The pre-2006 Cooper S was supercharged but the current S is Turbo-charged. A bit late to the conversation but heh, my parents have one so I thought I should chip in.Giblet wrote:I think the Mini is supercharged isn't it?
Utter nonsense, metal-to-metal rolling friction is only partially dependent on contact-pressure, compare with a roller-bearing where the viscous-losses are where your energy goes.autogyro wrote:Not for the direct power figures you require. Heavy enough spring (non flow) actuation would in anycase increase torque loss the higher the torque transfered through the system. So the actual efficiency has to be variable and cannot be quoted as one figure anyway. Dont forget, all transmission systems have variable efficiency depending on the ratio of transfer and varying frictional losses. With this toloroidal system frictional losses are much increased keeping the disks under pressure.WhiteBlue wrote:Why would that need energy? Can't they use springs or hydraulic pressure without flow?
You are not telling us anything new there. The point is that the double conversion from mechanical power to electrical and back requires the energy to be passed through two MGUs and two inverters. The weight of those installations and an electric storage capacity is not free even when you use KERS. You add weight for using the MGUs, the battery and the inverters that are not needed with a CVT. HERS with turbo compounding can produce more recovered energy than KERS. If the electric power train has to deal with the much increased loads everything gets heavier.autogyro wrote:The current from a turbo generator can be sent primarily to a powertrain motor generator for direct traction.
Excess can be fed to batteries (or a combination using capacitors or flywheel as well to improve charge/apply times)along with energy harvested from braking.
Stored energy from batteries can be used to drive compressor on induction as needed and can also be used for gearshifts on a intigral gearbox KERS/HYBRID unit.
Much heavier than F1 gearbox.autogyro wrote:What if the KERS/HYBRID motor/generator is also the gearbox with no extra gearing and capable of both harvesting and applying electrical energy at the same time?
I wonder if there's something your magic 'box cannot do Gyro, whistling "Waltzing Mathilda" perhaps?autogyro wrote:What if the KERS/HYBRID motor/generator is also the gearbox with no extra gearing and capable of both harvesting and applying electrical energy at the same time?
Nope the geartrain would be lighter and the casing would contain even burst loads.timbo wrote:Much heavier than F1 gearbox.autogyro wrote:What if the KERS/HYBRID motor/generator is also the gearbox with no extra gearing and capable of both harvesting and applying electrical energy at the same time?
Perhapsxpensive wrote:I wonder if there's something your magic 'box cannot do Gyro, whistling "Waltzing Mathilda" perhaps?autogyro wrote:What if the KERS/HYBRID motor/generator is also the gearbox with no extra gearing and capable of both harvesting and applying electrical energy at the same time?
It still would not disable the laws of physics. You still have to have separate electric generating capacity, electric buffering and separate electric motor capacity. A permanently working turbo extraction does not allow you to use the same MGU that you can use for KERS. You must install separate capacity and that forces the two conversions. However clever you arrange that mechanically it would still have the same weight and the same losses of a conventional design. Double electromechanical conversion puts you at 81-85% efficiency before we even speak about buffering with batteries, capacitors or flywheels.autogyro wrote:What if the KERS/HYBRID motor/generator is also the gearbox with no extra gearing and capable of both harvesting and applying electrical energy at the same time?
