The more classic port fuel injection systems use the vacuum referenced fuel pressure regulator to keep the fuel pressure drop across the injector always constant as was mentioned. As intake vacuum drops the pressure goes up and as intake vaccum increases the fuel pressure decreases. It is plenty fast to compensate for transient conditions, trust me. Put a gauge on it and watch it. The return style systems allow the injector to deliver the same exact amount of fuel for a given pulse width (injector opening/closing event) regardless of manifold vacuum since the fuel pressure was tracking it accordingly. Rather than distrusting the return style systems you really liked them without knowing it.
The switch to return-less systems is driven mainly by cost (less fittings, pipes, lines, holes in the fuel tank, hardware in general) and the ever tightening evaporative emissions standards. The return style systems are always circulating fuel thru the (hot) fuel rail thus increasing the heat input into the fuel in the tank. The hotter the fuel in the tank, the more vapor is created to be dealt with by the evaporative emissions system (the charcoal canister). Elminate the return fuel and the system elminates a lot of vapor generation. There was never an issue that I have heard about with system pressure drift or anything like that with return style systems. In addition, with the returnless systems there less line connections to (potentially) leak and a simpler system to build in the assembly plant with less lines to route and connect. Anytime you can elminate parts the reliability goes up as there are less parts to fail.
As mentioned in the other post
https://www.fjrforum.com/forum//index.php?s...c=20185&hl= the return-less fuel rails do have to contend with the water hammer effect in addition to the ever-changing pressure drop across the injector changing the reference injector pulse...which is a constant in a return sytsem but now varies for each load and speed point with the return-less systems. This means that for a given injector pulse width the injector would deliver more fuel at high vaccum conditions (closed throttle) and less fuel when manifold vaccum is zero (full throttle conditions.)
The ECM is programmed with an injector pulse offset or compensation for each speed load point in the basic fuel map to account for the changing pressure drop across the injector. So, the ECM will "delete" some fuel from the calculated pulse width at high vaccum conditions and "add" some fuel to the calculated pulse width at low vaccum conditions so as to compensate for the lower amount of fuel delivery.
Aside from the advantages of the return-less system mentioned one of the key enablers of the return-less systems were ECM's with porcessors fast enough to do the extra compensation calculation for each cylinder at each speed and load point. Older ECM's of yesteryear were simply not fast enough and did not have enough computing capacity to calculate and deliver the injector correction for each cylinder event. Modern day ECM's have dramitically more computing power and much faster speed (just like in the desktop computer market) allowing cylinder by cylinder compensation and correct in real time....for each cylinder...for each event.
It was not as simple as just deleting the fuel pressure regulator and calling it good.
The other nice thing about return style systems was that the fuel injectors have effectively more "range". Since the injector "on time", or pulse width, has to be artificially increased when the vacuum in the intake is zero (full throttle or WOT) to compensate for the lack of fuel pressure increase the injector just lost some dynamic range. As a result, it is common to see larger injectors fitted into systems that are converted to return-less.
Two simple reasons for the fuel pressure increase on the returnless systems. On is to offset the loss of dynamic range just mentioned. If the pressure is increased in the fuel rail the injector will now have to open less to flow the same amount thus offsetting the loss of flow at the low vaccum conditions. In effect, the pressure goes full time to what it was at when the fuel return type system was compensating for low vaccum conditions. The other reason the fuel pressure is increased is to fend off vapor lock. Since the fuel is dead headed in the rail and not constantly replaced by cooler fuel circulating thru the rail the fuel has a tendency to pick up more heat and "boil" or flash into vapor. Especially in a hot soak condition. As long as the rail maintains fuel pressure during shutdown the higher pressure will prevent boiling and vapor lock. Along this train of thought, keep the water hammer effect in mind. As the negative pulses travel up and down the rail it is desireable to always keep the fuel pressurized to a point that vapor cannot form. If the fuel pressure too low then the even lower value seen during a low pressure spike could allow vapor fo form. Keeping the pressure higher offsets the low pressure spikes sufficiently that the fuel cannot spike low enough in pressure to allow vapor to form.
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