Electric Road Systems: Strategic Stepping Stone on the Way towards Sustainable Freight Transport?
Abstract
:1. Introduction
- What is the sustainability impact of overhead line ERS in comparison to the current fossil-powered system?
- What is the relative importance of different life-cycle phases?
- Could the introduction of ERS be a strategic stepping stone on the way towards sustainable transport?
2. Background
2.1. Electric Road Systems
- i
- Conductive power supply through overhead lines, similar to trains;
- ii
- Conductive power supply through an electric rail in the road, similar to some subways; and
- iii
- Inductive power supply without any physical contact through electric coils in the road.
2.2. Strategic Planning towards Sustainability
“In a sustainable society, nature is not subject to systematically increasing…1 …concentrations of substances extracted from the Earth’s crust;2 …concentrations of substances produced by society;3 …degradation by physical means; and, in that society…4 ...people are not subject to conditions that systematically undermine their capacity to meet their needs.”
3. Methods
3.1. Strategic Life-Cycle Assessment
3.2. Life-Cycle Assessment
4. Results
4.1. Strategic Life-Cycle Assessment of ERS and Diesel Truck Transport
4.1.1. Assessment against Sustainability Principle 1
4.1.2. Assessment against Sustainability Principle 2
4.1.3. Assessment against Sustainability Principle 3
4.1.4. Assessment against Sustainability Principle 4
4.1.5. Requirements for Sustainable Freight Transport Systems
4.2. Life-Cycle Assessment of ERS and Current Fossil-Powered Truck Transport
5. Concluding Discussion
5.1. What Is the Sustainability Impact of ERS in Comparison to the Current Fossil-Powered System?
5.2. What Is the Relative Importance of Different Life-Cycle Phases?
5.3. Is the Introduction of ERS a Strategic Stepping Stone on the Way towards Sustainable Transport and What Role Could They Play in That Transition?
5.3.1. Lock-In and Threshold Effects
5.3.2. Stepping Stones towards Sustainability
5.4. Recommendations and Future Research
Acknowledgments
Author Contributions
Conflicts of Interest
References
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Life-Cycle Phase | SP1 Effects of ERS-Powered Trucks | SP1 Effects of Diesel-Powered Trucks |
---|---|---|
Extraction | Heavy metals in components and processes. Emissions from fossil fuel usage. | Heavy metals in components and processes. Emissions from fossil fuel usage. Oil leakages, gas flaring. |
Production | Heavy metals in components and production. Emissions from fossil fuel usage. | Heavy metals in components and production. Emissions from fossil fuel usage. |
Distribution | Emissions from truck transports of infrastructure systems, vehicles. | Emissions from truck transports of infrastructure systems, vehicles and fuel. |
Use | Copper emissions from catenary wire friction. Heavy metals in maintenance. Emissions from maintenance transport. | Combustion emissions. Heavy metals and fossil oil in maintenance. Emissions from maintenance transport. |
Waste | Incomplete recycling of heavy metals and other materials related to SP1. Some cables and other components may be left in the ground and leak heavy metals. Emissions and leakages from recycling processes and landfills. | Incomplete recycling of heavy metals and other materials related to SP1. Emissions and leakages from recycling processes and landfills. |
Life-Cycle Phase | SP2 Effects of ERS-Powered Trucks | SP2 Effects of Diesel-Powered Trucks |
---|---|---|
Extraction | NOX emissions from combustion. | NOX emissions from combustion. |
Production | NOX emissions from combustion. POP and Dioxin emissions. | NOX emissions from combustion. POP and Dioxin emissions. |
Distribution | NOX emissions from truck transports of infrastructure systems and vehicles. | NOX emissions from truck transports of infrastructure systems and vehicles. |
Use | NOX emissions from truck transports of infrastructure systems and maintenance vehicles. Leakage of persistent chemicals from electric components. | NOX emissions from truck transports of infrastructure systems and maintenance vehicles. NOX emissions from the vehicle’s engine. Leakage of persistent chemicals from electric components. |
Waste | Incomplete recycling of compounds related to SP2. Emissions and leakages from recycling processes and landfills. | Incomplete recycling of compounds related to SP2. Emissions and leakages from recycling processes and landfills. |
