I would think that in the majority of new design cases in the auto industry BTE will be improved in turbo projects compared to the NA alternative. I would be interested to see figures of a case where BTE was reduced by fitting a turbo. It sounds like a rather obscure case. What would be the motivation? Just brute power maximization?riff_raff wrote:...the BTE of an SI engine can be either improved or reduced by turbocharging.
Isn’t the purpose of boosting always to increase max power over an otherwise identical NA engine? An NA engine could feature identical combustion pressure. What, other than power, would turbocharging add?WhiteBlue wrote:I would think that in the majority of new design cases in the auto industry BTE will be improved in turbo projects compared to the NA alternative. I would be interested to see figures of a case where BTE was reduced by fitting a turbo. It sounds like a rather obscure case. What would be the motivation? Just brute power maximization?riff_raff wrote:...the BTE of an SI engine can be either improved or reduced by turbocharging.
The wide spread application of turbo charging is done in order to downsize NA engines and improve fuel economy IMO. The trend got started with diesels where turbos are practically a standard in modern design. This trend is now being followed by spark ignited petrol engines although some mainly US based users seem to deny this trend. At least the European auto industry seems to be on a crusade to downsize and turbocharge practically every new engine they introduce. This may exclude some exotic super cars and very low price cars but the centre piece of the European road car market goes for downsized designs. This leads me to the conclusion that the motive for turbo charging is more based on fuel economy than on power maximization.olefud wrote:Isn’t the purpose of boosting always to increase max power over an otherwise identical NA engine? An NA engine could feature identical combustion pressure. What, other than power, would turbocharging add?
I think you’re making my point. A similarly downsized NA engine is a bit on the wimpy side. In order to gain back enough power to be socially acceptable, the engine is subjected to turbocharging. But the NA engine would enjoy a cooler mixture, higher compression ratio (volumetric) and be even less weighty than the turbo.WhiteBlue wrote:The wide spread application of turbo charging is done in order to downsize NA engines and improve fuel economy IMO. The trend got started with diesels where turbos are practically a standard in modern design. This trend is now being followed by spark ignited petrol engines although some mainly US based users seem to deny this trend. At least the European auto industry seems to be on a crusade to downsize and turbocharge practically every new engine they introduce. This may exclude some exotic super cars and very low price cars but the centre piece of the European road car market goes for downsized designs. This leads me to the conclusion that the motive for turbo charging is more based on fuel economy than on power maximization.olefud wrote:Isn’t the purpose of boosting always to increase max power over an otherwise identical NA engine? An NA engine could feature identical combustion pressure. What, other than power, would turbocharging add?
do you understand that diesel engines have a huge surplus of air especially at low speeds, necessary to get combustion of the fuel ?WhiteBlue wrote: The wide spread application of turbo charging is done in order to downsize NA engines and improve fuel economy IMO. The trend got started with diesels where turbos are practically a standard in modern design. This trend is now being followed by spark ignited petrol engines although some mainly US based users seem to deny this trend.
That's a funny way to see things. Needless to say that I don't agree. With the rest of the world I prefer more fuel efficient engines. But I see that isn't socially acceptable to you. I respect such personal choices.olefud wrote: A similarly downsized NA engine is a bit on the wimpy side. In order to gain back enough power to be socially acceptable, the engine is subjected to turbocharging. But the NA engine would enjoy a cooler mixture, higher compression ratio (volumetric) and be even less weighty than the turbo. It’s all about power.
Do not worry about me not understanding your thoughts. The point is that the perceived disadvantages of turbocharged SI engines are going to disappear with the development of the technology. For instance compression ratio will increase in the years to come as it has already done in the past. The advantages of turbocharging particularly the use of waste energy to run higher operating pressures will stay.Tommy Cookers wrote:do you understand that diesel engines have a huge surplus of air especially at low speeds, necessary to get combustion of the fuel ?
