VERSITET Senior adviser Morten Winther AARHUS UNIVERSITY DEPARTMENT OF ENVIRONMENTAL SCIENCE DCE –...

 VERSITET

Senior adviser Morten Winther

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

DCE – DANISH CENTRE for ENVIRONMENT and ENERGY

20 October 2015

UNI      

Emissions from heavy duty vehicles using upgraded biogas as a fuel

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

Introduction

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−The project “Biogas for transport - resources, environment and welfare economics” is carried out at DCE from 2014-2016 (Jensen et al., 2015)

−The project is an internal project under the Science Program for Sustainable Energy and Environment

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

Introduction

3

› The project examines the following questions:

› Is potential biogas production sufficient to fulfil the transport energy demand in a future perspective. What are the emission consequences, and health related and social costs

› Important to understand, in order to create a qualified basis for prioritisation of biogas resources

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

Disposition

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−This presentation explains the work made so far in WP3 and 4, dealing with fuel and emission estimates in the project

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

Disposition

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−Fuel consumption for trucks and buses in a diesel reference scenario up to 2035

−Some notes on CNG (Compressed Natural Gas) and LNG (Liquefied Natural Gas) vehicles in a biogas scenario

−CH4 emission sources critical for CNG/LNG vehicles

−Calculated GHG (Greenhouse Gas) emission savings in 2035−Some conclusions

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

6

Diesel reference scenario

− HDV’s are grouped into rigid trucks, truck-trailers, articulated

trucks and buses

− FC = Nveh

x Milann

(km) x EFC

(MJ/km)

− Fleet, mileage and speed data: DTU Transport and Danish Road

Directorate

− Fuel factors also split into e.g. EU emission legislation levels:

Conv. and Euro I-VI

Type/size RT 3,5 - 7,5t RT 7,5 - 12t RT 12 - 14 t RT 14 - 20t RT 20 - 26t RT 26 - 28t RT 28 - 32t RT >32t TT/AT 28 - 34t TT/AT 34 - 40t TT/AT 40 - 50t TT/AT 50 - 60t TT/AT >60t Urban Buses <15t Urban Buses 15 - 18t Urban Buses >18t Coaches <15t Coaches 15 - 18t Coaches >18tRT: rigid trucksTT/AT: Truck-trailers, artic. trucks

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

7

− Euro VI enters the fleet and old emission technologies are phased out

− Euro VI dominates fuel totals; 81 %, 95 %, 99 % in 2020, 2025 and 2030, respectively

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

8

− Euro VI vehicles are relevant for natural gas substitution.

− Most fuel expected for 40-50t and 34-40t trucks; 46 % and 21 %, respectively (note the axis scaling!).

− 2035: 45 PJ diesel in total. A full substitution requires 51 PJ of natural gas

Euro VI in closer details

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

CNG vehicles – short description

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− CNG: Compressed Natural Gas

− On board storage: Pressure bottles (200-260 bar)

− SI (spark ignition) engine, operates similarly to a gasoline engine

− Euro VI, equipped with a three-way catalyst

− CNG has smaller km range between fuel stops compared to diesel

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

CNG vehicles – short description

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− CNG fuel economy vs diesel: Big variations.

− An average of 19 % more MJ/km was found in recent national work1

1COWI/Energistyrelsen: Framework conditions for using

natural gas in heavy duty road transport, 150 pp.,

December 2014 (in Danish: Rammevilkår for gas til tung

vejtransport)

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

CNG vehicles – short description

11

− NOx and PM (Particulate Matter): No significant emission differences between natural gas and diesel Euro VI, based on the limited measurement data assessed so far1

1COWI/Energistyrelsen: Framework conditions for using

natural gas in heavy duty road transport, 150 pp.,

December 2014 (in Danish: Rammevilkår for gas til tung

vejtransport)

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

CNG vehicles – substitution

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− CNG Substitution is made for rigid trucks

Demand for long range is less critical for smaller trucks

Some CNG trucks already for sale in Denmark (up to 320 hp)1, a good precondition

1www.gasbiler.info: Natural gas fueled vehicles for sale

in Denmark, Danish Gas Technology Centre

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

LNG vehicles – short description

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− LNG: Liquefied Natural Gas

− On board storage: Vacuum insulated storage tanks (3-10 bar, -160 oC)

− Dual fuel engine (using 5 % diesel to pilot ignition); operates similarly to a diesel engine

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

LNG vehicles – short description

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− Emission performance similar to Euro VI, equipped with SCR and DPF

− Longer km range than CNG, due to more fuel stored

− Fuel economy: Same drawback as for CNG, compared to diesel (ICCT, 2015)

