Post on 11-Oct-2020
Vehicle Emission Measurement
10-06-2019
Andriannah Mbandi, PhD
Stockholm Environment Institute, Africa Centre
Combustion Process
Ideal Combustion λ = 1
Fuel
Fuel
Fuel
CO2
CO2
CO2
O2
O2
O2
Combustion processLean Mixture λ > 1
Rich Mixture λ < 1
Fuel
Fuel
Fuel
CO2
CO2
CO2
O2
O2
O2
O2
O2 O2
O2
Fuel
Fuel
Fuel
CO2
CO2
O2
O2
Unburnt
Fuel
CO
O
Combustion gas: oxygen (O2)• O2 levels inverse of CO levels-
without air injection system
• Lean Mixture: O2
• Rich Mixture: O2
• O2 content increases sharply as λ>1
© http://www.youtube.com/watch?v=nIhDLnTGMAE
Combustion gas: carbon dioxide (CO2)
• Result of complete combustion
• Overall combustion and catalytic converter efficiency
• Not a pass or fail gas
• CO2: 12-16%
Combustion gas: carbon monoxide (CO)
• Incomplete combustion
• Excess fuel = rich mixture
• Partially burnt fuel
• Catalytic converter requires air/fuel ratio to vary lean to rich➢ Pre-catalytic converter: CO<1.5%
➢ After catalytic converter: CO~0%
• Feedback carburetted engine ran rich at idle: CO~9%
Combustion gas: hydrocarbons (HC)
• Unburned fuel due to incomplete combustion
• All engines produce HC:➢ Pre-catalytic converter: 150-300 ppm
➢ After catalytic converter: ~0 ppm
• Wasted fuel ➢ 1% partially burnt fuel produce 200 ppm HC
Combustion gas: oxides of nitrogen (NOX)
• Primary contributor of ozone
• Formed under high T & P: not formed at idle or light loads
• Lean mixture at high T: excess O2 molecules combine to form NOX
• Exhaust gas recirculation(EGR): O2 and T
Combustion gas: oxides of sulphur (SOX)
• High sulphur (S) content in fuel
➢ Reduction in S content reduces emissions in exhaust
➢ Marine engineshave higher contribution
© Bilfinger, 2014
Combustion particles-particulate matter (PM)
• Formed in combustion cylinder and in the exhaust system of the vehicle.
• Mostly attributable to heavy duty diesel vehicles
Mix (condensed) liquid & solid-Organic or Inorganic
• Sulphates• Nitrates• Ammonia• Sodium chloride• Black Carbon• Mineral dust• Water
©ARB, 2009
Source apportionment: what are the sources of urban air pollution?
Source: Karagulian, F. et al. (2015) ‘Contributions to cities’ ambient particulate matter (PM): A systematic review of local source contributions at
global level’, Atmospheric Environment. doi: 10.1016/j.atmosenv.2015.08.087.
Impact of air pollution in Africa?
GBD (2016) Global burden of Disease Study 2015-Results by risk factor-country level (online data base-Viz Hub-GBD Compare). Seattle.
Available at: https://vizhub.healthdata.org/gbd-compare/.
Petrol and Diesel Engines
Petrol Engine Diesel Engine
Spark Ignition Compression Ignition
Fuel/Air premixed before compression
Fuel/Air not premixed
Lower efficiency & Lighter Higher efficiency-High compression ratio & Heavier
AFR:14.7 (predetermined) AFR: 20-100/1 (air injected not controlled)
Emissions: More fuel, >CO2, less NOX and low PM
Emissions: less fuel, <CO2, >NOX
Higher PM
Pollutants: CO, HC, NOX Pollutants: NOX, PM, Smoke
Units of measurementGasesO2: % CO2: %CO: %HC: ppmNOX: ppm
PMParticulate Mass (µg/m3)Particulate Number (#/km)
Smoke:Opacity: % Smoke density: m-1
Engine: λ, RPM, T, P
Vehicle Emission Legislation
Emission limits
Test cycles
Test and Measurement Specifications
Result Calculation and reporting specifications
Standards
Regulations
© AVL, 2014
Use of PEMS to measure gases & PM
Exhaust sample
Heated sample line
GPS & weather probe
power supply 110 VAC, 220VAC or 12 VDC
Exhaust Flow Meter (EFM)
Weighing
Flow tube
Gas bench: CO/CO2 (NDIR) NOx(NDUV), THC (FID)
EU Emission legislation
© AVL, 2014
Light Duty Heavy Duty
Vehicle technology and fuel quality
ECUSCR
EGR
DOC
DPF
Adopted ICCT, 2012
TWC
©factsaboutscr, 2014
Selective Catalytic Reduction (SCR)Diesel engine control emissions technology
• Reduces NOx (~90%) using urea as a reductant within a catalyst system
• End product: N2, H2O and small CO2
3 Way Catalytic converter (TWC)Petrol engine control emissions technology• Most vehicles sold have TWC• use of TWCs with an oxygen sensor-based
closed-loop fuel delivery system• Simultaneous conversion of the three
criteria pollutants-HC, CO, and NOx
© clickcarparts, 2014
Inspection & Maintenance
Test CO HC NOX PM Smoke Cost Time Where?
