Honda F1 project leader Yusuke Hasegawa has outlined a number of reasons why Honda has been struggling so badly in the beginning of the 2017 Formula One season. He confirmed that lots of problems were not discovered while running on the dynamo meter.
Going buy power output maybe the wheel is about 80 mm inducer and 70 mm exducer... Less blades mean less surface area and less obstruction for more flow (more top end) however efficiency drops. They would use trial and error i guess.godlameroso wrote: ↑01 Nov 2017, 03:59Both turbine and compressor can be kept relatively compact with the right wheels. The number and shape of blades along with inducer and exducer combinations along with their taper.Mudflap wrote: ↑31 Oct 2017, 22:12Well I suppose they used about 1 turbo per race anyway so why notPlatinumZealot wrote: ↑31 Oct 2017, 18:49
Yes. I was prepared for that question. I suppose the 35 place and 20 place grid drops could be construed to be a compressor wheel change!
Increasing wheel trim increases mass as well as the CG overhang (distance to first bearing). Secondly, the allowable unbalance for a given balance quality grade is proportional to rotor mass, so unbalance will increase too.
All these give you a lower frequency forward whirl mode, higher unbalance and a fair amount of extra inertia to accelerate.
And I'm not too sure how compressor efficiency varies with wheel trim, maybe GG can elucidate .
Single stage turbines have been done to death, I wouldn't be surprised if the answer is in some old dusty book TC has stashed somewhere I reckon.
I wonder how many blades they have on their turbine wheel, I suppose that information is on a need to know. Less blades means more surface area for the blades to affect airflow, however there has to be a compromise to get the best surface area vs best pressure ratio vs best response vs best harmonics and a host of other technical niggles you're probably more familiar with. My guess is 6-7 blades, maybe a 74-88 trim something wild like that.
I was thinking 74 to 88mm, less blades doesn't always mean more flow as you can make larger blades, the area of the space between the blades can be the same with 3 4 5 6 7 8 or 9 blades. If we think of each blade as an aerofoil you can easily see the effect of larger blades, in the same way you see the effect of a larger wing. Do you want a bunch of small wings or a few larger ones, you have to find the right compromise.PlatinumZealot wrote: ↑02 Nov 2017, 04:14Going buy power output maybe the wheel is about 80 mm inducer and 70 mm exducer... Less blades mean less surface area and less obstruction for more flow (more top end) however efficiency drops. They would use trial and error i guess.godlameroso wrote: ↑01 Nov 2017, 03:59Both turbine and compressor can be kept relatively compact with the right wheels. The number and shape of blades along with inducer and exducer combinations along with their taper.Mudflap wrote: ↑31 Oct 2017, 22:12
Well I suppose they used about 1 turbo per race anyway so why not
Increasing wheel trim increases mass as well as the CG overhang (distance to first bearing). Secondly, the allowable unbalance for a given balance quality grade is proportional to rotor mass, so unbalance will increase too.
All these give you a lower frequency forward whirl mode, higher unbalance and a fair amount of extra inertia to accelerate.
And I'm not too sure how compressor efficiency varies with wheel trim, maybe GG can elucidate .
Single stage turbines have been done to death, I wouldn't be surprised if the answer is in some old dusty book TC has stashed somewhere I reckon.
I wonder how many blades they have on their turbine wheel, I suppose that information is on a need to know. Less blades means more surface area for the blades to affect airflow, however there has to be a compromise to get the best surface area vs best pressure ratio vs best response vs best harmonics and a host of other technical niggles you're probably more familiar with. My guess is 6-7 blades, maybe a 74-88 trim something wild like that.
The compressor wheel might have a loop hole. Honda could have made an air box with an adjustable " bullet" shape protruding into the turbine to tune the air flow charecteristics between races. The intake pipe to the turbine is free to change right?
Water vapor would need to be reclaimed pre-turbine. Unless you had some intentionally leaky gaskets.ringo wrote: ↑03 Nov 2017, 02:34Since we have oil burning, we might as well have water injection too.. or if its illegal, chilled oil injection.
https://www.youtube.com/watch?v=bwSgNxmKudc
5.8.1 With the exception of incidental leakage through joints (either into or out of the system), all
(and only) the fluids entering the compressor inlet and the fuel injectors must exit from the
engine exhaust system.
7.3 Catch tank :
In order to avoid the possibility of oil being deposited on the track, the engine sump breather
must vent into the main engine air intake system.
