Convection. Warm air rises and causes cooler air to be pulled in under it from the other side of the room. The cool air being pulled in lowers the pressure above it which causes the warmer air that has risen to the ceiling to move into the room away from the window.
If you looked sideways at a room with the radiator and window on the left wall the air would be making a circular pattern in a clockwise motion. The warm air is being pulled *away* from the window at the top of the room and the cooler air at the ground is pulled towards the radiator which then heats it up.
I get the idea and tradition of countering a down draft and avoiding poor convection flows, but how much of this is really tradition and hypothesis (which predated our ability to accurately model this) Vs practical reality?
(I) a lot I’m pretty sure came down to building design convenience and tradition,.under the window is a handy place to fill with radiator that is often hard to use for anything else, on another wall a radiator will take wall space, esp traditional horizontal ones.
(Ii) laying pipes to outer walls tends to extend pipe run (sometimes hugely), under many national codes these don’t need to be lagged, this will lead to loss, and a greater pressure drop & demand on the system
(Iii) heating air next to any window also increases the temp gradient, and that (disregarding flow) increases heat loss, almost linearly with temp gradient. The point of the Q I think, and v good Q IMHO.
(Iv) it puzzles me how many radiators are positioned to flow hot air behind a curtain or blind, rather than using the curtain as a thermal barrier, newer blinds might also be pretty helpful in disrupting down/convection currents
It’s a looong time since I studied thermo, but back then there was no way near enough computing power to model a fridge, let alone something as complex as a room! Got a feeling we could do with revisiting yesteryears’ hypotheses here’s with some tests and modern modelling.
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