Idle Test χ χ low fast UK, EU
2-Speed idle Test χ χ low fast UK, EU
Snap or Free
acceleration Test
χ low fast California, SA
IM 240 χ χ χ High Medium USA
Full load χ χ χ χ χ High Medium EU, USA,
Japan
I/M Standards-based on distribution of emissions
levels
I/M requirement for operating vehicle + Linked to vehicle registration
Set Inspection fees to support I/M programs
Capacity building for all actors in I/M
Phased Approach: Learning Adaptation
Capacity building
EU Emission I/M Standards
Source: EU directives 96/96 EC and 2001/9/ECYear CO standard
(%)
Lambda
(λ)
Test (Petrol)
< 1986 4.5 - Idle
> 1986 3.5 - Idle
With Catalytic converter 0.5 - Idle
0.3 0.97< λ < 1.03 2 speed idle
Year Turbocharged Naturally aspirant Test (Diesel)
< 1980 - -
> 1980 3.0 m-1 2.5 m-1 Free acceleration
UK Emission MOT standards
Year Test Type (Petrol) Pass or Fail
All Visual Inspection Visual Black smoke/dense blue
>1975 Standard Emissions Gas Analyzer (non-
catalyst test)
CO :3.5%-4.5%
HC: 1200ppm
>1992 Basic Emissions Gas Analyzer & EC
Fast Idle
Normal Idle
CO<0.2% HC<200ppm
0.97 < λ <1.03
CO <0.3%
Year Turbocharged
Opacity (m-1)
Normal
Opacity(m-1)
Test (Diesel)
<1979 - - Visual
1979-2008 3 2.5 Diesel fast pass
> 2008 1.5 1.5 Diesel fast pass
©hicksmotandservice, 2014
• Decentralized: ~20 000 local car repair garages
• Test: ❑ Vehicle safety❑ Road worthiness❑ Exhaust emissions
Age: 3 years oldAnnual test Cost: £30-£130Failure: notice & repairRe-test: free or reduced fee(defect/time)Time: 45-60 min, 2 technicians
© www.gov.uk/government/publications/your-car-and-the-mot2014
California Air Resources Board (ARB)
• Heavy-duty trucks and buses: control excessive smoke emissions & prevent tampering (>6000lb)
• Test-Society of Automotive Engineers (SAE) J1667 snap acceleration procedure-opacity measurement
• Test using PEMS
❑ Periodic Smoke Inspection Program (PSIP)
❑ Heavy-Duty Vehicle Inspection Program (HDVIP)
Allowable levels of Smoke Opacity
All post 1991 or newer engines Must not exceed 40% opacity
All pre-1991 engines Must not exceed 55% opacity
South Africa-Cape Town Emission Legislation• Air Quality Management by-Law 2003, 2010
• Vehicles: Compression ignition (Diesel)
• Dark smoke (2010): Light absorption >=20%
• BP Hartridge smoke meter
2003 2010
Naturally aspirated 60 HSU2.125m-1
50HSU1.61m-1
18.57%
Turbocharged 66 HSU2.51m-1
56HSU1.191m-1
21.57%
©Oliver, 2014
Framework for Vehicle Emission
Measurement
1. Micro-scale per vehicle: real-world vehicle emission measurement
Mbandi, A. (2018) Assessing the contribution of road transport emission to air pollution and greenhouse gases in Africa: A disaggregate study in Kenya. University of York
1. Micro-scale per vehicle: real-world vehicle emission data
2. Meso-scale: urban vehicle fleet characteristics and activity
Mbandi, A.M.; Böhnke, J.R.; Schwela, D.; Vallack, H.; Ashmore, M.R.; Emberson, L. Estimating On-Road Vehicle Fuel Economy in Africa: A Case Study Based on an Urban Transport Survey in Nairobi, Kenya. Energies 2019, 12, 1177
2. Meso-scale: urban vehicle fleet characteristics and activity
Mbandi, A.M.; Böhnke, J.R.; Schwela, D.; Vallack, H.; Ashmore, M.R.; Emberson, L. Estimating On-Road Vehicle Fuel Economy in Africa: A Case Study Based on an Urban Transport Survey in Nairobi, Kenya. Energies 2019, 12, 1177
3. Macro-scale: Assessment of the impact of road transport policies on air pollution and
greenhouse gas emissions in Kenya
Mbandi, A. (2018) Assessing the contribution of road transport emission to air pollution and greenhouse gases in Africa: A disaggregate study in Kenya. University of York
3. Macro-scale: Air pollution, Greenhouse Gas emissions in
Kenya, 2010
Mbandi, A. (2018) Assessing the contribution of road transport emission to air pollution and greenhouse gases in Africa: A disaggregate
study in Kenya. University of York.