Swedish Transport Administration electric road program
The Swedish Transport Administration electric road program (Swedish: Trafikverkets Program för Elvägar) or Swedish Transport Administration Electrification Program (Swedish: Trafikverkets Program för Elektrifiering)[1] is a program involving the assessment, planning, and implementation of an electric road national infrastructure for Sweden by Trafikverket, the Swedish Transport Administration.
The fact-finding program began in 2012[2] and assessments of various electric road technologies in Sweden began in 2013.[3]: 12 Trafikverket expected the final report of the Swedish electrification commission by the end of 2022,[4] but it was delayed until December 2024.[5]
The final report of the second Swedish-German research collaboration on electric road systems, CollERS 2, advised Trafikverket to select a single ERS technology, suitable for heavy trucks, with several suppliers who use an existing standard, coordinated with German and French ERS decisions, not necessarily led by the European Union but with their coordination, utilizing an ERS-technology-neutral payment system.[6] In 2024 the CollERS project was renewed and extended to include France.[7] The first standard for on-board ground-level power supply equipment for electric road vehicles was published in late 2022,[8] with a complete set of standards expected by the end of 2024.[9]
The first permanent electric road in Sweden was as of 2023 planned to be built on a section of the E20 route between Hallsberg and Örebro.[10] Trafikverket was expected to announce its chosen technology for electric roads by late 2023,[11] but due to procurement offers exceeding the project's budget, in 2023 Trafikverket began investigating cost-reducing measures in order to realize the project within its budget.[12] The E20 project was funded at 500-600 million SEK, or about 24-29 million SEK per two lane-kilometers.[13] As of 2024, the procurement process is expected to begin again at the end of 2025.[14]
Technology
[edit]TRL (formerly Transport Research Laboratory) lists three power delivery types for dynamic charging, or charging while the vehicle is in motion: overhead power lines, ground level power through in-road or on-road rail, and wireless inductive charging. Overhead power was most technologically mature solution which provided the highest levels of power at the time of the 2018 report, but the technology is unsuitable for non-commercial vehicles. Ground-level power is suitable for all vehicles, with rail being a mature solution with high transfer of power and easily accessible and inspected elements. Inductive charging delivers the least power and requires more roadside equipment than the alternatives.[15]: Appendix D By the late 2010s, infrastructure costs of ground-level rail became lower than overhead lines.[16][17]: 21–24
Standardization
[edit]Alstom, Elonroad, and other companies have, in 2020, begun drafting a standard for ground-level power supply electric roads.[18][19] The European Commission published in 2021 a request for regulation and standardization of electric road systems.[20] Shortly afterward, a working group of the French Ministry of Ecology recommended adopting a European electric road standard formulated with Sweden, Germany, Italy, the Netherlands, Spain, Poland, and others,[21] while leaning toward rail ERS, though the specific rail technology has yet to be standardized.[22] The first standard for electrical equipment on-board a vehicle powered by a rail electric road system (ERS), CENELEC Technical Standard 50717, has been published in late 2022.[8] Following standards, encompassing full interoperability and a "unified and interoperable solution" for ground-level power supply, are scheduled to be published by the end 2024, detailing a complete European standard on electric road systems "for communication and power supply through conductive rails embedded in the road"[23][9] as specified in the proposed technical standard prTS 50740 in accordance with European Union directive 2023/1804.[24][25]
The Swedish government charged Trafikverket with taking concrete measures on the Sweden-Germany-France cooperation regarding electric roads, and publish annual reports in October 2022, 2023, and 2024, and a final report in October 2025.[26][27] A report by Research Institutes of Sweden (RISE) recommends that Stockholm County choose the stationary and dynamic charging standards selected by Trafikverket.[28]: 46 RISE recommends intra-city dynamic charging infrastructure capable of at least 20 kW so vehicles can gain range while driving on the electric road, for driving on peripheral roads[28]: 40–42 and inter-city infrastructure capable of 300 kW or more for best cost-effectiveness.[29] The Swedish National Road and Transport Research Institute (VTI) similarly recommends a system capable of delivering 300 kW per truck.[30] The French Ministry of Ecology working group recommends 400 kW for 44-ton trucks driving at 90 kilometers per hour along a 2% grade, or at minimum 250 kW so the truck can charge along flat or gently-sloping roads.[21]: 25
