Tuesday 30 August 2016

Solar-powered wearables

Why put solar panels on the roof, when you could wear them?

www.ecouterre.com Solar powered wearables guaranteed to give you a charge

(Apart from lack of surface area, washing, electrical storage, waterproofing, most energy being needed by buildings, and probably spending most of your time inside.)

Friday 26 August 2016

A breath of fresh air in a sea of thermodynamics

I remember a conversation between our architect and one of the potential contractors, and the question was what kind of heat recovery ventilation system we were using. I'd only just discovered that heat recovery ventilation was possible, and didn't dwell too much on this question. The answer was that we were using heat recovery ventilation rather than moisture recovery ventilation.

To recap:
  • If you want a warm house, you need insulation.
  • If you have insulation, the house should also be airtight. 
  • If it's airtight you need mechanical ventilation with heat recovery.

Insulation, airtightness and mechanical ventilation with heat recovery represent a holy trinity of low energy building that cannot be violated. 

Without insulation, you're going to lose a lot of heat,  and you're going to get cold spots on the thin external walls, which will lead to condensation. Cold, expensive to heat, and damp!

Without airtightness, you're going to get humid air passing through the insulation and at some point that will lead to condensation. It will probably happen in the worst possible place: where you can't see it, but your structure can.

Without ventilation, you'll eventually suffocate, but way before that the humidity is going to get so high that you'll get condensation even where there is airtight insulation. 

Mechanical ventilation is best because any kind of natural ventilation will usually lead to too much or too little exchange of air, depending on how nature is feeling at a particular time. 

If you're going to have mechanical ventilation, you should put in a heat exchanger and then you don't need to throw away all the heat in the air.

...

So five years later I'm still learning things about ventilation. I've written a bit about our problems with heat recovery ventilation, but I know even less about the other kind: energy recovery ventilation, or moisture recovery ventilation. These are abbreviated to HRV and ERV for any fans of the TLA (three-letter acronym). 

In both systems the air leaving the house passes through a heat exchanger and there is a transfer of heat to the air coming into the house across a membrane. In fact it is an array of membranes and with a well-designed arrangement of cross flow and counter flow, you can recover over 90% of the heat in the air. The transfer of heat follows the third law of thermodynamics, from hot to cold, so this will keep the house warmer in the winter, and cooler in the summer.

The difference between the systems is in moisture. Heat recovery ventilation just transfers heat, while energy recovery ventilation also allows moisture to transfer. This will also move from higher to lower humidity, so will tend to keep the humidity out in the summer, and stop the house from getting too dry in the winter. 

So which one should you get? 

As usual there are different schools of thought:
A) A is definitely better than B
B) Only a bloody idiot would use A
C) There are good and bad points of both so in the end it doesn't make a lot of difference which one you choose

It's probably more fashion than physics, and I'm going to be writing about fashion soon!

But until that link works, you can read about the different kinds of heat exchanger from Zehnder America.

Wednesday 24 August 2016

It's a Passive House, not a passive solar house

Here's another thing I didn't fully appreciate until taking the Passivhaus course last summer. The windows don't need to be that big.

I guess I started off with the idea of getting all our energy from the sun, so that we wouldn't need to get any heating energy from anywhere else. This is known as passive solar design. It was a popular idea in the 1970s, but by the early 1980s it was clear that super-insulation was a better approach. Trying to meet heating needs by making the south-facing windows as big as possible was the wrong approach for two reasons: it would end up being much more expensive, and on a sunny day the south facing rooms would get far too hot.

At least this was clear to those involved in those discussions in the 1970s and 1980s, but there have since been generations of house builders clinging to the dream of putting in enough windows so that heat is free.

This doesn't mean we should live in caves. Windows in houses are a very good idea, and it's also important to put most of the windows to the South where they will get solar gain in the winter and will be easier to shade in the summer. Also it's a good idea to have few windows east and west where there will be little heat to gain in the winter when you need it, but a significant amount in the summer when you don't.