Enabling Fast Charging - Infrastructure and Economic Considerations
10/10/2017
The ability to charge battery electric vehicles (BEVs) on a time scale that is on par with the time to fuel an internal combustion engine vehicle (ICEV) would remove a significant barrier to the adoption of BEVs. However, for viability, fast charging at this time scale needs to also occur at a price that is acceptable to consumers. Therefore, the cost drivers for both BEV owners and charging station providers are analyzed. In addition, key infrastructure considerations are examined, including grid stability and delivery of power, the design of fast charging stations and the design and use of electric vehicle service equipment. Each of these aspects have technical barriers that need to be addressed, and are directly linked to economic impacts to use and implementation. This discussion focuses on both the economic and infrastructure issues which exist and need to be addressed for the effective implementation of fast charging at 400 kW and above. extreme fast charging (XFC); electric vehicle infrastructure; battery electric vehicles; demand charges; total cost of ownership, economicsIn so doing, it has been found that there is a distinct need to effectively manage the intermittent, high power demand of fast charging, strategically plan infrastructure corridors, and to further understand the cost of operation of charging infrastructure and BEVs.
Authors: Burnham, A.; Dufek, E.J.; Stephens, T.; Francfort, J.; Michelbacher, C.; Carlson, R.B.; Zhang, J.; Vijayagopal, R.; Dias, F.; Mohanpurkar, M.; Scoffield, D.; Hardy, K.; Shirk, M.; Hovsapian, R.; Ahmed, S.; Bloom, I.; Jansen, A.N.; Keyser, M.; Kreuzer, C.; Markel, A.; Meintz, A.; Pesaran, A.; Tanim, T.R.
Notes: This Journal of Power Sources article (Vol. 367 (2017): pp. 237-249) is copyrighted by Elsevier B.V. and only available by accessing it through Science Direct.
From Gas to Grid: Building Charging Infrastructure to Power Electric Vehicle Demand
10/3/2017
This report identifies the key hurdles that have inhibited the growth of charging infrastructure, and explains how they might be overcome, along with the best practices for siting chargers and designing electricity tariffs for EV charging stations.
Authors: Fitzgerald, G.; Nelder, C.
Notes: This copyrighted publication is available on the Rocky Mountain Institute website.
Enabling Fast Charging: A Technology Gap Assessment
10/1/2017
In this report, researchers at Idaho National Laboratory teamed with Argonne National Laboratory and the National Renewable Energy Laboratory to identify technical gaps to implementing an extreme fast charging network in the United States. This report highlights technical gaps at the battery, vehicle, and infrastructure levels.
Authors: Howell, D.; Boyd, S.; Cunningham, B.; Gillard, S.; Slezak, L.; Ahmed, S.; Bloom, I.; Burnham, A.; Hardy, K.; Jansen, A.N.; Nelson, P.A.; Robertson, D.C.; Stephens, T.; Vijayagopal, R.; Carlson, R.B.; Dias, F.; Dufek, E.J.; Michelbacher, C.J.; Mohanpurkar, M.; Scoffield, D.; Shirk, M.; Tanim, T.; Keyser, M.; Kreuzer, C.; Li, O.; Markel, A.; Meintz, A.; Pesaran, A.; Santhanagopalan, S.; Smith, K.; Wood, E.; Zhang, J.
Transportation Electrification Beyond Light Duty: Technology and Market Assessment
9/1/2017
This report focuses on electrification of government, commercial, and industrial fleets and provides the background necessary to understand the potential for electrification in these markets. Specifically, it covers the challenges and opportunities for electrification in the service and goods and people movement fleets to guide policy makers and researchers in identifying where federal investment in electrification could be most beneficial.
Authors: Birky, A.K.; Laughlin, M.; Tartaglia, K.; Price, R.; Lin, Z.
National Plug-In Electric Vehicle Infrastructure Analysis
9/1/2017
This document describes a study conducted by the National Renewable Energy Laboratory quantifying the charging station infrastructure required to serve the growing U.S. fleet of plug-in electric vehicles (PEVs). PEV sales, which include plug-in hybrid electric vehicles (PHEVs) and battery electric vehicles (BEVs), have surged recently. Most PEV charging occurs at home, but widespread PEV adoption will require the development of a national network of non-residential charging stations. Installation of these stations strategically would maximize the economic viability of early stations while enabling efficient network growth as the PEV market matures. This document describes what effective co-evolution of the PEV fleet and charging infrastructure might look like under a range of scenarios. To develop the roadmap, NREL analyzed PEV charging requirements along interstate corridors and within urban and rural communities. The results suggest that a few hundred corridor fast-charging stations could enable long-distance BEV travel between U.S. cities. Compared to interstate corridors, urban and rural communities are expected to have significantly larger charging infrastructure requirements. About 8,000 fast-charging stations would be required to provide a minimum level of coverage nationwide. In an expanding PEV market, the total number of non-residential charging outlets or 'plugs' required to meet demand ranges from around 100,000 to more than 1.2 million. Understanding what drives this large range in capacity requirements is critical. For example, whether consumers prefer long-range or short-range PEVs has a larger effect on plug requirements than does the total number of PEVs on the road. The relative success of PHEVs versus BEVs also has a major impact, as does the number of PHEVs that charge away from home. This study shows how important it is to understand consumer preferences and driving behaviors when planning charging networks.
