It looks like it would be somewhere around 10-20 watts per ballast, depending on which ballast we are talking about. QUOTE]
That figure is way too high. And the actual input watts depends on the specific lamp-ballast combination. A 32 watt lamp could use more or less than 32 watts depending on the Ballast Factor for that lamp-ballast combination.
Practically all T8 lamps in use operate on electronic ballasts and overwhelming majority are 0.88 BF. It may surprise you, but this means most T8 ballasts in the field are designed to put out 88% output with electrical power delivered to the lamp in the ballpark of 25W per 4' 32W lamp. (There's a gain factor of 10-12% in lumens per watt when you drive fluorescent lamps at high frequency *see note 1). Just about every other commercial & industrial ballast for non T8 lamps operate at 95-100% of rated output. I'd just chalk it off as traditions.
Obscure magnetic ballasts to run 32W T8 lamps exist, but they're very uncommon. This is where sales people come up with the 72W per pair figure.
15 year old two lamp T8 ballasts has a line input of around 58-59W or ~85%.
Premium efficiency ballast available today offers you the same for 54-55W, which puts the output-to-input efficiency around 92%.
Probably the more significant savings is that 120-277v ballasts are auto regulating and do not let line voltage variations sway power consumption. 4 lamp version is a hair better knocking off another half a watt input per lamp.
Many ballasts can run 2 and 3 foot lamps, as well as run one lesser lamp than maximum but they're tuned for optimal efficiency running maximum quantity of 32W 4' lamps. so the efficiency suffers in other combination and many older single voltage ballasts are often incompatible with 25W 4' T8 or LED drop-ins.
This here is how its looking for the most current Philips LED linear lamp paired with their ICN-2P16-TLED-N dedicated LED ballast which offers performance very very close to operating on ICN-2P32-N ballast for fluorescent lamps which maintains backward compatibility with FL lamps. The boxed one is their premium DLC 4.0 version. There's Home Depot/builder's grade glass envelope LED lamp that puts out 2,100 day-one lumens per lamp but has significantly worse long term durability that is trumped by premium T8 lamps at lower cost per lamp. You'll see that LED lamps only compete against 25 and 28W saver lamps, which are only usable in temperatures not colder than room temp. 32W lamps that can operate at lower temp puts out correspondingly more light. I crossed out the 700 series lamp, which is the lowest bid lamp. Premium LED lamps cost far more than premium T8 lamps, so I believe its fair to leave out the cheapest FL lamp.
Philips TLED with dedicated Philips LED ballast. Not much difference if using their NEMA PREM T8 ballast. The lumens in this chart is per lamp, watt is per two lamp system. As far as these lamps are concerned, these lumens assume operation on dedicated LED ballast or 0.88 BF FL ballast. LEDs and fluorescent both require a ballast regardless of how sales department chose to disclose it and with fluorescent ballasts hitting 90-95% efficiency, we're already very close to realistic limits. Line voltage LED lamps just move the ballast loss to inside the lamp envelope. There are four pins per lamp and at present time, pin assignment is all over the map on "ballast bypass" type lamps meaning that replacement lamp bought to replace failed LED lamps could require rewiring to accommodate them.
This is what it's looking like with contemporary fluorescent system. Lumens and watts are both in pairs. The outputs for both technologies are day-one performance, but those builder's grade LED lamps that you can buy for under ten bucks have steeper LED degradation slope than F40CW.
*note 1:
When you crunch numbers with book values, you can actually end up with higher lumens per watt than dividing the lumens by watts from the lamp's box. This is because lumens per lamp watt is calibrated at 60Hz for T8 and T12 lamps. All fluorescent lamps make a tad over 10% more light per watt on high frequency. Even though T8 lamps can operate at 60 Hz or high freq, almost all T8 lamps in the field are operated at tens of KHz. T5 lamps are not intended to be operated at 60Hz and as such the specs for T5 lamps are measured at 25,000 Hz which means you divide out the lumens by watts on the box, but this has been exploited by sales people to present T5 as having superior efficiency.
I was thinking that seemed pretty high as well. 10 watts total loss for a 4 lamp ballast, maybe but still probably on the high side of reality.