The final report of the second Swedish-German research collaboration on electric road systems, CollERS 2, advised Trafikverket to select a single ERS technology, suitable for heavy trucks, with several suppliers who use an existing standard, coordinated with German and French ERS decisions, not necessarily led by the European Union but with their coordination, utilizing an ERS-technology-neutral payment system.[6] In 2024 the CollERS project was renewed and extended to include France.[7]
Assessment
[edit]Assessments of various electric road technologies began in 2013.[3]: 12 Initially the Swedish Transport Administration had expected to finish the program's assessment phase by 2022, then begin formulation of the national electric road network the same year, and finish its planning by 2033.[3]: 40 The schedule was accelerated in October 2020, when the Swedish government charged a commission with investigating the standardization, construction, operation, maintenance and financing of electric roads in Sweden.[31] A report generated by TRL in association with the Swedish Transport Administration listed available electric road systems, of which KAIST OLEV, Siemens eHighway, Elways, Elonroad, Bombardier PRIMOVE, and Electreon were estimated to be the most commercial-ready, with OLEV and eHighway already possessing a complete system in 2018.[15]: 13–15 After further investigation the readiness level assessments of OLEV and Electreon were lowered.[32] An interim report summarizing the assessment phase was published in February 2021,[17] and a preliminary report on the standardization, construction, operation, maintenance and financing of electric roads was submitted September 2021.[31][33]
Assessed technologies
[edit]Siemens
[edit]Overhead power lines were first tested through the program, using Siemens eHighway technology. The system was inaugurated in June 2016 in Sandviken municipality near Gävle in central Sweden. A 2-kilometre stretch of the E16 motorway was fitted with trolley wires 5.4 metres above its surface, which supply power at 750 volts DC. Trolleytrucks can connect the power pickups, mounted on mechanical arms or trolley poles, while driving under the wires. The trolley poles allow for a degree of lateral movement, but if the lorry is steered into the outside lane, the trolley poles are lowered automatically and the lorry switches to battery or diesel power.[34] The system as tested is capable of delivering 500 kW of power and has an estimated maintenance period of 20 years.[15]: 140–144
Elways-Evias
[edit]Ground-level conductive rails were tested from 2017 to 2019, using technology by the company Elways. A 2-kilometre stretch of the 893 road between Arlanda airport cargo terminal and the Rosersberg logistics area was fitted with embedded conductor rails as part of the eRoadArlanda project. Short sections of the rails are energized as a compatible vehicle approaches and they are disconnected once the vehicle has passed. The system measures the energy consumed, so that the vehicle owner can be billed.[15]: 146–149 Buses and trucks were tested on the road,[35] and the system is suited for electric cars, and is safe to touch even when the road is flooded with salt water.[36] The system as tested is capable of delivering 200 kW of power and has an estimated maintenance period of 20 years.[15]: 146–149 Evias, which commercializes the technology by Elways,[37] reports that in a pilot with Budpartner initiated in 2021 the infrastructure successfully delivered 960 kW of power,[38] and hopes to deliver megawatts of power for logistics loading docks and electric aircraft in the future.[39]
Electreon
[edit]Trafikverket assessed a wireless electric road system (WERS) with inductive coils using technology by Electreon, an Israeli startup. Testing was scheduled to begin in 2020.[40] The system is made of short sections containing copper coils that energize when a vehicle is driving over them and switch off when it's passed, and it supports power metering and a billing for the energy consumed. The system is estimated to have a maintenance period of 5 years for roadside equipment[15]: 171–172 and about 10 years for in-road equipment.[41]