Authors: Wood, E.; Rames, C.; Muratori, M.; Raghavan, S.; Melaina, M.
Fuel Consumption Sensitivity of Conventional and Hybrid Electric Light-Duty Gasoline Vehicles to Driving Style
8/11/2017
Aggressive driving is an important topic for many reasons, one of which is higher energy used per unit distance traveled, potentially accompanied by an elevated production of greenhouse gases and other pollutants. Examining a large data set of self-reported fuel economy (FE) values revealed that the dispersion of FE values is quite large and is larger for hybrid electric vehicles (HEVs) than for conventional gasoline vehicles. This occurred despite the fact that the city and highway FE ratings for HEVs are generally much closer in value than for conventional gasoline vehicles. A study was undertaken to better understand this and better quantify the effects of aggressive driving, including reviewing past aggressive driving studies, developing and exercising a new vehicle energy model, and conducting a related experimental investigation. The vehicle energy model focused on the limitations of regenerative braking in combination with varying levels of driving-style aggressiveness to show that this could account for greater FE variation in an HEV compared to a similar conventional vehicle. A closely matched pair of gasoline-fueled sedans, one an HEV and the other having a conventional powertrain, was chosen for both modeling and chassis dynamometer experimental comparisons. Results indicate that the regenerative braking limitations could be a main contributor to the greater HEV FE variation under the range of drive cycles considered. The complete body of results gives insight into the range of fuel use penalties that results from aggressive driving and why the variation can be larger on a percent basis for an HEV compared to a similar conventional vehicle, while the absolute fuel use penalty for aggressive driving is generally larger for conventional vehicles than HEVs.
Authors: Thomas, J.; Huff, S.; West, B.; and Chambon, P.
Foothill Transit Battery Electric Bus Demonstration Results: Second Report
6/30/2017
This report summarizes results of a battery electric bus (BEB) evaluation at Foothill Transit, located in the San Gabriel and Pomona Valley region of Los Angeles County, California. Foothill Transit is collaborating with the California Air Resources Board and the U.S. Department of Energy's (DOE's) National Renewable Energy Laboratory to evaluate its fleet of Proterra BEBs in revenue service. The focus of this evaluation is to compare performance of the BEBs to that of conventional technology and to track progress over time toward meeting performance targets. This project has also provided an opportunity for DOE to conduct a detailed evaluation of the BEBs and charging infrastructure. This is the second report summarizing the results of the BEB demonstration at Foothill Transit and it provides data on the buses from August 2015 through December 2016. Data are provided on a selection of compressed natural gas buses as a baseline comparison.
Authors: Eudy, L.; Jeffers, M.
Considerations for Corridor and Community DC Fast Charging Complex System Design
6/15/2017
This report focuses on direct current fast charger (DCFC) systems and how they can be deployed to provide convenient charging for plug-in electric vehicle drivers. First, the report shares lessons learned from previous DCFC deployment and data collection activities. Second, it establishes considerations and criteria for designing and upgrading DCFC complexes. Third, it provides cost estimates for hypothetical high-power DCFC complexes that meet simplified design requirements. Finally, it presents results for a business case analysis that shed light on the financial challenges associated with DCFCs.
Authors: Francfort, J.; Salisbury, S.; Smart, J.; Garetson, T.; Karner, D.
Public Sector Fleet EV Procurement Examples: A Case Study of Three All-Electric Vehicle Procurements Conducted by the U.S. Navy, City of New Bedford, and City of Seattle
6/6/2017
The deployment of EVs helps fleets to reduce air pollution from vehicle emissions and lower operating costs associated with maintenance and fueling. However, EV procurement by fleets has been limited by the higher up-front purchase costs and lack of availability of EVs compared to their gasoline counterparts, as well as the availability of charging infrastructure. Despite the existing barriers, many state and local public fleets have successfully integrated EVs to their fleets, and have used innovative procurement strategies to reduce the acquisition costs of EVs. This case study explores EV procurements conducted by the U.S. Navy, the City of New Bedford in Massachusetts, and the City of Seattle in Washington State—examples of public fleet procurements that captured financial incentives to reduce the vehicles’ upfront cost.