(so increased massflow/power by turbocharging (relatively) reduces the disproportionate mechanical losses of the NA diesel)
do you understand that turbocharging a diesel does not require a reduction in compression ratio ?(detonation is needed)
unlike turbocharging a SI engine, where lowering the CR is required to avoid detonation (in a fair comparison)
these are reasons why turbocharging a diesel is always advantageous
they do not apply to the SI engine
Tommy Cookers-Tommy Cookers wrote:....do you understand that turbocharging a diesel does not require a reduction in compression ratio ?(detonation is needed) unlike turbocharging a SI engine, where lowering the CR is required to avoid detonation (in a fair comparison)....these are reasons why turbocharging a diesel is always advantageous
they do not apply to the SI engine
I think the engineers would of love to have one these 24 years ago. 
Again, you’re missing the point. The NA engine is the more efficient engine for reasons including those mentioned. The social acceptability relates to the lower power of the NA engine and the inability to satisfy customers. Thus, at the price of lower efficiency, the engine is turbocharged solely to gain power and social acceptance on the showroom floor.WhiteBlue wrote:That's a funny way to see things. Needless to say that I don't agree. With the rest of the world I prefer more fuel efficient engines. But I see that isn't socially acceptable to you. I respect such personal choices.olefud wrote: A similarly downsized NA engine is a bit on the wimpy side. In order to gain back enough power to be socially acceptable, the engine is subjected to turbocharging. But the NA engine would enjoy a cooler mixture, higher compression ratio (volumetric) and be even less weighty than the turbo. It’s all about power.
Your logic is somewhat confused. A car buyer who considers buying a car is not interested to know how much power his engine would hypothetically have without the turbo charger fitted. All he wants to know is the total power, the acceleration, the top speed, the fuel economy, the handling and looks of his object of desire. The chance that our guy will buy a downsized, turbocharged car with better fuel economy than an alternative NA engined option is rising all the time. I do not need to rely on my own experience to know that. Our expert from Garrett told us that in the interview that I posted in the opening post. Privately I'm just wondering how long people will listen to sales people who are bullshitting them with the story of wonderful efficiency of NA engines that unfortunately return only 15 miles to a gallon.olefud wrote:The social acceptability relates to the lower power of the NA engine and the inability to satisfy customers. Thus, at the price of lower efficiency, the engine is turbocharged solely to gain power and social acceptance on the showroom floor.
Good questions. IMO, under full boost, not only would pumping losses be diminished, but some low level “compounding” work could be recovered with enough boost. This would depend on the high-boost duty cycle of the engine –high in a racing engine, low in a road engine.Smokes wrote:Everyone here knows how turbocharging works.
in regards to the BTE of the engine
Assuming the the turbo compressor and impeller has spooled up to a working rpm to deliver an usable mass flow rate of air.
Turbocharging an engine will use the waste gasses to force compressed air into the engine. This statement is true right.
Does mean that the pumping losses of the engine are reduced and the that charge is mixed better due to swirl and increase compression ratio so that the energy generated on the power stroke is higher.
What is the pumping loss reduction and the typical useful work done by the fuel charge?
When the turbo compressor and impeller is either running to fast or to slow to deliver a mass flow rate.
Do the pumping losses increase to take into account the drag of the compressor and the manifold?
Also the valve overlap for a turbocharged is minimise compared to a N/A engine does this also reduce the charge mix?
how much useful work of the charge is lost when the engine cannot pull the ideal amount of air into the engine and the compression rate is dropped?
Does this also mean a turbocharged SI CI engine efficent operating range is dependant on the operating range of the turbo compressor and impeller.
You’re of course correct that efficiency can be improved in many ways, including reducing friction. But many of these have been exploited to the point of diminishing returns –and the object of this thread is turbo charging vis-à-vis efficiency. Further, the question of thermal efficiency differs greatly in competition and road engines –though the former changes towards the road engine with a fuel flow restriction.Smokes wrote:Everyone seems to forget the basics of engine efficiency.
Strapping on a turbo just means more fuel and air can be drawn into the engine and compressed to a high enough ratio without knocking.
For the charge to start doing work it has to it has to over come engine friction pumping losses, power train inertia, some of the energy is turned in to heat and light. Also not all of the pressure generated by the charge is used up by the time the piston hits bdc.
All the turbo can does to improve efficiency is reduce pumping losses by using the waste energy from the exhaust gasses and force air into the cylinders.
More efficiency can be gained by reducing engine friction which is where illmor/mercedes were going before FIA banned using beryllium.
