25-03-2017, 03:56 PM
Hybrid drivetrain systems are becoming more prevalent in automotive and commercial vehicle applications and have also been introduced for the 2009 Formula 1 season motorsport. The development of F1 has the clear intention to direct the technical development in the port of engines to impact the key subject of the fuel efficiency in the conventional vehicles. In order to promote all technical developments, the type of system (electrical, mechanical, hydraulic, etc.) For application F1 has not been specified The development of energy saving systems for industrial and mobile applications has been an interesting topic in The previous decade. Several systems have been proposed and are generally referred to as hybrid systems. Hybrid electrical systems have the advantages of improved control, high efficiency and high specific energy. However, low specific power and high price were disadvantages of these systems.
A significant result of this action is the renewed interest and development of hybrid mechanical systems comprising a high-speed composite flywheel and a fully toroidal traction transmission (CVT) transmission. A steering wheel-based mechanical hybrid has few system components, weight and dispense with changes in the state of energy of electrical systems that produce a highly efficient and dense hybrid energy system. Due to the simplicity of the system, the mechanical hybrid provides a measured efficiency of 72% round trip in about half the package, half the weight and a quarter of the cost of an electric hybrid system. Hybrid systems using flywheels have been considered advantageous for some vehicle applications because of their low cost, ruggedness, strength and high specific energy. In addition, its high speed has been studied with specific systems of superior energy and power, which reduces the gap between theory and applications of flywheel systems. The difficulty in continuously variable transmission (CVT) control and the problem of the dynamics of a high-speed steering wheel were outstanding issues of mechanical hybrid systems.
A significant result of this action is the renewed interest and development of hybrid mechanical systems comprising a high-speed composite flywheel and a fully toroidal traction transmission (CVT) transmission. A steering wheel-based mechanical hybrid has few system components, weight and dispense with changes in the state of energy of electrical systems that produce a highly efficient and dense hybrid energy system. Due to the simplicity of the system, the mechanical hybrid provides a measured efficiency of 72% round trip in about half the package, half the weight and a quarter of the cost of an electric hybrid system. Hybrid systems using flywheels have been considered advantageous for some vehicle applications because of their low cost, ruggedness, strength and high specific energy. In addition, its high speed has been studied with specific systems of superior energy and power, which reduces the gap between theory and applications of flywheel systems. The difficulty in continuously variable transmission (CVT) control and the problem of the dynamics of a high-speed steering wheel were outstanding issues of mechanical hybrid systems.