You don't think they have done that as much as possible on modern turbines?
Even a small turbine fitted to a radio controlled airplane can take many seconds to spool up.
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While the technical regulations regarding the power units are going into their 4th stable year, Mercedes' engine Chief, Andy Cowell, has noted there are still gains to be made. Cowell underlined that the key to these continued improvements are Mercedes' proven testing facility.
You don't think they have done that as much as possible on modern turbines?
You still need the mass flow. And yes, response times can be quick depending on what your energy source is. In a combustion turbine you are instantly adding more fuel to be combusted.PlatinumZealot wrote: ↑08 Dec 2017, 02:56Exactlty. You are building pressure in an open system everytime you need more torque. Go to the back of the turbine and you look right through the blades. Think about that. You esentailly have a chamber with some blades on either side and you have to build pressure inside it. The turbine is free flowing so the air has to basically compress against itself. Combustion occurs at one pressure as well. That response aint happening until that back pressure builds up with flow rate and heat spread! That takes seconds due to size of chamber speed of sound and what not. For a piston engine this is not a problem because the combustion chamber is very small, igntion is rapid and chamber is esentially a closed system. I am rusty when it comes to turbines.. But i know the response time aint pretty.
Has there been a need to? Primary applications remain aircraft and power plants. Automotive applications have been limited to concept cars, range extenders, one-off customs, drag racing, tractor pull and an Indy car. None of those required quick 'throttle response.' RC model aircraft engine manufacturing would not be a hotbed of research on the topic; regardless, that the engine is small does not alter the relationship between the mass flow it can produce and apply to its turbine. So it should not be expected to necessarily spool up faster.MrPotatoHead wrote: ↑08 Dec 2017, 01:56You don't think they have done that as much as possible on modern turbines?
Even a small turbine fitted to a radio controlled airplane can take many seconds to spool up.
This is the important part. Automotive turbochargers can spool quickly due to a variety of different techniques, despite being able to "look right through the blades," PZ.dren wrote: ↑08 Dec 2017, 14:41You still need the mass flow. And yes, response times can be quick depending on what your energy source is.PlatinumZealot wrote: ↑08 Dec 2017, 02:56Exactlty. You are building pressure in an open system everytime you need more torque. Go to the back of the turbine and you look right through the blades. Think about that. You esentailly have a chamber with some blades on either side and you have to build pressure inside it. The turbine is free flowing so the air has to basically compress against itself. Combustion occurs at one pressure as well. That response aint happening until that back pressure builds up with flow rate and heat spread! That takes seconds due to size of chamber speed of sound and what not. For a piston engine this is not a problem because the combustion chamber is very small, igntion is rapid and chamber is esentially a closed system. I am rusty when it comes to turbines.. But i know the response time aint pretty.
Some options:In 2007, NASCAR owner/driver Michael Waltrip and his team had severe penalties handed down by officials. Team Vice-President Bobby Kennedy and Crew Chief David Hyder of Waltrip's No. 55 were ejected from the Daytona International Speedway. Hyder was fined $100,000 for his involvement with lining fuel tanks and intake valves with Sterno. NASCAR also docked Waltrip 100 owner points and disqualified his qualifying speed for the Daytona 500. Mid-week, NASCAR determined that the then unknown substance was Sterno. When the highly regulated NASCAR fuel was added, the Sterno would liquefy, giving the car an added octane boost.[4]
5.10.5 Any device, system or procedure the purpose and/or effect of which is to increase the flow
rate after the measurement point is prohibited.
Aahmm... An automotige turbocharger is not an engine! It has no combustion chamber. And it is a radial turbine which is definitively a quick response turbine with high pressure gradient per stage. That is the biggest reason why radial turbines are used on cars!
i am aware that street car engines made in the late 1990's early 2000's with partitioned crank cases such as the Toyota "AZ" engines do use a special passages joining the compartments to equalize air pressure under all the pistons as they reciprocate. These are inline engines.. v6 might not have such a big problem.. But still It reduces pumping losses and improves lubrication under the piston rings. It won't be a good idea to add significant back-pressure on this system though.roon wrote: ↑12 Dec 2017, 01:34Regarding qualifying modes and potential oil burning: I'm curious about crankcase pressure dynamics. Assuming a 90* V6 with a three-throw crank, we have three cylinder pairs--one pair per crank throw. If the crankcase were not a continuous volume but rather segregated by piston pair, there would be three separate crankcase volumes. Each of these would experience a rise and fall in pressure as the cylinder pairs rise and fall. Inlets, outlets, and passive valves could allow this volume to act as a pump.
