules have been revised slightly.
Table 4: Revised over-all activity data, in terajoules
For information on revised or newly implemented emission factors, please refer to the three sub-chapters linked above.
For specific information on recalculated emission estimates for Base Year and 2018, please see the pollutant specific recalculation tables following chapter 8.1 - Recalculations.
Uncertainty estimates for activity data of mobile sources derive from research project FKZ 360 16 023: “Ermittlung der Unsicherheiten der mit den Modellen TREMOD und TREMOD-MM berechneten Luftschadstoffemissionen des landgebundenen Verkehrs in Deutschland” by Knörr et al. (2009) 8).
Uncertainty estimates for emission factors were compiled during the PAREST research project. Here, the final report has not yet been published.
For further information on sub-sector specific planned improvements, please follow the links above.
bibliography : 1 : AGEB, 2019: Working Group on Energy Balances (Arbeitsgemeinschaft Energiebilanzen (Hrsg.), AGEB): Energiebilanz für die Bundesrepublik Deutschland; URL: https://ag-energiebilanzen.de/7-0-Bilanzen-1990-2018.html, (Aufruf: 29.11.2019), Köln & Berlin, 2019. : 2 : BAFA, 2019: Federal Office of Economics and Export Control (Bundesamt für Wirtschaft und Ausfuhrkontrolle, BAFA): Amtliche Mineralöldaten für die Bundesrepublik Deutschland; URL: https://www.bafa.de/SharedDocs/Downloads/DE/Energie/Mineraloel/moel_amtliche_daten_2017_dezember.html, Eschborn, 2019. : 3 : BSH, 2019: Federal Maritime and Hydrographic Agency (Bundesamt für Seeschifffahrt und Hydrographie, BSH): Pflege und Aktualisierung des Modells zur Berechnung der Energieeinsätze und Emissionen des von deutschen Häfen ausgehenden Seeverkehrs, im Auftrag des Umweltbundesamtes, Hamburg, 2019. : 4 : Knörr et al. (2009): Knörr, W., Heldstab, J., & Kasser, F.: Ermittlung der Unsicherheiten der mit den Modellen TREMOD und TREMOD-MM berechneten Luftschadstoffemissionen des landgebundenen Verkehrs in Deutschland; final report; URL: https://www.umweltbundesamt.de/sites/default/files/medien/461/publikationen/3937.pdf, FKZ 360 16 023, Heidelberg & Zürich, 2009. : 5 : EMEP/EEA, 2019: EMEP/EEA air pollutant emission inventory guidebook 2019, Copenhagen, 2019 bibliography