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

LNG vehicles – substitution

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− LNG substitution for large trucks (TT/AT trucks)

− LNG fulfills demand for longer km range by large trucks

− Suitable engine capacities already on the market in e.g. the US

− EU directive 2014/94 places on member countries to establish LNG fueling stations along main arterial roads by 2025

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

CH4 loss from CNG/LNG vehicles1

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− CNG sources:

− CH4 from exhaust (tail pipe)

− CH4 from the crankcase (So-called ”blow by emissions”, leaks between piston rings and cylinder walls, vented to the atmosphere)

1Delgado, O., Muncrief, R.: Assessment of heavy-duty

natural gas vehicle emissions: Implications and policy

recommendations, The International Council on Clean

Transportation (ICCT), White Paper, 34 pp., July 2015

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

CH4 loss from CNG/LNG vehicles1

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− LNG sources:

− CH4 from exhaust (tail pipe)

− CH4 from dynamic venting in the fuel injection system

− CH4 from the fuel tank (”boil off” pressure release for safety reasons)

1Delgado, O., Muncrief, R.: Assessment of heavy-duty

natural gas vehicle emissions: Implications and policy

recommendations, The International Council on Clean

Transportation (ICCT), White Paper, 34 pp., July 2015

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

CH4 loss from the fueling station1

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− CNG fueling stations CH4 leaks from pipes and fittings

CH4 escape during nozzle connection and disconnection

Compressor loss

− LNG fueling stations

Methane boil-off in storage tanks

Manual venting of vehicle fuel tanks prior to refueling

Spills and escape during nozzle connection/disconnection

1Delgado, O., Muncrief, R.: Assessment of heavy-duty

natural gas vehicle emissions: Implications and policy

recommendations, The International Council on Clean

Transportation (ICCT), White Paper, 34 pp., July 2015

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

19

− Calculation for 2035: All heavy duty Euro VI vehicles use CNG/LNG

− Tank-to-wheel greenhouse gas emissions:

For low/high CH4 loss, estimates range between 12 - 22 % of diesel reference case

CO2 originates from the ”5 %” diesel pilot fuel

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DEPARTMENT OF ENVIRONMENTAL SCIENCE

20

− Pump-to-wheel greenhouse gas emissions:

Using low/high CH4 loss, estimates range between 14-25 % of diesel reference case

CO2 originates from the ”5 %” diesel pilot fuel

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

Conclusions

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− For CNG/LNG vehicles there a several emission sources of CH4, on board the vehicles as well as at the gas fueling station

− NOx and PM (Particulate Matter): The (scarce) literature data reveals no significant emission differences between natural gas and diesel vehicles for Euro VI

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

Conclusions

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− Estimated tank-to-wheel GHG emissions from CNG/LNG vehicles are in the range of 12-22 %, of the diesel reference case

− Including fueling station losses of CH4, estimated ”pump-to-wheel” emissions increase to 14-25 % compared to diesel

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

Conclusions

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− Additional CH4 loss is expected during the production of biogas and during distribution

− On the other hand, the CH4 emission savings from manure will be very big

− Both sources are being assessed in the current project; no results yet.

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

24

Thank you for your attention!

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

Summary of CH4 loss

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− Conclusions from ICCT (2015) survey: CH4 from exhaust is the same for CNG and LNG

CNG crankcase ~ LNG dynamic venting + fuel tank venting

Fueling station loss, CNG ~ LNG

CH4 loss (% of fuel delivered)  low estimate high estimate

Pump-to-tank Fueling station 0,3 0,3Tank-to-wheel Exhaust 0,1 0,9

Crankcase ~ dynamic venting/tank boil off 0,4 0,8

Total Pump-to-Wheel 0,8 2,0Source: ICCT (2015)

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

20 October 2015Internal DCE seminar 2015

Introduction

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− For overview’s sake, the project consist of 8 WP’s:

› WP1, WP2: Biomass resources and potential biogas production (Jørgensen,

Møller)

› WP3: Future energy demand of the transport sector with a focus on road

transport heavy duty vehicles (HDV); (Jensen)

› WP4: Energy consumption and emissions of different HDV’s powered by

upgraded biogas (Winther)

› WP5: Health-related external costs of air pollution (Brandt)

› WP6, WP7: Life-cycle Analysis and Cost-Benefit Analysis (Thomsen, Cong)

› WP8: Stakeholder involvement and dissemination of results (Jensen)

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DEPARTMENT OF ENVIRONMENTAL SCIENCE

27

AARHUS UNIVERSITY

DEPARTMENT OF ENVIRONMENTAL SCIENCE

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