Almost every engine on the road today has "windows" between the adjacent cylinder main webbing to help with cylinder to cylinder breathing.PlatinumZealot wrote: ↑14 Dec 2017, 06:22i am aware that street car engines made in the late 1990's early 2000's with partitioned crank cases such as the Toyota "AZ" engines do use a special passages joining the compartments to equalize air pressure under all the pistons as they reciprocate. These are inline engines.. v6 might not have such a big problem.. But still It reduces pumping losses and improves lubrication under the piston rings. It won't be a good idea to add significant back-pressure on this system though.roon wrote: ↑12 Dec 2017, 01:34Regarding qualifying modes and potential oil burning: I'm curious about crankcase pressure dynamics. Assuming a 90* V6 with a three-throw crank, we have three cylinder pairs--one pair per crank throw. If the crankcase were not a continuous volume but rather segregated by piston pair, there would be three separate crankcase volumes. Each of these would experience a rise and fall in pressure as the cylinder pairs rise and fall. Inlets, outlets, and passive valves could allow this volume to act as a pump.
You are really reaching here... The fuel flow regulations are quite clear:roon wrote: ↑14 Dec 2017, 00:17The composition of the lubricant is unknown. Would more-viscous, gelled gasoline or alcohol (Sterno) have sufficient lubricating qualities?
Some options:In 2007, NASCAR owner/driver Michael Waltrip and his team had severe penalties handed down by officials. Team Vice-President Bobby Kennedy and Crew Chief David Hyder of Waltrip's No. 55 were ejected from the Daytona International Speedway. Hyder was fined $100,000 for his involvement with lining fuel tanks and intake valves with Sterno. NASCAR also docked Waltrip 100 owner points and disqualified his qualifying speed for the Daytona 500. Mid-week, NASCAR determined that the then unknown substance was Sterno. When the highly regulated NASCAR fuel was added, the Sterno would liquefy, giving the car an added octane boost.[4]A line linking the fuel injectors to the valvetrain lubrication would be internal and hidden from view.
- The vapors emitted from the lubricant when heated or subjected to high shear or pressure, would render the sump breather gases flammable. Greater energy content in the air-fuel charge when injesting sump breather gases.
- The lubricant interacts with the air-fuel charge as a vapor introduced through sump gases or cylinder wall film.
- The lubricant is being mixed with the fuel directly in order to alter the properties of the fuel (octane, energy content, combustion properties). I don't see a regulation specifying that only fuel may exist within the fuel lines, or that only fuel may pass through the fuel injector.
If the lubricant is introduced pre-sensor, how would this influence the sensor's reading of the material passing through it? Only attempting to increase the fuel flow rate post-sensor is illegal. Altering the sensor's reading by varying the composition of the materials passing through it is not addressed in the rules.
5.10.5 Any device, system or procedure the purpose and/or effect of which is to increase the flow
rate after the measurement point is prohibited.
The question would be why even try? A shortage of pressurized air is not the problem in any fashion - fuel is what is limited.roon wrote: ↑12 Dec 2017, 01:34Regarding qualifying modes and potential oil burning: I'm curious about crankcase pressure dynamics. Assuming a 90* V6 with a three-throw crank, we have three cylinder pairs--one pair per crank throw. If the crankcase were not a continuous volume but rather segregated by piston pair, there would be three separate crankcase volumes. Each of these would experience a rise and fall in pressure as the cylinder pairs rise and fall. Inlets, outlets, and passive valves could allow this volume to act as a pump.
