Induction course

Thinking Highways
By Thinking Highways March 13, 2015 17:14

Induction course


The UNPLUGGED project (www.unplugged-project.eu, info@unplugged-project.eu) aims to investigate how the use of inductive charging of Electric Vehicles (EVs) in urban environments improves the convenience and sustainability of car-based mobility. In particular, it will investigate how smart inductive charging infrastructure can facilitate full EV integration in the urban road systems while improving customer acceptance and perceived practicality. UNPLUGGED will achieve these goals by examining in detail the technical feasibility, practical issues, interoperability, user perception and socio-economic impacts of inductive charging. As one special variant, inductive charging will be investigated thoroughly.

Today EVs are having a hard time being accepted by customers and diffusing in the market. Even though many aspects of EVs seem to make them very appealing (e.g. very low energy cost and zero tail pipe emissions) there are several concerns that people have with this technology:

  • Range anxiety: Because of the limited range of EVs caused by the relatively low capacity of today’s battery technology, the freedom of the driver is limited, which one of the major reasons to own a vehicle
  • EVs require a significantly higher initial investment than vehicles with common combustion engines due to the high cost of the energy storage (battery)
  • EV batteries need to recharge frequently and hence the driver has to find a suitable recharging stations and has to plan the routes accordingly

The charging process itself is very time consuming and not user-friendly

Comparing conductive charging to inductive charging

Inductive charging offers several advantages over the conductive charging method (using a cable):

  • It is easily operated and comfortable due to the automation of the charging process
  • Since there is no need to plug in a cable the driver will not have to get out of the car and get his hands dirty especially in rainy, snowy or muddy environments (which also do not affect the wireless inductive charging process)
  • There is no risk that the user will forget to plug in the vehicle at the end of the parking, losing the capability of a fit range for the following use of the car
  • The system is safe against vandalism, misuse/abuse and environmental influences (e.g. humidity) because all devices are encapsulated in the vehicle and the ground
  • There is no negative impact on the cityscape (all devices are hidden in the ground)
  • Without having to manually connect the vehicle to the grid the availability of the EV for vehicle-to-grid applications (V2G) is higher (e.g. for using the vehicle’s battery to store excess energy in the grid)

These abovementioned advantages already prove the usefulness of (static) inductive charging compared to the currently more common conductive charging infrastructure. However inductive charging will offer many more possibilities in the future, especially concerning en-route charging.

The potential of inductive en-route charging

With inductive en-route charging, EVs could be charged while standing at the traffic light, the bus stop or the taxi stand while it whould be impracticable with the conductive charging option. So, using wireless inductive charging, these short timeframes could be used to charge the EV and hence increase its range. The charging method above is called stationary inductive charging because the vehicle is standing still while charging.

In addition, there is also the possibility to charge the vehicle while it is actually moving. This charging method is called dynamic inductive charging. This holds the potential of giving the driver virtually limitless range as long as he stays on paths specifically adapted for dynamic inductive charging. This could lead to a reduction of battery size or the use of capacitors that would both lower the weight and the cost for the vehicle. The impact on the infrastructure has to be taken into account, so it has to be evaluated if or when, dynamic inductive charging is needed and preferable to only stationary inductive charging.

UNPLUGGED project description

Given the current challenges in mobility (mainly due to fossil fuels) and the open issues that EVs rise in relation to economic and social feasibility, the inductive charging technology could become a centrepiece if all of the different inductive charging solutions (static, stationary an dynamic) are combined and used for their best specific purpose.

In this context, UNPLUGGED project aims to investigate how the use of inductive charging of Electric Vehicles (EV) in urban environments improves the convenience and sustainability of car-based mobility. In particular, it will be investigated how smart inductive charging infrastructure can facilitate full EV integration in the urban road systems while improving customer acceptance and perceived practicality.

Technical solution

Almost every Battery Electric Vehicle (BEV), which is currently commercially available, comes with a wired battery charging system. However in a system with contactless battery charging, all plugging is omitted for the customer. Instead, the energy transfer takes place contactlessly through devices integrated into the ground and the vehicle. These devices can be airtightly encapsulated having two main advantages compared to conductive systems: It is easier to reach a high IP rating (e.g. 6K9K) and the system is protected against vandalism.

Current inductive charging systems suffer from a lack of efficiency, slow power transfer rates, inadequate safety considerations and are not interoperable. All these factors influence each other and will have to be optimized simultaneously in order to make this technology feasible for public use.

