Here is something I don't know about the gasoline business and maybe someone could enlighten me. In my city, gasoline comes out of a pipeline (pretty sure that's it coming out of the ground in the linked Street View) and goes into giant tanks labeled "Regular Gasoline".
How is product differentiation done here? I assume it goes into the tanker trucks unmodified and they unload at the gas stations. Where do the high octane, etc. additives actually get added? At the pump?
Also this is a multi-mode pipeline which sometimes carries gas, diesel etc. Presumably when changing modes the stuff goes into the tank labeled "Purge Tank" during the transition. What is done with the contents of this tank?
"Regular" gasoline (87 octane much of the US, lower in the western states) was (is?) a commodity. What one bought at the pump was whatever 87 octane was available at the depot, regardless of the brand of the station.
High-octane (93 in much of the US, lower in the western states) is brand-specific. Pipeline loads are measured using clocks and flow-rates. E.g.: from 12:00 to 12:05, it's Brand X Ultimate. The pipeline flow-rate is used to determine what's in the line at the various depots.
The head and tail of the load are mixed, but if the high-octane is in the middle of a regular gas run, it's likely not a big deal. I don't know if it winds up in the purge tank or just a part of the other runs.
The intermediate grades were (are?) mixed at the station between high-octane and regular.
The article claims that, when a station offers Top Tier gasoline, it must do so for all "levels" of gas they provide, so your "regular is the same and the others are differentiated" interpretation doesn't match up.
My answer was to the commenter's questions, which, to me (perhaps incorrectly), did not involve the article's discussion of "Top Tier" gas.
As you point out in the article, a Top Tier gas licensee must meet the standards for all levels of gas they provide.
What the article doesn't make clear (to me), is that Top Tier is a set of standards that is licensed to almost every brand in the US (toptiergas.com). Being "Top Tier" doesn't mean the regular is Station Brand specific, just that it meets the Top Tier standards.
Given the large list of brands, it would not surprise me if most (or all) regular gas produced in the US meets these standards and is what you get at the depot as a commodity.
But I do not know that and my other info may be out of date. Hopefully there's a active pipeline worker / gas hauler reading :)
I assumed the "Top Tier" ingredients could be lumped together with other stuff, like ethanol (the street view scene linked in my original question shows a tank labeled thus), octane-boosting additives, detergents and so on. All based on the totally generic "regular gasoline" - two of the giant tanks are labeled that but there are a few tanks further back whose label is not visible.
The pipeline map shows the pipeline terminating pretty much exactly where you can see it coming out of the ground. There are other fuel depots nearby. One assumes secondary pipes to deliver material to them, but I don't know this business at all, so the more people who know do pipe in, the better.
Ah, one of the other fuel depots has some tank labels visible as well, and it does have separate tanks for "regular" and "premium" gas.
I assume the purge tank will be either reprocessed through the refinery again, or it'll be used for uses where the exact composition doesn't matter - for example many industrial processes can use almost any hydrocarbons for heating stuff, and therefore they use whatevers cheapest, which is probably the purge tank contents.
All modern engines are fuel injected, so the intake valve only ever sees filtered air.
So, no matter what type of fuel you use, the intake valve should never get carbon deposits.
Therefore I doubt these results... I suspect they are either doctored, or they use a very old carburettor engine which is probably deliberately mis-adjusted to make lots of carbon for the photo.
After all, that much carbon in just 100 hours of running would lead to a total blockage in just 300 hours. And my valves don't get blocked every 300 hours if running!
> All modern engines are fuel injected, so the intake valve only ever sees filtered air.
How modern are we talking?
There are plenty of fuel injected engines in production/use today that inject fuel into the manifold [1], right before the valve.
Those valves definitely make contact with fuel-laden air, not to mention EGR[2] recycling exhaust gasses into the intake manifold for emissions/efficiency improvements.
What you're talking about is direct injection, which is becoming more and more common, but is not "the norm" if you take the cross section of total vehicles on the road today
It is probably a typo and they should have wrote exhaust valve. It's thick enough to be an exhaust valve.
The cylinder head has both an intake valve and exhaust valve on each cylinder. One to let in misted fuel and air (delivered via the intake manifold, which is via fuel injection rail or carburetor jets), and another to allow the dispelling of combusted fuel.
That said I've seen carbon build up on intake valves too. Usually from bad valve adjustments or improper seating...bad lifters/rockers etc etc so they port isn't properly sealed in combustion. Nothing to do with being fuel injected or carbureted. It all comes via the intake manifold... The valves know absolutely no difference.