Electreon first tested receivers theoretically capable of up to 25 kW, installing three 25 kW receivers on an electric bus,[17]: 27 and subsequently five 20 kW receivers on an electric truck that achieved an average transfer rate of 14 kW per receiver.[42] The pilot was scheduled to conclude in March 2022,[43] however Electreon has requested an extension for another year[44] so it can test receivers theoretically capable of 30 kW.[45] Testing has been extended in late 2022 by another two years to assess seasonal damage and maintenance.[46]
The German Ministry of Economy, BMWK, tested infrastructure by Electreon in 2023 with a bus equipped with inductive coils that receive power from a 200-meter strip of transmitters under the road surface. The receivers were able to collect 64.3% of the power emitted from the transmitters. Installation proved complex and costly, and finding suitable locations for the coils' roadside power cabinets proved difficult.[47] The Coventry University dynamic charging project DynaCoV found wireless electric roads financially infeasible, using itemized costs provided in 2021 by Electreon.[48]
Elonroad
[edit]Trafikverket began testing ground-level conductive rails power delivery in 2020 using technology by Elonroad, a Swedish startup located in Lund. The project, EVolutionRoad, was scheduled to begin planning in 2019 and conclude its testing and demonstrations in 2022. The first stretch of road was inaugurated in June 2020[49] and is the first electric road system placed in an urban environment. The system uses a conductive pickup under the vehicle that connects to a rail on top of the road surface via sliding contacts. The rail is active one meter at a time when covered by the vehicle, making it safe in a city environment. The system measures the energy consumed, so that the vehicle owner can be billed. The system as tested is capable of delivering up to 300 kW with 97% efficiency while driving[50] and it is estimated to have a maintenance period of 10 years.[15]: 167 Testing has been extended in late 2022 by another two years to assess seasonal damage and maintenance.[51] At the request of Trafikverket, Elonroad has switched focus in 2023 from rail glued to the surface of the road, or on-road rail, to rail embedded in the road at surface level, or in-road rail, which is better suited for higher vehicle speeds.[52] Testing was concluded in May 2024. Elonroad credits the pilot with paving the way for their participation in the pilot project for electric roads in France.[53]
Cost
[edit]Type(and developer) | Power perreceiver(and powerpending furtherdevelopment) | Million SEKper km road(two lane-km) | References |
---|---|---|---|
Overhead powerlines (Siemens) | 650 kW(1000 kW) | 12.4 | [15]: 140–144 [17]: 23–24, 54 |
Ground-level power supplythrough in-road rail(Elways and NCC consortium) | 200 kW(800 kW) | 9.4-10.5 | [15]: 146–149 [17]: 21–23, 54 |
Ground-level power supplythrough on-road rail(Elonroad and ABB consortium) | 150 kW(500 kW) | 11.5-15.3 | [17]: 25–26, 54 |
Wireless power transferthrough in-roadinductive coils (Electreon) | 25 kW(40 kW) | 19.5-20.8 | [15]: 171–172 [17]: 26–28, 54 |
The first permanent electric road in Sweden was as of 2023 planned to be built on a section of the E20 route between Hallsberg and Örebro.[10] The E20 project was funded at 500-600 million SEK, or about 24-29 million SEK per two lane-kilometers.[13] The procurement process was cancelled as the submitted offers by Electreon and Elonroad exceeded the project's budget.[12] As of 2024, the procurement process is expected to begin again by the end of 2025.[14]
Infrastructure
[edit]The table on the right specifies Trafikverket's 2021 estimate for capital costs in million Swedish krona per two lane-kilometers or one road-kilometer: 12.4 for overhead wires, 9.4-10.5 for in-road rail, 11.5-15.3 for on-road rail, and 19.5-20.8 for inductive coils.[17]: 54
A 2022 paper estimates the capital costs per two lane-kilometers at 1.1M USD for overhead wires, 0.7M USD for in-road rail, and 2.2M USD for inductive coils.[54]: 11
Maintenance
[edit]Travikverket estimated in 2020 that other-than-damage maintenance costs are highest for either of the two rail systems, second highest for overhead lines, and lowest for induction.[55] Total annual maintenance costs were estimated in 2021 by the technology providers to be, in terms of percentage per year of the initial capital costs, 0.5% for rail, up to 1% for induction, and 1%-2% for overhead lines.[18] A 2022 paper estimated yearly repair and maintenance cost per kilometer at 16,000 USD for overhead lines, 11,000 USD for in-road rail, and 33,000 USD for inductive coils.[54]: 12
Annualized societal cost
