does carb ice enrich the mixture?
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does carb ice enrich the mixture?
interesting view point from a colleague the other day that carb icing enrichens the fuel air ratio, i always thought that it would just reduce the amount of air that could enter the carb. and therefore the ratio would stay the same, any thoughts on this? PA28 in particular.
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The air just takes a different route to the carburettor. Yes there is a slight restriction, but not much. Enrichment of the mixture occurs because hot air ls less dense than cold air. How much by I'm not sure. But the biggest effect is a performance reduction due to the reduced density of the charge.
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If ice reduces the air flow wouldn't that also reduce the amount of fuel sucked in by the air? Therefore keeping the mixture ratio about the same?
Followed by what gets completely blocked first, the fuel jet or the air stream?
Lean cut or rich cut?
Interesting think.
Followed by what gets completely blocked first, the fuel jet or the air stream?
Lean cut or rich cut?
Interesting think.
Got carb icing in my car once (climbing Beattock southbound from Glasgow;OAT at the airport was +2 and it's about 1,000ft amsl and it was in cloud so very damp); the plugs were sooty and the exhaust was black smoke.
In a pressure-driven carb the increased velocity increases the pressure drop (manifold depression/vacuum) which the carb "sees" as addtional flow due to an increased throttle setting, so (again) it supplies more fuel and enriches the mixture. If the ice ever did get to block the main jets then you might see a weakening of the mixture, but by that stage the engine would proably be barely running (that's a guess on my part)
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Under normal conditions. The butterfly controls the airflow, the airflow controls the fuel flow. If the butterfly is closed/throttle down, the mixture ratio remains the same, otherwise we would be running rich at low throttle and lean at full power.
Therefore if the ice builds up, as I believe it does, around the butterfly effectively closing the throttle then the same should apply, mixture stays the same, by ratio. The Venturi cross section is reduced the amount of air passing through is reduced. Although the pressure difference from atmospheric may be greater there is less volume of vacuum to fill with fuel.
Take a balloon a foot diameter at two atmospheres in a room, stick a pin in it, it goes pop. take another balloon at twenty feet dia also two atmospheres in the same room it would take out the windows, prob plus a bit! The pressure was the same.
Just my theory.
Therefore if the ice builds up, as I believe it does, around the butterfly effectively closing the throttle then the same should apply, mixture stays the same, by ratio. The Venturi cross section is reduced the amount of air passing through is reduced. Although the pressure difference from atmospheric may be greater there is less volume of vacuum to fill with fuel.
Take a balloon a foot diameter at two atmospheres in a room, stick a pin in it, it goes pop. take another balloon at twenty feet dia also two atmospheres in the same room it would take out the windows, prob plus a bit! The pressure was the same.
Just my theory.
Under normal conditions. The butterfly controls the airflow, the airflow controls the fuel flow. If the butterfly is closed/throttle down, the mixture ratio remains the same, otherwise we would be running rich at low throttle and lean at full power.
Therefore if the ice builds up, as I believe it does, around the butterfly effectively closing the throttle then the same should apply, mixture stays the same, by ratio.
Therefore if the ice builds up, as I believe it does, around the butterfly effectively closing the throttle then the same should apply, mixture stays the same, by ratio.
The increased flow velocity causes a greater pressure/temperature drop in the venturi, which reduces the temperature further and increases the rate of ice formation, which in turn reduces the choke area and increases the flow rate, dropping the temperature further and so on causing a runaway condition. That's why once the ice starts to form it can build to dangerous levels very quickly.
PDR
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This is accurate. I didn't know the answer to the rich/lean question, but looked it up- the answers I found confirmed everything PDR1 says.
Slight thread drift but for the last three years, I've been flying a 182 with a carburetor temperature gauge. A fantastic instrument. I don't know why more light aircraft don't have them. Just use Carb Heat to keep the needle out of the yellow arc.
The next time you do a runup apply carb heat and then slowly lean the mixture. You should see in a fixed pitch prop aircraft, an initial rise in RPM as the overly rich mixture created by the carb heat is leaned to best power. If you keep leaning you will eventually see s drop in RPM as you lose power from an overly lean mixture.
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I've been building and tuning up my own 4 stroke engines for many years and have often experimented with carburettor swaps on them. If you fit a carburettor with a smaller Venturi to any engine (which is sometimes done to improve low speed drive ability and response, but will possibly restrict top end power) you need a smaller main jet, otherwise the mixture will be too rich. This is because for the same airflow, the pressure drop across the main jet is greater with a smaller Venturi. Obviously, the basic principle of a carburettor is that the pressure drop across the main jet is what draws out the fuel.
If ice forms in the Venturi of a carb such that it reduces its diameter, the situation is the same as the above.
If ice forms in the Venturi of a carb such that it reduces its diameter, the situation is the same as the above.
I've been building and tuning up my own 4 stroke engines for many years and have often experimented with carburettor swaps on them. If you fit a carburettor with a smaller Venturi to any engine (which is sometimes done to improve low speed drive ability and response, but will possibly restrict top end power) you need a smaller main jet, otherwise the mixture will be too rich. This is because for the same airflow, the pressure drop across the main jet is greater with a smaller Venturi. Obviously, the basic principle of a carburettor is that the pressure drop across the main jet is what draws out the fuel.
If ice forms in the Venturi of a carb such that it reduces its diameter, the situation is the same as the above.
If ice forms in the Venturi of a carb such that it reduces its diameter, the situation is the same as the above.
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My apologies.
So it seems from Shytorque that the mixture will become rich under icing conditions.
Seems to make sense as the extra fuel would cool the area further making the situation worse?
BPF.
Leaning the mixture by reducing the fuel and applying heat isn't the issue here.
This is reducing the airflow.
So it seems from Shytorque that the mixture will become rich under icing conditions.
Seems to make sense as the extra fuel would cool the area further making the situation worse?
BPF.
Leaning the mixture by reducing the fuel and applying heat isn't the issue here.
This is reducing the airflow.
Once the fuel is released into the intake air it atimises into afine spray, and then it is supposed to vapourise. If it DOES vapourise it will cool the surrounding air (google "latent heat of vapourisation"), but there is always significant doubt as to whether it does at anything more than low power settings simpoly because it doesn't have time in the brief dash betwixt jet and cylinder.
Vapourisation promotes good fuel consumption and in some cases "cleaner" combustion and emissions, and it can also have an untercooling effect which improves charge density. But in most carburetted setups full vapourisation actually limits the maximum power available because the vapourised petrol occupies far more space in the inlet manifold and cylinder than fine droplets would do.
The power of any piston engine is ultimately limited by the amount of air you can make it breathe, and if you can make the fuel stay in nice concentrated droplets you can actually get more mixture into the cylinders than you could if the volume was cluttered-up with vapourise petrol. Once in the cylinder the droplets (again) have an intercooling effect which can allow you to run a slightly higher compression ratio if you are so inclined.
This has been known for decades, and it's the main reason why the really high performance setups still favoured carburettors over indirect fuel-injection well into the late 80s. F1 cars only really committed to fuel injection when the formula started introducing reductions in permitted fuel capacity.
But I digress...
PDR
The Chevvron microlight is fitted with a carb inlet temp guage and it is excellent.