A blast of walnut shells through the engine will clear those deposits right up. You can also use seafoam as a preventative measure to burn off any excess deposits.
If you want a performance boost, you can get a methanol-water injection added to your engine which should boost hp output while burning off those deposits. Just be careful with meth, if the mixture is not present engine temps will skyrocket leading to knocking and detonation very shortly afterwards. A properly integrated fuel-cutoff system will prevent this but you must ensure your meth controller has this functionality otherwise you are taking a great risk IMHO
With the exception of some, but not all, newer GDI (Gasoline Direct Injection) engines, fuel injected engines have fuel injectors in the intake manifold upstream of the intake valves. Some GDI also have a combination of traditional injectors and direct injectors. It is inaccurate to say "the intake valve only ever sees filtered air."
> All modern engines are fuel injected, so the intake valve only ever sees filtered air.
Not even close.
There's two sources I can think of off the top of my head for contamination of the intake valves. Others have mentioned the exhaust gate recirculuation, but there's also crank case air that can be recirculated.
A cold engine's piston rings don't fully seal properly against the cylinder walls. They can't or else the piston could drag and scrape the wall when thermal expansion occurs. So when you start a cold engine, a great deal of pressure slips past the rings into the crank case where the engine oil is. Depending on what phase the escape occurs, it can carry gasoline, combustion gasses, etc into the crank case.
In the bad old days when emission regulations weren't a thing, the normal practice was just to let this blow by vent from the engine crank case into the atmosphere. The EPA at some point considered this not so good, and mandated that this needed to stop. The solution that was implemented was to recirculate the air from the crank case into the intake manifold. Unfortunately this means that any particulate is also recirculated as well (evaporated oil is the nasty one) and can gum up the intake valves.
Now what you're thinking about is gasoline direct injection engines, and top tier gasoline isn't going to clean the intake valves because the gasoline is injected direct into the combustion chamber. But there's still port injected engines which are still fairly common, which wash the gasoline over the intake valve and in turn wash the contaminants from blow off the valves and into the combustion chamber. Hence why Top Tier gasoline is beneficial to engines that use valve injection.
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Just a fun aside for anyone that runs a gas car; if you've ever wondered why oil change intervals are either have both a time based and a mileage based interval; it's because of that cold engine start blow by. Oil doesn't degrade sitting in an engine case, but it's performance does degrade when gasoline from a cold engine being started slips past the piston rings and mixed with the oil.
When you're running long miles, it doesn't matter as much. The engine is able to get up to full temperature, which both properly seals the piston rings, but also warms up the oil, which causes the gasoline that has gotten into the oil to evaporate and be circulated back out.
But that doesn't happen if the engine isn't run long enough to get up to temperature; if you're making short little 5 minute trip commutes every day, then the oil just keep getting contaminated more and more with gasoline. Left unchecked, the oil ceases to be able to properly lubricate the engine from the contamination, and heavy wear and tear starts occurring in the engine itself.
A proper oil change interval would take into account all the factors that effect oil life; the engine's temperature when it was started, how long the engine was run, how hard the engine is run at, etc to calculate how badly the oil has been contaminated by cold starts. For people that have an oil life monitoring system; that's exactly what it does. But what about everyone else? Do you expect people to note down the ambient temperature, and the engine temperature every time they start up the car, plug it into an excel sheet and see how much oil life is left?
Hence the need for a simple formula that could accommodate most use cases; the 3500 mile or 6 month interval. 3500 miles for people that were running their cars hard such as towing boats, RV's, etc, which wore the oil out faster then normal commuters, and 6 months for people that were just making a 5 minute commute by car every day while in the middle of winter.
FYI most modern cars account for this now. My ford of 10 years will notify when an oil change is due and it varies between 3000 and 8000 miles in my experience
> Keeping things simple for consumers, when a participating retailer sells Top Tier fuel, all octane grades from regular to premium gasoline and diesel must adhere to the Top Tier standards. So it is not necessary for drivers to upgrade to premium to gain the cleansing benefits.
I think what they are saying is that gas stations of these brands sell the Top Tier brands gasoline among their selection. It's not clear if it is every station. And I have never even seen it much less purchased it.
https://goo.gl/maps/dZSTF4ziis16iMy36
How is product differentiation done here? I assume it goes into the tanker trucks unmodified and they unload at the gas stations. Where do the high octane, etc. additives actually get added? At the pump?
Also this is a multi-mode pipeline which sometimes carries gas, diesel etc. Presumably when changing modes the stuff goes into the tank labeled "Purge Tank" during the transition. What is done with the contents of this tank?