Yes.Today those little windows are pretty common, but back in the 1990's it was a special feature.MrPotatoHead wrote: ↑15 Dec 2017, 22:49Almost every engine on the road today has "windows" between the adjacent cylinder main webbing to help with cylinder to cylinder breathing.PlatinumZealot wrote: ↑14 Dec 2017, 06:22i am aware that street car engines made in the late 1990's early 2000's with partitioned crank cases such as the Toyota "AZ" engines do use a special passages joining the compartments to equalize air pressure under all the pistons as they reciprocate. These are inline engines.. v6 might not have such a big problem.. But still It reduces pumping losses and improves lubrication under the piston rings. It won't be a good idea to add significant back-pressure on this system though.roon wrote: ↑12 Dec 2017, 01:34Regarding qualifying modes and potential oil burning: I'm curious about crankcase pressure dynamics. Assuming a 90* V6 with a three-throw crank, we have three cylinder pairs--one pair per crank throw. If the crankcase were not a continuous volume but rather segregated by piston pair, there would be three separate crankcase volumes. Each of these would experience a rise and fall in pressure as the cylinder pairs rise and fall. Inlets, outlets, and passive valves could allow this volume to act as a pump.
On most race engines these windows are missing as a Dry Sump system is used and they are not needed.
99.9% of the time an engine will make more power with a negative pressure in the crankcase because of the increased ring sealing.
Pretty low risk environment here, so I don't mind reaching.
I'm more curious about how the sensor functions and if it is tuned toward a specific fluid composition. Alteration of the fuel beyond the testable, regulated components, via an additive downstream of the fuel tank, might influence how the sensor reads. Just speculating.MrPotatoHead wrote: ↑16 Dec 2017, 05:09The fuel flow regulations are quite clear:
5.1.4 Fuel mass flow must not exceed 100kg/h <--- It doesn't matter what fuel, that's it.
I don't think this precludes introducing substances into the fuel lines or the direct-injectors. Engine lubricant in this case.MrPotatoHead wrote: ↑16 Dec 2017, 05:095.14.2 Other than engine sump breather gases, exhaust gas recirculation, and fuel for the normal purpose of combustion in the engine, the spraying of any substance into the engine intake air is forbidden.
The wording is interesting. To me this implies the sump breather had an active valve emptying into the intake plenum(s). But this should be normal/expected. By regs, they have to route breather air through the engine. They want this to be a passive valve instead? Releasing gases only once a certain pressure level is reached.MrPotatoHead wrote: ↑16 Dec 2017, 05:09Once again the new rule added for 2018 tells you all that you need to know about "oil burning":
7.9 Oil injection: The use of active control valves between any part of the PU and the engine intake air is forbidden.
The rules are very explicit about introducing anything post sensor. This would be a big big no no. Again a reach.roon wrote: ↑16 Dec 2017, 21:27Pretty low risk environment here, so I don't mind reaching.
I'm more curious about how the sensor functions and if it is tuned toward a specific fluid composition. Alteration of the fuel beyond the testable, regulated components, via an additive downstream of the fuel tank, might influence how the sensor reads. Just speculating.MrPotatoHead wrote: ↑16 Dec 2017, 05:09The fuel flow regulations are quite clear:
5.1.4 Fuel mass flow must not exceed 100kg/h <--- It doesn't matter what fuel, that's it.
I don't think this precludes introducing substances into the fuel lines or the direct-injectors. Engine lubricant in this case.MrPotatoHead wrote: ↑16 Dec 2017, 05:095.14.2 Other than engine sump breather gases, exhaust gas recirculation, and fuel for the normal purpose of combustion in the engine, the spraying of any substance into the engine intake air is forbidden.
The wording is interesting. To me this implies the sump breather had an active valve emptying into the intake plenum(s). But this should be normal/expected. By regs, they have to route breather air through the engine. They want this to be a passive valve instead? Releasing gases only once a certain pressure level is reached.MrPotatoHead wrote: ↑16 Dec 2017, 05:09Once again the new rule added for 2018 tells you all that you need to know about "oil burning":
7.9 Oil injection: The use of active control valves between any part of the PU and the engine intake air is forbidden.
The wording is new for 2018 and it is because of the Mercedes engines breather system.roon wrote: ↑16 Dec 2017, 21:27
The wording is interesting. To me this implies the sump breather had an active valve emptying into the intake plenum(s). But this should be normal/expected. By regs, they have to route breather air through the engine. They want this to be a passive valve instead? Releasing gases only once a certain pressure level is reached.