[edit]A 2019 report by the Swedish Electromobility Centre estimates the annualized societal costs of the entire Swedish automotive fleet under each of the three power delivery systems. Each of the systems was found to result in net savings, with the rail system being the most beneficial.[56]: 10–11 A 2022 research paper by RISE estimates that installing approximately 4,000 km of electric roads that supply at least 150 kW per truck on average is the most economically beneficial option for electric vehicle charging.[29]
Overhead power lines, despite being the most mature technology and, at the time of the 2019 report, having the least expensive infrastructure, are the most expensive overall because they only allow tall commercial vehicles such as trucks and buses to charge while driving, while non-commercial vehicles cannot use the wires to charge while driving, so they will have to use static charging that requires larger batteries with higher capacities than batteries required with the use of dynamic charging. Though overhead lines had the least expensive infrastructure costs when the initial report was written,[56]: 10–11 soon afterward infrastructure costs of ground-level rail became lower than overhead lines.[16][17]: 21–24
Ground-level power supplies allow dynamic charging for all vehicles, which greatly reduces the required battery capacity and size since the battery is charged while it is being used. The reduced battery size and capacity reduces cost by about five billion euros annualized for the entire Swedish automotive fleet. The rail and inductive systems are estimated to have equal annualized costs for all components in aggregate other than infrastructure; the conductive rail infrastructure is estimated to cost about 1 billion euros annualized, while wireless inductive infrastructure is estimated to cost about 2.8 billion euros annualized.[56]: 10–11
The Swedish Transport Administration's regulations for state electric roads proposed in 2021 include estimates for different charging system costs for the customer driving different types of electric vehicles. Long-haul and regional haul trucks were found to incur the least costs with fast charging stations, though the conditions for such a fast-charging network are not currently met and it's not clear if they can ever be met,[57] while passenger vehicles were found to incur the least costs with electric road charging.[33]
Planning
[edit]The switch from the assessment phase to the planning phase was estimated to occur in 2022,[3]: 40 but the Swedish government accelerated the program's schedule, and began the planning phase with the creation of the electrification commission in October 2020. The commission will investigate the electrification of heavy transport vehicles, fast charging, and the standardization, construction, operation, maintenance and financing of electric roads in Sweden. A report on the chosen electric road infrastructure was expected by September 2021,[58][31] but the choice was delayed until late 2022 or early 2023,[59] and delayed again to mid or late 2023.[11] Regulations for electric roads, independent of the chosen technology, were proposed on September 1, 2021.[33] A final report on the expansion of the Swedish electric road network is expected by December 2024.[5]
Construction and operation
[edit]Legal aspects
[edit]The Swedish Transport Administration anticipates that a national electric road network would require interfaces between several players: the electricity supplier, the power grid company, the vehicle manufacturer, the road owner, the electric road technology operator, the metering and billing provider, and the user of the electric road. The ownership model can vary: the power grid company may own the secondary roadside electrical substations that power the electric road infrastructure or they may be owned by other players, and the power reading and payment system may be owned by a player separate from the infrastructure operator.[60]: 10–11 ABB formed a consortium that will handle the different aspects of the business model, such as energy metering and billing, for its ground-level power supply technology.[61][62]
Proposed framework
[edit]The Swedish Transport Agency has been tasked with proposing a technical, financial, and legal framework for the electric road toll system by November 1, 2022.[63] The agency proposes expanding the legal framework of the Stockholm congestion tax for electric road permits, and rolling out the technical framework in stages. For the first permanent electric road the Agency will offer fixed-fee permits for use of the electric road system. As the system gains more users, it will transition to usage-based billing. The infrastructure, along with equipment installed on registered vehicles, will verify the permit and the standing of the permit holder's debts and payments, then allow or disallow drawing power from the electric road system and bill the permit holder appropriately.[64][65]
