I assume most decorative fireplaces on the other hand are not built to heat the house.
Old school version of that were masonry stoves that come with ton+ of mass for the bricks and smoke being routed all over (often including a place to sleep) to take as much heat as possible from it.
If I had money for that I'd put a big hot water tank for buffer, heat it normally with heat pump, and just had emergency water-sheathed fireplate, with big buffer you can just fire it up once and have tank slowly give the heat back to the building. Or fire it up at the coldest days to save some heat pump power in days where there is barely any solar.
And here's more info on The Little Ice Age: https://en.wikipedia.org/wiki/Little_Ice_Age
Debatable as to whether solar activity was a contributor to The Little Ice Age.
It doesn’t seem completely implausible.
We don't use fireplaces anymore (a major "trick" being to put them in the middle of the house rather than in the exterior walls), and while using large windows to capture sunlight and heat works great in the winter, it also leads to overheating in the summer and thus more energy for air conditioning.
> These are modest changes, imperceptible to most, and they won't enable us to forgo active heating and cooling entirely. But they do echo a way of thinking which, today, is oft ignored. Hardwick Hall was designed with Sun, season and temperature in mind.
Everyone I know who has built a house has thought very much about sun, season and temperature. This is very much a factor in determining the sizes and quantity of windows on south-facing vs. north-facing walls, for example.
Again, it's a very interesting article on this one particular castle, but the idea that it has something to teach modern architects and builders is pure fantasy. We're already well aware of all these factors and how they interact with materials and design.
I've lived in houses that certainly did not take into account sun, season and temperature. I learned a lot from that experience. My current house is optimized for it. I've learned a few more things about it, and could do better.
> the idea that it has something to teach modern architects and builders is pure fantasy
Not my experience with architects and builders.
For example, how many houses have a cupola? They're common on older homes, but non-existent on modern ones. What the roof does is accelerate the wind moving over the roof, then the air vents in the cupola let the wind through, which sucks the heat out of the attic.
Another design element is eaves. Eaves shade the house in summer and don't shade it in winter (for more heat gain). Eaves also keep the sides of the house dry, which means your siding and paint and window frames last a lot longer. Mine are 1.5 feet. Most houses around here have tiny or even non-existent eaves.
The advent of air-conditioning is when architects stopped paying attention to the sun.
All architects think about siting and solar exposure. But the builders are in charge, and they optimize for what the market responds to -- which does not always include factors like these which contribute to long-term comfort and livability.
So I would say that consumers could learn a thing or two. That said, most buyers are not buying newly-built homes, so their ability to influence the inclusion of some of these features are limited.
The industry is downstream of market demands. If customers aren't aware enough to demand smart things, builders will skip them to save money, or to optimize for more visible features. Same old story.
A lot of contemporary energy-efficient designs slope the windows now such that light can enter in the winter but not the summer, but in the past this problem would have been remedied with awnings.
Making what's essentially "an insulated box" is far more universal climate-wise than most of the old methods, because what's good in summer (north-facing windows, good airflow, getting some cold from the ground) is terrible for winter and vice versa. And where it is useful, it IS used, just instead of fireplace having big thermal mass we have floor heating where the concrete floor is the heat storage (and sometimes extra tank of water)
And every method to make it "better" directly competes with "just buy more solar/battery to run heat pump cheaper.
That's what awnings (or solar overhangs, or light shelves) are for. You block the high/hot summer sun but let in the low/cool winter sun.
> the idea that it has something to teach modern architects and builders is pure fantasy
Isn't the idea of mcmansions that they co opt smart classic design ideas, but use them in a manner which doesn't let them fulfill their function purpose(skeuomorphism)? So someone certainly has some things to learn
I imagine that McMansions are generally about as energy efficient (per square foot) as other contemporary homes, though.
Right, this is my point. We already think about these things.
> Isn't the idea of mcmansions
I don't think McMansions, or whatever your favorite example of bad architecture is, shows that we've somehow lost knowledge. Architects and builders are aware of all of these things, but that doesn't mean there aren't still clients who want less energy-efficient designs for all sorts of reasons, like aesthetics.
