22 April 2014
Toyota’s FPEG features a hollow step-shaped piston, combustion chamber and gas spring chamber. Click to enlarge.A team at Toyota Central R&D Labs Inc. is developing a prototype 10 kW Free Piston Engine Linear Generator (FPEG) featuring a thin and compact build, high efficiency and high fuel flexibility. Toyota envisions that a pair of such units (20 kW) would enable B/C-segment electric drive vehicles to cruise at 120 km/h (75 mph). The team presented two papers on the state of their work at the recent SAE 2014 World Congress in Detroit.
The Toyota FPEG is based on a double piston system; at one end is the combustion chamber, and at the other, the adjustable gas spring chamber. Burned gas is scavenged out through exhaust valves mounted in the cylinder head of the combustion chamber; fresh air is brought in through the scavenging port at the side wall of the cylinder liner.
A portion of the kinetic energy of the piston is stored in the gas spring, and extracted on the return stroke to the combustion chamber side. A magnetic “mover” is mounted at the outer periphery of the piston; the mover and the stator coils together comprise the linear generator component of the FPEG.
- The larger cross-sectional area of the gas spring chamber leads to lower compression temperature of the gas spring chamber and consequently decreased heat loss.
- The piston has a hollow structure and moves along a column stay, which in turn enables the construction of a cooling oil passage within the stay. The key technologies to deliver stable continuous operation of an FPEG are lubricating, cooling, and control logic. (The Toyota team’s second paper deals exclusively with the control system.)
- The inner periphery of the hollow piston also serves as a sliding surface on the column stay, enabling a steady small clearance between the magnets and coil for improved generating efficiency.
- The magnet is set far from the piston top, preventing magnet degaussing by heating.
The researchers developed a one-dimensional cycle simulation to investigate the performance of the proposed structure, and used it to assess spark ignition combustion (SI) and premixed charged compression ignition combustion (PCCI). They achieved output power of 10 kW with both SI and PCCI combustion cases; the PCCI combustion case realized 42% thermal efficiency.
They then constructed an FPEG prototype with a uni-flow scavenging type, two-stroke SI combustion system as an experimental study. They used ceramic-coated piston rings and cylinder liner they developed in order to ensure the smooth sliding of the piston even under insufficient lubrication. Poppet valves seated in a water-cooled cylinder head were actuated by hydraulic valve trains to control exhaust valve timing. Direct injection reduced unburned hydrocarbon emissions exhausted through the scavenging process.
A pressure regulating valve in the gas spring chamber enabled a variable gas mass, thereby varying the stiffness of the gas springs—one of the variables to shift the FPEG to different operating points.
The linear generator was a permanently excited synchronous machine consisting of the stationary coil, the mover (based on neodymium-iron-boron magnets) attached to the piston, and iron-cored stator. The poer electronics drive the machine as both a motor and a generator.
The researchers designed the prototype control system to ensure that the compression ratio was kept to the values which enable stable combustions—i.e., the generating load coefficient is variable, not constant. The coefficient is determined by a feedback control method based on the postion and velocity of the piston.
As there is no crank mechanism, the piston position in an FPEG is not defined with crank angle. However, knowing the piston position is critical not only to timings (fuel injection, ignition, opening/closing exhaust valves), but also to mode selections of driving or generating. To determine piston position, the Toyota researchers count plural-lines grooves engraved on the side surface of the piston body with gap sensors fixed on the inner wall of the cylinder block. (The detailed method of detecting and controlling piston position is the subject of the second paper.)
The generator control logic must meet the following requirements, according to the researchers:
- Assuming a multi-unit vehicle application, the multiple FPEGs would cancel out vibration through a horizontally opposed layout; the frequency and phase of the piston oscillation should be controllable.
- TDC and BDC need to be precisely controlled for stabilizing two-stroke combustion.
- After knocking or misfire, the oscillation must continue robustly.
The experimental analysis also showed that the precise control of ignition position is essential for stable operation of the FPEG.
In future work, the research team plans to improve the power generation of the system and to perform a quantitative analysis of the efficiency.
- Kosaka, H., Akita, T., Moriya, K., Goto, S. et al. (2014) “Development of Free Piston Engine Linear Generator System Part 1 - Investigation of Fundamental Characteristics,” SAE Technical Paper 2014-01-1203 doi:10.4271/2014-01-1203
- Goto, S., Moriya, K., Kosaka, H., Akita, T. et al. (2014) “Development of Free Piston Engine Linear Generator System Part 2 - Investigation of Control System for Generator,” SAE Technical Paper 2014-01-1193 doi:10.4271/2014-01-1193