@FW17 - turbo compounding is different to compound turbo-charging.
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@FW17 - turbo compounding is different to compound turbo-charging.
Combustion or production issues?Bill wrote: ↑18 Jan 2026, 17:41Some teams are experiencing fuel combustions problems with there engine and have ask for some concessions from fia to run fuel that has not been homologated during testing.so why are the media not reporting on these and follow up the story do some digging and identify who these are.do some real reporting not lazy click bait thing maybe they are afraid of what they may find maybe it will conflict with the prevailing narrative that a particular manufacturer is going to dominate.
Both the engine are sensitive to very small variations in fuel qualitywuzak wrote: ↑18 Jan 2026, 18:01Combustion or production issues?Bill wrote: ↑18 Jan 2026, 17:41Some teams are experiencing fuel combustions problems with there engine and have ask for some concessions from fia to run fuel that has not been homologated during testing.so why are the media not reporting on these and follow up the story do some digging and identify who these are.do some real reporting not lazy click bait thing maybe they are afraid of what they may find maybe it will conflict with the prevailing narrative that a particular manufacturer is going to dominate.
I read that this was because there was a manufacturing constraint for the Barcelona test. My guess is its Mercedes/Petronas because they have 4 teams to supply and Petronas just isn't in the same league as the other fuel suppliers who have decades of R&D and tens of billions invested in sustainable fuels.Bill wrote: ↑18 Jan 2026, 17:41Some teams are experiencing fuel combustions problems with there engine and have ask for some concessions from fia to run fuel that has not been homologated during testing.so why are the media not reporting on these and follow up the story do some digging and identify who these are.do some real reporting not lazy click bait thing maybe they are afraid of what they may find maybe it will conflict with the prevailing narrative that a particular manufacturer is going to dominate.
About the same way any of us, throwing at a dart board. The manufacturers aren’t running to to the media with anything.
The turbine used in F1 utilises both pressure and blowdown pulses. Have you heard of a company call GARRETT? They know a thing or two about turbochargers. Here is an article posted on their website. https://www.garrettmotion.com/wp-conten ... vanced.pdfsaviour stivala wrote: ↑17 Jan 2026, 20:33The MGU-H- ERA turbocharger turbine used in formula 1 is a pressure turbine type and not a blow-down type of turbine, no matter what you and T C says. If it wasn't a pressure type of turbine, a wate-gate would not be used.vorticism wrote: ↑17 Jan 2026, 19:46The MGUH-era turbo was both as evidenced by the existence of both tuned headers and wastegates on those engines. You made a blanket statement about "the turbocharging process" requiring backpressure, which is what Tommy countered.saviour stivala wrote: ↑17 Jan 2026, 18:23Re your persistence colossal mix-up of the Wright turbo compounding by the use of a ''BLOW-DOWN TURBINE'' with that of the Formula 1 turbocharger ''PRESSURE TURBINE''.
(From page 5 and 6)
A design feature that can be common to both manifold types is a " DIVIDED MANIFOLD" , typically employed with " DIVIDED " or "twin-scroll" turbine housings. Divided exhaust manifolds can be incorporated into either a cast or welded tubular manifolds. The concept is to DIVIDE or separate the cylinders whose cycles interfere with one another to best utilize the engine’s exhaust pulse energy.
For example, on a four-cylinder engine with firing order 1-3-4-2, cylinder #1 is ending its expansion stroke and opening its exhaust valve while cylinder #2 still has its exhaust valve open (cylinder #2 is in its overlap period). In an undivided exhaust manifold, this pressure pulse from cylinder #1’s exhaust blowdown event is much more likely to contaminate cylinder #2 with high pressure exhaust gas. Not only does this hurt cylinder #2’s ability to breathe properly, but this pulse energy would have been better utilized in the turbine. The proper grouping for this engine is to keep complementary cylinders grouped together-- #1 and #4 are complementary; as are cylinders #2 and #3.
Because of the better utilization of the exhaust pulse energy, the turbine’s performance is improved and boost increases more quickly.
Yes. Agree that the 'twin-scroll' exhaust turbine housing design minimizes the effect of mixing all exhaust pulses into one collector, by dividing said pulses into two collectors. As the formula 1 ICE is a V-6 cylinder, using a twin-scroll exhaust turbine housing means that two sets of three selected cylinders will each blow their respective exhaust gas through a primary, with all three primary in the set pumping into a collector, with each of the two collectors pumping into the nozzle aimed at the turbine. The system of multi primaries (more than one) pumping into a collector with the collector pumping into the turbine nozzle aimed at the turbine, will still render the exhaust turbine a 'pressure turbine'. The fact that a variable opening waste-gate is used, provides the exhaust gases from cylinders to turbine with two paths, when the waste-gate is opened exhaust gas pressure is at atmospheric pressure, and no turbine recovery is possible, When it is closed, exhaust gas is above atmospheric pressure and turbine recovery is possible.gruntguru wrote: ↑19 Jan 2026, 04:54The turbine used in F1 utilises both pressure and blowdown pulses. Have you heard of a company call GARRETT? They know a thing or two about turbochargers. Here is an article posted on their website. https://www.garrettmotion.com/wp-conten ... vanced.pdfsaviour stivala wrote: ↑17 Jan 2026, 20:33The MGU-H- ERA turbocharger turbine used in formula 1 is a pressure turbine type and not a blow-down type of turbine, no matter what you and T C says. If it wasn't a pressure type of turbine, a wate-gate would not be used.
