Storing Heat Underground in a Geosolar System

June 30, 2016

NOTE: Images in this archived article have been removed.

As an engineer and permaculture designer living in a cold-climate, I am particularly fascinated with the interplay between thermodynamics and design and with capturing “waste” energy and finding novel, inexpensive and efficient ways to store and/or recapture and re-use it. One of these such systems, is geothermal storage.

In late 2015, our consulting company, Adaptive Habitat, was hired to design and install a geosolar heat collection system just north of Calgary, Alberta, underneath a Ready-To-Move (RTM) home. For R&D and monitoring purposes we decided to outfit the system with 11 temperature probes.

We are really pleased with its performance to-date. Here is a summary of how it is designed it and what we have observed so far.

What is Annualized Geosolar?

This system, which is also called an Annualized Geosolar (AGS) system, basically captures hot air from the attic in the spring, summer and fall and, using a fan, blows it underground beneath the home. The heat from the attic air transfers into the soil as it travels through the underground duct and then migrates slowly through the earth, returning to surface approximately six months later. This heats the crawspace under the home during the winter months. The end result is a reduction in heating bills and increased comfort from a warm floor. Note that, in conventional design, the attic air would be simply discharged to atmosphere through a power vent – so we are not even increasing power consumption with this modification.

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How it Works

In the first video, I describe how air circulates through the AGS System.

In this second video, I go into more detail about the system design and take you underneath the crawl space.

How The System is Performing

Here are two screenshots, showing the change in temperature over the course of six months that the system has been running.

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You can see that the ground temperature around the ducts started off frozen (0 deg C) and is now in the range of 15 – 20 deg C. Based on these initial results, and based on my experience with other geothermal storage projects, I am anticipating that for every unit of electricity that we use to move heat (via the fan) we will get 13 units of heat returned into the home. That’s a Coefficient of Performance of 13!

For comparison purposes, your gas furnace has a COP of 0.7 – 0.9 which is 14 – 18 times less efficient. **(0.7 represents a furnace with 70% efficiency while 0.9 represents a furnace with an efficiency of 90%)

Design, Construction & Installation

Ideally, if you want to put something like this under your home or building, it needs to be thought-out and designed ahead of time. It would be possible to use this system in a retrofit but it would be less efficient and more expensive to install.

To install the system, we dug a trench down the center of the house pad, and used low cost materials such as two 50 gallon drums and 4.5 inch weeping tile for the inlet / outlet and duct work. We also had to bring a duct from the attic down into the crawl space. Material cost was around $3,500 CAD. We did have an excavator dig the trench, but he was there anyways digging the trenches for the eco-septic field that we also designed and installed (more on that in a later post).

Once the duct was laid, we covered and heavily compacted around the ducts both to eliminate settling and improve contact with the soil (thus improving thermal conductivity).

Then we laid burial grade expanded polystyrene as the insulative layer, which delays the captured heat by ~ six months. Basically the heat is forced to travel a longer horizontal distance, preventing it from returning before we need it. This reduces the depth at which we need to install the ducting.

(Ed. note: You can see a slideshow of photographs illustrating the project on Rob’s site.)

Summary

We are going to continue monitoring this AGS system for the next three years and will continue to report on it’s performance. By this winter, we should also have some numbers for the actual amount of heat returned to the home and we will be able to provide some quantification on the amount of natural gas and money saved in heating bills. With what we are seeing right now (ground temperatures of 15 – 20 deg C) and some experience with other projects, we anticipate the results to be very positive.

The Groundswell Network Society Community Greenhouse (a project we have been involved with for the last few years) also has an AGS system that has been in operation for over 5 years. Despite the fact that this greenhouse is located in the Rocky Mountains, and has an average winter temperature of -10 deg C, the greenhouse interior no longer drops below 0 degrees C, with no supplemental heating, because of the heat stored & being returned from the earth below.

I also already see an improvement in that the fan could easily be powered by a photovoltaic panel, which could eliminate any grid electricity required. Also, if the panel was sized correctly, it could be tuned and the control could be eliminated as well.

For those of you in warmer climates, you could use a variant system to cool your buildings in the summer and heat them in the winter to provide low-cost air conditioning.

I see a huge opportunity for these systems in similar mobile or RTM homes, greenhouses, conventional homes and commercial buildings. I look forward to seeing more of them get installed!

Rob Avis

Rob Avis is a petroleum engineer turned permaculture teacher, designer and public speaker. He graduated from the University of Alberta and also have international training and certifications in renewable energy and regenerative design. He and his wife Michelle have been running Verge Permaculture in Calgary for the past 5 years.

Tags: permaculture design, Renewable Energy