Life-Cycle Phase | SP3 Effects of ERS-Powered Trucks | SP3 Effects of Diesel-Powered Trucks |
---|---|---|
Extraction | Open pit mining of metals. | Open pit mining of metals and other resources. Oil extraction. |
Production | Contamination at refineries. | |
Distribution | Land use for roads and power grids. | Land use for roads and pipelines. |
Use | Land use for roads. | Land use for roads. |
Waste | Non-recycled materials to landfills. | Non-recycled materials to landfills. |
Life-Cycle Phase | SP4 effects of ERS-Powered Trucks | SP4 Effects of Diesel-Powered Trucks |
---|---|---|
Extraction | Use of scarce resources such as copper. Open pit mining causes negative health effects and forces people to move. | Use of scarce resources such as platinum. Open pit mining causes negative health effects and forces people to move. |
Production | Negative health effects from emissions related to fossil fuel use and component production. Harmful job conditions at some places. | Negative health effects from emissions related to fossil fuel use and component production. Harmful job conditions at some places. |
Distribution | Health effects from transport emissions. | Health effects from transport emissions. |
Use | Health risks due to high voltage and overhead line accidents. | Negative health effects from emissions related to fossil fuel use. |
Waste | Harmful emissions and working conditions in some countries. | Harmful emissions and working conditions in some countries. |
Life-Cycle Phase | Requirements for Sustainable ERS |
---|---|
Extraction | Very limited extraction of new resources. Extraction with best available technology (BAT). Complete restauration of the site after operation. Respecting indigenous people’s rights. |
Production | Strict application of BAT, precautionary and substitution principle. Rare substances with high accumulation potential are kept in closed loops. |
Distribution | Only using sustainable modes of transport powered by renewable energy. |
Use | Ensuring a safe, comfortable and effective satisfaction of people’s need for transportation *. Only renewable energy input and no emissions of critical substances from use and maintenance. |
Waste | Optimized for following EU’s waste hierarchy [45]: prevention, reuse, recycle, recovery; except there should be no need for landfilling. Circular material flow. |
Component | Material Use per km | Technical Life Time, Years | Reference |
---|---|---|---|
Overhead lines (double) | Copper: 4800 kg | 40 | Swedish Transport Administration [46], Stripple and Uppenberg [47] |
Catenary masts | Steel: 7752 kg PE: 122 kg Fiberglass: 152 kg | 50 | Swedish Transport Administration [46], Stripple and Uppenberg [47] |
Semi-rigid roadside barriers | Concrete: 5500 kg Steel: 16,000 kg | 20 | Swedish Transport Administration [46], Stripple and Uppenberg [47] |
Electrical equipment, protective relay, fuses | Steel: 57 kg | 40 | Uppenberg [48] |
Cables, AXQJ 1 kV 3×70/21 | Aluminium: 363 kg Copper: 121 kg PE: 216 kg | 40 | Uppenberg [48] |
Distribution sheds | Steel, low-alloyed: 145 kg | 50 | Uppenberg [48] |
Transformer 1/0,4 kV, 100 kVA | Steel: 3 kg Copper: 1 kg | 40 | Uppenberg [48] |
Transformer 1/0,4 kV, 50 kVA | Steel: 89 kg Copper: 38 kg | 40 | Uppenberg [48] |
Transformer 1/0,4 kV, 30 kVA | Steel: 3 kg Copper: 1 kg | 40 | Uppenberg [48] |
Transformer 1/0,4 kV, 16 kVA | Steel: 3 kg Copper: 1 kg | 40 | Uppenberg [48] |
Transformer 1/0,4 kV, 5 kVA | Steel: 3 kg Copper: 1 kg | 40 | Uppenberg [48] |
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Schulte, J.; Ny, H. Electric Road Systems: Strategic Stepping Stone on the Way towards Sustainable Freight Transport? Sustainability 2018, 10, 1148. https://doi.org/10.3390/su10041148
Schulte J, Ny H. Electric Road Systems: Strategic Stepping Stone on the Way towards Sustainable Freight Transport? Sustainability. 2018; 10(4):1148. https://doi.org/10.3390/su10041148
Chicago/Turabian StyleSchulte, Jesko, and Henrik Ny. 2018. "Electric Road Systems: Strategic Stepping Stone on the Way towards Sustainable Freight Transport?" Sustainability 10, no. 4: 1148. https://doi.org/10.3390/su10041148
APA StyleSchulte, J., & Ny, H. (2018). Electric Road Systems: Strategic Stepping Stone on the Way towards Sustainable Freight Transport? Sustainability, 10(4), 1148. https://doi.org/10.3390/su10041148