We know how to build energy-efficient buildings that are appropriate for the location and seasons. We also know how to build buildings for other purposes, and are aware of the tradeoffs in how they use more energy. Energy conservation isn't the only goal in home design.
Good thing initiatives like the passive house institute are bringing back some of these principles, you can easily cut a modern home heating/cooling needs by 70%+ by following simples rules
People building houses today are much better served by spending their money on solar + battery + heat pumps than going passive.
It's better no matter the heat source really. And it allows you to do without central heating and/or complex heating techs which are more annoying to maintain and replace
> expensive mechanical ventilation
A top of the line heat recovery ventilation unit cost the same as a shit tier air/air heat pump and has no moving parts besides the fans, which are cheap and easy to replace.
You can even make reasonably efficient heat exchangers at home with corrugated plastic sheets...
The old houses didn't overheat because the floor wasn't insulated all that well so the cold came from below. We could do something similar by just mounting heat pump ground loop under the house, before it is built, but today house developers want it cheap and quick so you pretty much can't find much of that and would have to do it on your own.
Other interesting system is using underground as a way to cool house air intake, just running pipes underground for several metres to get it to cool down in summer and heat up a bit in winter. But again, expensive thing compared to "just add more solar panels/battery storage and let AC handle it"
Which brings us to next interesting problem - you would think that ERV should be built-in into modern cooling/heating systems, but it’s no the case.
Most modern homes have this issue. Building science has driven them to be air tight bubbles. Look at blower door tests on current construction and a lot of "building science" driven construction.
All you need to do is design a house with a sensible ventilation system, which costs virtually nothing compared to the rest of the building costs. It's even more stupid for americans because they already all have complex ventilation system...
I'm always a little confused by radiators placed underneath windows in modern buildings. I'm sure it evens out cold spots, but it sends a lot of heat right outside.
Article[0] on it
I’ve heard a story, and I don’t know if it’s an urban legend, that steam heat became popular after the 1918 flu pandemic because it was going to force overheating of units and make people open their windows and let the bad air out.
I’ve never heard it put that way, but the flu pandemic had a huge impact on heating systems, because they actually changed the code requirements for heating systems when the pandemic was around, because they didn’t know what was causing this. They thought there was something in the air that was causing this. And so what they did is they started requiring buildings to be ventilated. Essentially, they changed the requirements for heating buildings so you had to maintain 70 degrees in the building with all the windows open in the sleeping rooms. So people see these great big huge radiators and think that that’s what they have to have in the house. Usually, the reason those radiators are so big is because they had to heat the house with windows open.
Edit: switched out to different article focused on Chicago
But, to answer the OP, putting conditioning on the perimiter of the building keeps the interior temperature gradient minimal. If you deliver conditioning to the center of the building, the perimeter approaches outside temperatures (depending) and you have a big gradient and much less comfort. There's also better heat transfer when you deliver conditioning at bigger delta T, which pushes towards the perimeter as well... But it means more ducting/piping. And if you're using fireplaces for heat, it's complex because classically fireplaces pull in air from the conditioned space, and make up air comes from outside, you really want that fire to warm up surfaces to get radiative heat; burying it in the center of the building will be better than having it off in the corner; but it you use outside air for combustion, you can put it on the perimeter.
I have had multiple conversations with people who lived a while in that area. Rich, educated countries, modern economies, but they live like they are poor farmers in the 19th century.
Were you in prison when you experienced the above?
A great example is the Clinton Presidential Library in Little Rock, Arkansas. At first glance, the building seems to be a giant rectangular box made of glass. Hardly ideal in the long, hot Arkansas summers.
It’s not the truth, though. In reality, the building is said to be highly efficient and was the first Federal building to be LEED certified. Amazing.
I guess we’ve learned a few things over the years.
https://www.clintonlibrary.gov/about-us/leed-certified-build...