That is the thing though, turbine blades don't work like aeroplane wing profiles. That is a weird sort of thinking.godlameroso wrote: ↑02 Nov 2017, 05:23I was thinking 74 to 88mm, less blades doesn't always mean more flow as you can make larger blades, the area of the space between the blades can be the same with 3 4 5 6 7 8 or 9 blades. If we think of each blade as an aerofoil you can easily see the effect of larger blades, in the same way you see the effect of a larger wing. Do you want a bunch of small wings or a few larger ones, you have to find the right compromise.PlatinumZealot wrote: ↑02 Nov 2017, 04:14Going buy power output maybe the wheel is about 80 mm inducer and 70 mm exducer... Less blades mean less surface area and less obstruction for more flow (more top end) however efficiency drops. They would use trial and error i guess.godlameroso wrote: ↑01 Nov 2017, 03:59
Both turbine and compressor can be kept relatively compact with the right wheels. The number and shape of blades along with inducer and exducer combinations along with their taper.
Single stage turbines have been done to death, I wouldn't be surprised if the answer is in some old dusty book TC has stashed somewhere I reckon.
I wonder how many blades they have on their turbine wheel, I suppose that information is on a need to know. Less blades means more surface area for the blades to affect airflow, however there has to be a compromise to get the best surface area vs best pressure ratio vs best response vs best harmonics and a host of other technical niggles you're probably more familiar with. My guess is 6-7 blades, maybe a 74-88 trim something wild like that.
The compressor wheel might have a loop hole. Honda could have made an air box with an adjustable " bullet" shape protruding into the turbine to tune the air flow charecteristics between races. The intake pipe to the turbine is free to change right?
Hmm sort of echoes what has been said in the engine threads. Was expecting something more sneaky.Wazari wrote: ↑02 Nov 2017, 07:37There has been some interest about "oil burning" in this current PU. Here is a simplistic but IMO a pretty well summary of what is happening and why the limit on oil consumption being permitted:
http://www.roadandtrack.com/motorsports ... ore-power/
But they do. Especially when you begin to optimize the airflow and you use high flow turbines.PlatinumZealot wrote: ↑03 Nov 2017, 05:47That is the thing though, turbine blades don't work like aeroplane wing profiles. That is a weird sort of thinking.godlameroso wrote: ↑02 Nov 2017, 05:23I was thinking 74 to 88mm, less blades doesn't always mean more flow as you can make larger blades, the area of the space between the blades can be the same with 3 4 5 6 7 8 or 9 blades. If we think of each blade as an aerofoil you can easily see the effect of larger blades, in the same way you see the effect of a larger wing. Do you want a bunch of small wings or a few larger ones, you have to find the right compromise.PlatinumZealot wrote: ↑02 Nov 2017, 04:14
Going buy power output maybe the wheel is about 80 mm inducer and 70 mm exducer... Less blades mean less surface area and less obstruction for more flow (more top end) however efficiency drops. They would use trial and error i guess.
The compressor wheel might have a loop hole. Honda could have made an air box with an adjustable " bullet" shape protruding into the turbine to tune the air flow charecteristics between races. The intake pipe to the turbine is free to change right?
It's a bit conspiracy but Fia doesn't do what they do with good intention. If oil burning keeps competition alive don't ban it in season. If oil burning ban would bring competition then do it.bigblue wrote: ↑03 Nov 2017, 09:54There are a few reports in Japanese media that Honda had a qualifying mode available, but it was outlawed by tighter FIA rules. I guess it was based around oil burning, as what else is available, and recently tightened-up in the regulations ?
I forget where I first saw this mentioned (might be here, might be on autosport's forums), but a post over at autosport brought it up again. The links provided are to a Japanese web-site, where only a paragraph of a subscription article is visible, and of course they are written in Japanese, so machine translation has been used by the poster.
The links are http://members.f1-life.net/race/59657/ and http://members.f1-life.net/race/59662/. Obviously it's hard to judge how reputable the site is for me, and it's hard to know much without access to the full article, but I thought it was interesting anyway.
If true, it's bad timing for Honda as just as they implement this, it's outlawed (seems the regulations changed just before the Italian GP). Then again, the very smoky Mercedes probably has it developed to the last degree, so maybe not so bad (edit : forgot about Mercedes changing engines just before the regulation update, e.g. see this article on crash.net). Hopefully Honda's developed some expertise in this area which is still applicable within the tightened regulations.