First permanent electric road
[edit]The Swedish Transport Administration announced on July 1, 2021, that a section of the E20 route was chosen to be the first permanent electric road in Sweden.[66] The road was expected to begin operation by 2027.[10]
Trafikverket has made an initial selection of procurement providers by April 2022.[67][68] the choice of technology was expected to be announced by early 2023 with work beginning in March 2023,[68] but the choice was delayed to mid to late 2023.[11] In August the procurement process was cancelled, as the submitted offers exceeded the project's budget. Trafikverket will perform cost analyses seeking cost-reducing measures that will help realize the project within its budget.[12] The E20 project was funded at 500-600 million SEK, or about 24-29 million SEK per two lane-kilometers.[13] As of 2024, the procurement process is expected to begin again by the end of 2025.[14]
An analysis by the logistics firm Novoleap concluded that the electric road on the E20 section between Hallsberg and Örebro will result, for logistics companies, in reduced capital costs for electric fleets, reduced operating costs, and reduced CO2 emissions. Novoleap notes that the total cost of the electric road may be positive or negative depending on its capital costs for infrastructure, its annual maintenance costs, and its delivered power per vehicle; 200 kW of power per truck is adequate, but higher levels of power such as 400 kW and 800 kW are more beneficial and might be required in the long term.[69] The VTI similarly recommends a system capable of delivering 300 kW per truck.[30] The Swedish Transport Agency has proposed in late 2022 the billing framework for the first permanent electric road, which will initially rely on a permit for a fixed fee. As the system gains more users, it will transition to usage-based billing.[64]
An expansion of further 3000 kilometers of electric roads is expected by 2045.[70]
See also
[edit]References
[edit]- ^ Trafikverket (June 24, 2020), Trafikverkets Program för Elvägar byter namn, archived from the original on August 14, 2021
- ^ "Test och demonstration - resultat, erfarenheter, lärande och reflektioner", Region Gävleborg, March 24, 2023
- ^ a b c d Swedish Transport Administration (November 29, 2017), National roadmap for electric road systems (PDF), archived from the original (PDF) on November 24, 2020
- ^ Kenneth Natanaelsson (March 26, 2021), Elektrifiering av transportsystem (PDF), Trafikverket, archived from the original (PDF) on March 2, 2022
- ^ a b Energimyndigheten (Swedish Energy Agency) (January 2023), Delrapport inom uppdraget om handlingsprogram för laddinfrastruktur och tankinfrastruktur för vätgas, p. 20
- ^ a b Matts Andersson; et al. (January 31, 2024), Choosing ERS technology for Europe (PDF), WSP Sverige AB, archived from the original (PDF) on March 10, 2024
- ^ a b "Declaration between France and Sweden on a renewed Strategic Innovation Partnership for Sustainable, Digital and Resilient Societies" (PDF), Regeringen, January 30, 2024
- ^ a b "PD CLC/TS 50717 Technical Requirements for Current Collectors for ground-level feeding system on road vehicles in operation", The British Standards Institution, 2022, archived from the original on January 2, 2023, retrieved January 2, 2023
- ^ a b Matts Andersson (July 4, 2022), Regulating Electric Road Systems in Europe - How can a deployment of ERS be facilitated? (PDF), CollERS2 - Swedish German research collaboration on Electric Road Systems
- ^ a b c Kenneth Natanaelsson (March 17, 2023), "Elväg Örebro-Hallsberg, Infradagen 2023", Mälardalsrådet
- ^ a b c Per Mattsson (January 18, 2023), "40 experter: Så blir det nya mobilitetsåret", Dagens industri
- ^ a b c "Vi avbryter upphandlingen för Sverige första permanenta elväg", Trafikverket, August 28, 2023
- ^ a b c Johan Kristensson (September 5, 2023), "Skjuts upp – därför skenade kostnaden för Sveriges första permanenta elväg", NyTeknik
- ^ a b c Lesley Brown (28 August 2024), "Electric Road Systems, towards decarbonising road transport", Futura Mobility, archived from the original on September 4, 2024
- ^ a b c d e f g h i j k D Bateman; et al. (October 8, 2018), Electric Road Systems: a solution for the future (PDF), TRL, archived (PDF) from the original on 3 August 2020, retrieved 10 February 2021
- ^ a b Guerrieri, M. (2019), "Catenary-Free Tramway Systems: Functional and Cost–Benefit Analysis for a Metropolitan Area.", Urban Rail Transit, 5 (4): 289–309, doi:10.1007/s40864-019-00118-y, hdl:11572/246245, S2CID 208953068
