Sviluppo e sperimentazione di un sistema di ibridizzazione e del relativo sistema di controllo per veicoli convenzionali
Abstract
Recently, the possibility of upgrading conventional vehicles to Hybrid Electric Vehicles is gaining
interest. Among the different options for hybridization, researchers are focusing on electrification
of rear wheels in front‐driven vehicles, transforming the vehicle in a Through‐The‐Road (TTR)
parallel HEV.
This thesis deals with the development of an automotive hybridization kit (equipment, along with
associated techniques and methodologies), aimed at converting conventional cars into hybrid
solar vehicles (Mild‐Solar‐Hybrid). The main aspect of the projects consists into the integration of
state‐of‐the‐art components (in‐wheel motors, photovoltaic panels, batteries), and into the
development of an optimal controller for the power management.
A prototype of the hybridizing equipment – patented by the University of Salerno (Italy)‐ is
installed on a FIAT Grande Punto. A mild parallel hybrid structure is obtained by
substituting/integrating the rear wheels with 7kW in‐wheel motors and adding a lithium battery to
manage on‐board energy. Thus, the vehicle can operate in electric mode (when ICE is switched off
or disconnected by the front wheels) or in hybrid mode (when the ICE drives the front wheels and
the rear in‐wheel motors operate in traction mode or in generation mode, corresponding to a
positive or negative torque). The battery can be recharged both by rear wheels, when operating in
generation mode, and by photovoltaic panels.
The vehicle is also equipped with an EOBD gate (On Board Diagnostics protocol), which allows
accessing data such as pedal position, vehicle speed, engine speed, manifold pressure and other
variables. The Vehicle Management Unit (VMU), which is part of the invention and implements
control logics compatible with typical drive styles of conventional‐car users, receives the data from
OBD gate, from battery (SOC estimation) and drives in‐wheel motors by properly acting on the
electric node. In order to develop an effective and safe control strategy for wheel‐motors, a
precise real‐time knowledge of the Driver Intention is required. In particular, the detection of the
active gear is needed.
The thesis, focused on the main aspects of prototype design and realization, also provides insights
on control issues related to the integration of the above‐mentioned components, drivability and
safety. [edited by author]