(From page 5 and 6)
A design feature that can be common to both manifold types is a " DIVIDED MANIFOLD" , typically employed with " DIVIDED " or "twin-scroll" turbine housings. Divided exhaust manifolds can be incorporated into either a cast or welded tubular manifolds. The concept is to DIVIDE or separate the cylinders whose cycles interfere with one another to best utilize the engine’s exhaust pulse energy.
For example, on a four-cylinder engine with firing order 1-3-4-2, cylinder #1 is ending its expansion stroke and opening its exhaust valve while cylinder #2 still has its exhaust valve open (cylinder #2 is in its overlap period). In an undivided exhaust manifold, this pressure pulse from cylinder #1’s exhaust blowdown event is much more likely to contaminate cylinder #2 with high pressure exhaust gas. Not only does this hurt cylinder #2’s ability to breathe properly, but this pulse energy would have been better utilized in the turbine. The proper grouping for this engine is to keep complementary cylinders grouped together-- #1 and #4 are complementary; as are cylinders #2 and #3.
Because of the better utilization of the exhaust pulse energy, the turbine’s performance is improved and boost increases more quickly.
It uses some form of pulse effect because they would all stay with log manifolds if it were only a pressure turbine.saviour stivala wrote: ↑19 Jan 2026, 06:30Yes. Agree that the 'twin-scroll' exhaust turbine housing design minimizes the effect of mixing all exhaust pulses into one collector, by dividing said pulses into two collectors. As the formula 1 ICE is a V-6 cylinder, using a twin-scroll exhaust turbine housing means that two sets of three selected cylinders will each blow their respective exhaust gas through a primary, with all three primary in the set pumping into a collector, with each of the two collectors pumping into the nozzle aimed at the turbine. The system of multi primaries (more than one) pumping into a collector with the collector pumping into the turbine nozzle aimed at the turbine, will still render the exhaust turbine a 'pressure turbine'. The fact that a variable opening waste-gate is used, provides the exhaust gases from cylinders to turbine with two paths, when the waste-gate is opened exhaust gas pressure is at atmospheric pressure, and no turbine recovery is possible, When it is closed, exhaust gas is above atmospheric pressure and turbine recovery is possible.gruntguru wrote: ↑19 Jan 2026, 04:54The turbine used in F1 utilises both pressure and blowdown pulses. Have you heard of a company call GARRETT? They know a thing or two about turbochargers. Here is an article posted on their website. https://www.garrettmotion.com/wp-conten ... vanced.pdfsaviour stivala wrote: ↑17 Jan 2026, 20:33
The MGU-H- ERA turbocharger turbine used in formula 1 is a pressure turbine type and not a blow-down type of turbine, no matter what you and T C says. If it wasn't a pressure type of turbine, a wate-gate would not be used.
(From page 5 and 6)
A design feature that can be common to both manifold types is a " DIVIDED MANIFOLD" , typically employed with " DIVIDED " or "twin-scroll" turbine housings. Divided exhaust manifolds can be incorporated into either a cast or welded tubular manifolds. The concept is to DIVIDE or separate the cylinders whose cycles interfere with one another to best utilize the engine’s exhaust pulse energy.
For example, on a four-cylinder engine with firing order 1-3-4-2, cylinder #1 is ending its expansion stroke and opening its exhaust valve while cylinder #2 still has its exhaust valve open (cylinder #2 is in its overlap period). In an undivided exhaust manifold, this pressure pulse from cylinder #1’s exhaust blowdown event is much more likely to contaminate cylinder #2 with high pressure exhaust gas. Not only does this hurt cylinder #2’s ability to breathe properly, but this pulse energy would have been better utilized in the turbine. The proper grouping for this engine is to keep complementary cylinders grouped together-- #1 and #4 are complementary; as are cylinders #2 and #3.
Because of the better utilization of the exhaust pulse energy, the turbine’s performance is improved and boost increases more quickly.
I'm not the person you're replying to, but there's a 3000MJ/h limit to the fuel energy flow in the regulations. Now MJ/h (unit of mechanical work per unit of time) is obviously a unit of power, so 3000 MJ/h = 833 kW.