- ^ a b c d e f g h i j Analysera förutsättningar och planera för en utbyggnad av elvägar, Swedish Transport Administration, February 2, 2021, archived from the original on 3 February 2021, retrieved 10 February 2021
- ^ a b PIARC (February 17, 2021), Electric Road Systems - PIARC Online Discussion, 34 minutes 34 seconds (standardization), 2 hours 36 minutes 51 seconds (standardization), 2 hours 35 minutes 25 seconds (maintenance), archived from the original on 2021-12-22
- ^ Martin G. H. Gustavsson, ed. (March 26, 2021), "Key Messages on Electric Roads - Executive Summary from the CollERS Project" (PDF), CollERS, p. 6, retrieved February 11, 2022
- ^ European Commission (July 14, 2021), Proposal for a REGULATION OF THE EUROPEAN PARLIAMENT AND OF THE COUNCIL on the deployment of alternative fuels infrastructure, and repealing Directive 2014/94/EU of the European Parliament and of the Council
- ^ a b Patrick Pélata; et al. (July 2021), Système de route électrique. Groupe de travail n°1 (PDF), archived from the original (PDF) on October 21, 2021
- ^ Laurent Miguet (April 28, 2022), "Sur les routes de la mobilité électrique", Le Moniteur
- ^ Final draft: Standardization request to CEN-CENELEC on 'Alternative fuels infrastructure' (AFI II) (PDF), European Commission, February 2, 2022, archived from the original (PDF) on July 9, 2022
- ^ Technical Specification for ground-based feeding systems for dynamic electric road charging infrastructure on road vehicles in operation CLC/prTS 50740, October 25, 2023
- ^ Regulation (EU) 2023/1804 of the European Parliament and of the Council of 13 September 2023 on the deployment of alternative fuels infrastructure, and repealing Directive 2014/94/EU, September 9, 2023
- ^ Fortsatt samarbete om elvägar med Frankrike och Tyskland, Infrastrukturdepartementet (Ministry of Infrastructure of Sweden), March 31, 2022
- ^ "Samarbete om elvägar med andra länder", Trafikutskottets betänkande 2022/23:TU4 - Infrastrukturfrågor, Riksdagen
- ^ a b Jakob Rogstadius (December 11, 2021), "Recommendations for Charging Infrastructure in Stockholm County" (PDF), RISE Rapport, 2022:01
- ^ a b Jakob Rogstadius (November 24, 2022), Interaktionseffekter mellan batterielektriska lastbilar, elvägar och statisk laddinfrastruktur (PDF), RISE
Jakob Rogstadius (November 23, 2022), Interaction Effects between Battery Electric Trucks, Electric Road Systems and Static Charging Infrastructure, archived from the original on December 23, 2022 (English translation) - ^ a b Lina Nordin; et al. (2023), Omvärldsanalys och faktorer som påverkar nyttjandegraden av elvägar (PDF), VTI, p. 48
- ^ a b c Government Offices of Sweden (October 15, 2020), Regeringen ökar tempot i elektrifieringsarbetet
- ^ Martin Gustavsson (May 12, 2020), Maturity of ERS power transfer technologies - 4th Electric Road Systems Conference 2020 (PDF)
- ^ a b c Regler för statliga elvägar SOU 2021:73 (PDF), Regeringskansliet (Government Offices of Sweden), September 1, 2021, pp. 291–297, archived from the original (PDF) on September 2, 2021
- ^ First electric road in Sweden inaugurated, Swedish Transport Administration, June 22, 2016
- ^ Mikael Hellgren; Nicholas Honeth, Efficiency of AC conductive eRoad charging system –Analysis of experimental data (PDF)
- ^ Daniel Boffey (April 12, 2018), "World's first electrified road for charging vehicles opens in Sweden", The Guardian
- ^ Elways - About, archived from the original on April 17, 2021
- ^ Per Mattsson (December 19, 2021), "Elvägs-uppstickarens nya giv: Automatiskt ladda bilen på 10 minuter", di.se
- ^ Per Mattsson (December 27, 2021), "30 experter: Det här var de största trenderna inom mobilitet 2021", di.se
- ^ Eva Janzon (May 2, 2019), Israeler bygger elväg på Gotland, Världen idag
- ^ Aileen Cho (August 31, 2022), "Q3 Tech Focus: Mixed Results as Smart Road Testing Begins", ENR
- ^ "ElectReon Completes Dynamic Wireless Charging Road For Trucks", InsideEVs, retrieved 2022-11-10
- ^ Patrik Widegren (December 13, 2021), "Elvägen på Gotland kan rivas upp nästa år", Sveriges Television
- ^ Anna Jutehammar (December 10, 2021), "Elvägen till flyget måste rivas upp efter projektet", Sveriges Radio
- ^ Fogden, Tom (April 11, 2022), "Electreon Extends and Expands Swedish Wireless In-Road Charging Pilot", Auto Futures, retrieved November 10, 2022
- ^ "Elbilsladdningsprojekt i Nyland i Kramfors – igen", SVT, October 19, 2022
- ^ A. Wendt et al., "Wireless Electric Road Systems – Technology Readiness and Recent Developments," 2024 IEEE Wireless Power Technology Conference and Expo (WPTCE), Kyoto, Japan, 2024, pp. 177-182, doi: 10.1109/WPTCE59894.2024.10557264.