Authors: Nigro, N.
King County Metro Battery Electric Bus Demonstration: Preliminary Project Results
5/22/2017
The U.S. Federal Transit Administration (FTA) funds a variety of research projects that support the commercialization of zero-emission bus technology. To evaluate projects funded through these programs, FTA has enlisted the help of the National Renewable Energy Laboratory (NREL) to conduct third-party evaluations of the technologies deployed under the FTA programs. NREL works with the selected agencies to evaluate the performance of the zero-emission buses compared to baseline conventional buses in similar service. The evaluation effort will advance the knowledge base of zero-emission technologies in transit bus applications and provide 'lessons learned' to aid other fleets in incrementally introducing next generation zero-emission buses into their operations. This report provides preliminary results from a fleet of 3 BEBs operated by King County Metro in Seattle, Washington.
Authors: Eudy, L.; Jeffers, M.
Massachusetts Fuel Cell Bus Project: Demonstrating a Total Transit Solution for Fuel Cell Electric Buses in Boston
5/22/2017
The Federal Transit Administration's National Fuel Cell Bus Program focuses on developing commercially viable fuel cell bus technologies. Nuvera is leading the Massachusetts Fuel Cell Bus project to demonstrate a complete transit solution for fuel cell electric buses that includes one bus and an on-site hydrogen generation station for the Massachusetts Bay Transportation Authority (MBTA). A team consisting of ElDorado National, BAE Systems, and Ballard Power Systems built the fuel cell electric bus, and Nuvera is providing its PowerTap on-site hydrogen generator to provide fuel for the bus.
Authors: Eudy, L.
Capturing the Federal EV Tax Credit for Public Fleets: A Case Study of Multi-Jurisdictional EV Fleet Procurement in Alameda County, California
4/26/2017
Alameda County, California, led a collective purchase of 90 EVs for ten county and municipal public fleets. The aggregate procurement resulted in the purchase of 64 Ford Focus EV sedans and 23 Nissan LEAF EV sedans. The jurisdictions also conducted aggregate procurements for EV charging stations and charging station installations. This publication provides an overview of the procurement process and details how it was successful in attracting bids from local vendors for the purchase of EVs, while reducing vehicle purchase administrative costs for participating fleets.
Authors: Nigro, N.
Implementing Workplace Charging within Federal Agencies
4/19/2017
This case study, prepared for the U.S. Department of Energy Vehicle Technologies Office, draws from available information and lessons learned from federal agencies that have piloted plug-in electric vehicle (PEV) workplace charging programs. It can be challenging for organizations to involve all the key stakeholders needed to develop a charging program, but engaging them at an early stage can simplify the process of setting an adequate plan for the workplace. Key stakeholders may include workplace charging managers, facilities managers, parking managers, employee PEV drivers, legal counsel, employee benefits managers, and union representatives.
Multiple PEV charging stations are available on the GSA schedule. Agencies will need to select the charging station type and design that is most appropriate for each specific worksite - Level 1, Level 2, or DC Fast Charging. In addition, the GSA Blanket Purchase Agreement (BPA) can help reduce upfront costs, which will help keep the reimbursement fees within the threshold of what employees are willing to pay.
Authors: Smith, M.
EVgo Fleet and Tariff Analysis; Phase I: California
4/4/2017
Public direct current (DC) fast chargers are anticipated to play an important role in accelerating plug-in electric vehicle (PEV) adoption and mitigating emissions. This project analyzed charging session data in 2016 from all 230 EVgo DCFC stations in California to determine the key factors that contribute to the electricity costs and alternatives that may be available to reduce those costs, and to provide guidance for future rate design discussions.
Authors: Fitzgerald, G.; Nelder, C.
Battery Electric Buses - State of the Practice
1/26/2017
This synthesis report documents current practices of transit systems for deploying battery electric buses, including planning, procurement, infrastructure installation, and operations and maintenance. The report is intended for transit agencies that are interested in understanding the potential benefits and challenges associated with the introduction and operation of battery electric buses. It is also valuable to manufacturers trying to better meet the needs of their customers and to federal, state, and local funding agencies and policy makers.
Authors: Hanlin, J.; Reddaway, D.; Lane, J.
Notes:
This copyrighted National Academies of Sciences, Engineering, and Medicine publication can be downloaded from the National Academies Press website.