These problems become even more challenging when instead of the static inductive charging, we move on to stationary inductive charging. Stationary inductive charging describes all inductive charging that is carried out at charging points that lie on the driver’s route. This might include traffic lights, bus stops, taxi stands and so on. The actual power transfer does not work any differently from the static inductive charging (both stationary) but the time for the (re)charging and the proper positioning of the energy transfer units is much shorter. From the power grid’s point of view there is also a lack of information about how much energy will be needed for how long and at what location.

At this point en-route charging not only sets the technical challenges already described above (for stationary inductive charging) but a whole new set of questions involving technical and economic feasibility or even social impacts of this technology. However, as described in the beginning, one of the main issues right now is the lack of range with current batteries. With dynamic inductive charging one could charge the battery while driving effectively extending the range and making it possible to use smaller (and lighter) batteries or even make use of different energy storage such as capacitors (lighter, cheaper and with a longer life than batteries but with limited capacity) or hybrid solutions.

The three different types of charging build on each other (static -> stationary -> dynamic) and in order to reach the goal of making BEVs become an actual alternative to conventional combustion engines we should start at the bottom with the problems of static charging and begin solving them.

UNPLUGGED project technical proposal addresses a variety of different types of vehicles, including car, taxis, light duty vehicles and buses.

Demonstrators

The two fully operational testing platforms will allow for a parallel use for testing activies and are available to all participants. The first platform will be located in Aachen managed by FKA focussing mainly on the EV side of the charging system and the second platform, that will later be used for the demonstration, will be located in Zaragoza managed by CIRCE, Endesa and Enel. All institutions will be in charge of coordinating the activities to guarantee the interoperability of the system with the final demo site in Zaragoza.

Results

The UNPLUGGED project has made the following progress:

  • Face the challenges of the development of innovative on route inductive charging technologies, allowing EV to meet the growing demand of vehicles with longer distance autonomy and with smaller, cheaper and less weight batteries at the same time.
  • Contribute to stationary and on route inductive charging technologies by improving power transfer speed and efficiency, vehicle/coil positioning, magnetic and crash safety, inductive infrastructure devices protection against weather and vandalism.
  • Provide mechanisms to dramatically increase the interoperability of solutions developed among the different stakeholders participating in Unplugged, having in mind and keeping it open to other initiatives and projects.
  • Provide advances in the economic feasibility of the inductive charging technologies, both stationary and on route, by evaluating vehicle, infrastructure and power grid/utilities needs and TCO, as well as different billing possibilities.
  • Lead to better social acceptance of EVs and its required infrastructure by improving and demonstrating progress in users’ safety, comfort, ease of use, less impact in cityscape and better resilience to vandalism, as well as in users’ sense of freedom (one of the main reasons leading users to acquire vehicles)

UNPLUGGED has materialized these advances into the following outputs:

Products

  • Charging station for passenger vehicles (3.7 kW)
  • Charging station for commercial light duty vehicle (50 kW)
  • Positioning system that provides a positioning accuracy better than 10 cm combining a camera, RFID technology and an HMI adapted to the natural handling of a vehicle.
  • Wireless communication system between vehicle and charging station, with interoperability as a main target.

Studies

  • Assessment of the integration of wireless charging systems with vehicles and road infrastructure in urban areas
  • Study about vehicle integration of inductive charging technology (mechanical, electrical, communication)

UNPLUGGED consortium is led by ENIDE and FKA
Joining the efforts of the main stakeholders in the sector are: vehicle industry (as Volvo, Centro Ricerche Fiat, Hella or Continental), power supply industry (ENDESA and ENEL) and transport operators (as Transport for London) among several key research and technological centers.

ENIDE (www.enide.eu) brings innovation to logistics and personal mobility, with a particular focus on Electric Vehicles (EV): we are collaborating in projects such as FABRIC on inductive charging for vehicles (especially when the vehicle is moving) and ZeEUS about the deployment of electric bus in urban areas.

Concerning EVs, ENIDE focuses on:

  • EV fleet management
  • Integration of EV into the transport system and the grid
  • Demand forecast in real time, using the profile of use of the vehicles
  • Developing Apps interacting with the vehicle
  • Adapting existing route planners

DO NOT MISS THE FINAL EVENT!

The UNPLUGGED final event will take place the 26th March in Zaragoza, Spain. It will include discussions about inductive charging and the challenge and opportunities of the electro mobility sector.  The event will also involve cutting edge R+D European projects related to electric vehicles (eCo-FEV, FABRIC, Fastincharge,) as well as the vision of cities and industry. Registration is free and is currently available.


FYI

For more information on UNPLUGGED contact Martí Massot Vila at marti.massot@enide.eu or visit www.enide.eu

This project has received funding from the European Union’s Seventh Framework Programme for research, technological development and demonstration under grant agreement no 314126.

Thinking Highways
By Thinking Highways March 13, 2015 17:14