- ^ Elaine Meskhi (December 2021), DynaCoV - Final Feasibility Report on DWPT Deployment within the UK
- ^ "Nästa generations elväg invigd i Lund av sydsvenskt konsortium – med energi- och digitaliseringsminister Anders Ygeman", Mynewsdesk (in Swedish), June 5, 2020, retrieved June 17, 2020
- ^ "Elonroad teams with Hydro to build road that dynamically charges electric vehicles", www.hydro.com, retrieved 2020-06-17
- ^ "Test av elväg vid Dannero travbana", Sveriges Radio, October 5, 2022
- ^ Anna Wilkens (February 8, 2023), "Nytt fokus på nedsänkt elväg – upphöjda elvägsskenor monteras bort", Innovation Skåne
- ^ Johann Bernövall (May 21, 2024), "Elonroad avslutar elvägstester efter fem år: "Fantastiskt pilotprojekt"", impactloop.se
- ^ a b Hasan Huseyin Coban (March 6, 2022), "Analyzing the Societal Cost of Electric Roads Compared to Batteries and Oil for All Forms of Road Transport" (PDF), Energies, 15 (5): 1925, doi:10.3390/en15051925
- ^ Krister Palo (September 15, 2020), Vägunderhåll och kostnader för olika typer av Elvägar (PDF), Trafikverket, p. 5
- ^ a b c Francisco J. Márquez-Fernández (May 20, 2019), Power conversion challenges with an all-electric land transport system (PDF), Swedish Electromobility Centre, archived from the original (PDF) on November 21, 2019
- ^ Börjesson M, Johansson M, Kågeson P (2021), "The economics of electric roads", Transportation Research Part C: Emerging Technologies, 125: 102990, doi:10.1016/j.trc.2021.102990, S2CID 214702482
- ^ Government Offices of Sweden (October 15, 2020), Planering för elvägar och snabbladdning
- ^ "Rebecka Johansson, Ministry of Infrastructure - ERS Regulations, policies and strategies in Sweden", Electric Road Systems - PIARC Online Discussion, November 4, 2021, 14 minutes 25 seconds into the video
- ^ Björn Hasselgren (October 9, 2019), Swedish ERS - program background, current analysis phase and plans ahead (PDF), Swedish Transport Administration
- ^ ABB Norge (August 11, 2011), Vi er med på bygging av første permanente el-vei for #tungtrafikk, i Sverige: E20 mellom Hallsberg og Örebro, 21 km, klar i 2025Delivery truckHigh voltage signSmiling face. Elektriske skinner mater lastebiler med strøm via glideskinnerThumbs up, Twitter
- ^ ABB (July 13, 2021), Industriföretag och startups skapar innovativt konsortium för att minska koldioxidutsläpp via elvägar [Industry leaders and startup companies form innovative consortium to reduce carbon emission through electric road solutions]
- ^ Swedish Ministry of Infrastructure (March 24, 2022), Uppdrag till Transportstyrelsen att föreslå ett avgiftssystem för statliga elvägar, retrieved March 24, 2022
- ^ a b Peter Höök (November 9, 2022), "Förenklat avgiftssystem för statliga elvägar", transportochlogistik.se
- ^ Geidne, Jonny (November 2022), Nytt avgiftssystem för att ladda fordon på statliga elvägar, Transportstyrelsen
- ^ Swedish Transport Administration (July 1, 2021), Sveriges första elväg byggs mellan Örebro och Hallsberg
- ^ Per Mattsson (January 15, 2022), "30 experter: Överraskningarna som kommer omforma vår mobilitet 2022", di.se
- ^ a b "Produktion Elväg E20 Örebro - Hallsberg", The Swedish Transport Administration's Procurement Plan (PDF), March 1, 2022, p. 28, archived from the original (PDF) on March 9, 2022
- ^ Henrik Wallström (June 5, 2020), Report electric road Region Örebro County (PDF), pp. 17–19, 49, 61, archived from the original (PDF) on January 11, 2022, retrieved January 11, 2022
- ^ Jonas Grönvik (September 1, 2021), "Sverige på väg att bli först med elvägar – Rullar ut ganska snabbt", Ny Teknik
External links
[edit]- Trafikverket (March 10, 2022), Sveriges första permanenta elväg
- PIARC (February 17, 2021), Electric Road Systems - PIARC Online Discussion
- Technical Committee 69 - Electrical power/energy transfer systems for electrically propelled road vehicles and industrial trucks, International Electrotechnical Commission