Chapter 1
[earth sheltered home cross section]
The control of underground heat-flow is a steadily expanding technology. Considerable advancement has now been made toward the production of cold-climate homes that require no mechanical heating or cooling whatsoever. By using a new process called Passive Annual Heat Storage, heat can be collected, stored and retrieved, over the entire year, without using energy robbing mechanical equipment.
Plain old dirt is the ideal heat-storage medium. Heat is stored naturally in the earth as it soaks up the warm summer sunshine. The earth retains this heat until cold weather arrives, then it slowly relinquishes its store to the open air. The summer-long heating up and the winter-long cooling off produce a year around constant temperature 20 feet (6.1 m) into the earth. Interestingly, this constant temperature mirrors the average annual air temperature.
An earth sheltered home designed with the principles of Passive Annual Heat Storage, controls the summer heat input and winter heat loss to establish a new average annual inside air temperature, which, in turn, will produce a new constant temperature in the earth around the home. The home and the earth will
[Fig. 1]
work together to remain within just a few degrees of this average all year long. In this way the environment around the earth sheltered home can be climatized to any suitable temperature. Of course, a home set comfortably in a nearly constant 70 degrees (21 degrees C) environment needs neither air conditioners nor furnaces.
[Fig. 2]
THE FIRST WORKING EXAMPLE
This unique heat control method was still in its infancy in January of 1981, when a major feature of Passive Annual Heat Storage (an insulation watershed umbrella) was incorporated into the design of an earth-sheltered home that was being built in Missoula, Montana. This home, called the Geodome because of its shape, has its insulation watershed umbrella extended into the earth about ten feet (3 m) beyond the walls of the house, and encloses a two-foot (.6 m) deep portion of earth on the roof. (fig. 4)
[Fig. 3]
The building is monitored by 48 temperature and five moisture sensors. By the autumn of 1981, the temperature ten feet (3 m) under the surface, 12 feet (3.7 m) behind the north wall, and two feet (.6 m) beyond the insulation itself had been heated by excess summer heat from its usual 45 degrees to 64 degrees (7 18 degrees C). The two-foot (.6 m) deep portion of insulated earth on the roof was warmed up to 77 degrees (25 degrees C), while two feet under the floor it was 68 degrees (20 degrees C). Throughout the first year, the north wall temperature on the second floor of the home varied only six degrees, from a high of 72 degrees (22 degrees C) in September to a low of 66 degrees (19 degrees C) the next February. Thus the home has been snugly wrapped with a nearly 70 degree (21 degree C) layer of earth, several feet thick (1 m), which has kept the home comfortable all winter. Even though the insulation umbrella is only half as big as we now know it should be, the earth around the home remains warm and dry!
This outstanding performance has provided operational proof of the advantages of Passive Annual Heat Storage over conventional earth shelter design methods. As a result, further improvement has been made in the art of long-term heat-storing.
[Fig. 4]
IMPROVING THE EARTH SHELTER
Earth sheltered homes do enable the non-mechanical methods of passive solar heating to be used more effectively because earth sheltering is inherently energy efficient. Some solar- heated earth-sheltered homes have worked quite well in selected climates. But even the better ones have been able to maintain a fairly stable temperature for only a week or so in inclement weather without needing back-up heat. Generally, passive-solar homes of all types have been able to collect only a portion of their space-heating needs because of one inherent problem: solar energy simply isn't there when it is needed.
The noon sun is highest in the sky on June 21st and lowest at the tail end of December. It provides plenty of heat in the summer but, thanks to short days and foul weather, heat availability all but disappears in the winter, especially in the cold and cloudy Northwest. So, attempting to collect a home's heating needs in the winter-time is like trying to collect milk from a dry cow!
What is needed to bring solar heating out of the dark ages is an inexpensive method for storing large quantities of heat over the entire year in a simple, natural, passively-operated reservoir: the earth. However, conventional earth-shelter designs do not take full advantage of the fine heat-storing ability (thermal mass) of the earth. A simple heat flow principle tells us why. Heat flows by conduction from warm places to cool places.
Conventional earth sheltered-homes prevent the earth about them from getting warm enough in the summertime to allow the heat to flow back into the home in the wintertime. While the concrete may warm up to room temperature, the earth around the building usually has its heat flow characteristics dominated by the colder outdoor weather conditions, rather than the controlled indoor temperatures. This occurs because the heat-storing earth is usually insulated from the heat-collecting house and not insulated from the generally cooler out-of-doors. Therefore, the conventional insulation layout actually prevents the home's average annual air temperature from establishing a sufficiently warm deep-earth constant temperature.
Storing a large amount of heat at room temperature requires a large amount of thermal mass. The relatively small warm storage mass of the conventional solar-heated earth-sheltered home prevents the use of the abundant summer heat, since heat can be stored to last for only a week or so in cloudy winter weather before a back-up heater must be turned on. Homes that are restricted by small thermal storage are thus forced to resort to winter- oriented passive solar heating, which discards the energy-rich summer sunshine by shading. This also limits building locations to those where sunshine is readily available in the wintertime.
For an earth sheltered home to remain warm all winter from heat gathered six months earlier, the heat storing earth must be kept both warm and dry. When cold rain water is allowed to soak into the ground around the building, as it is in conventional earth sheltering, it not only causes waterproofing difficulties, but it cools off the earth.
Further improvement is also needed in the current methods of supplying fresh air to tight underground structures, because most ventilation methods bring in hot air during the summer and cold air all winter.
Recognizing such problems is the first step toward solving them. Now, all of these problems can be solved by using the principles of Passive Annual Heat Storage.
HOW PASSIVE ANNUAL HEAT STORAGE WORKS
Passive Annual Heat Storage is a new process for allowing summer's heat to be absorbed right out of the home, keeping it cool and comfortable, and storing this heat at room temperature in the dry earth around the building. This reserve can then be conducted back into the home any time the indoor temperature attempts to fall, even through an entire winter. So, the home and earth together will maintain their comfortable temperature automatically, within just a few degrees.
[Fig. 5]
This unique method for maintaining a deep earth constant temperature of about 70 degrees (21 degrees C) is based on several principles of physics:
1. Heat flows by conduction from warm places to cool places, and will ONLY return when
the original source cools to a temperature which is below the storage temperature.
2. Far more solar heat is available in the summertime than in the wintertime.
3. Earth is an ideal thermal mass for storing heat over time periods well in excess of six
months.
4. The constant temperature 20 feet (6 m) into the earth is a reflection of the average
annual air temperature.
5. It takes six months to conduct heat 20 feet (6 m) through the earth.
Earth sheltered technology can be significantly improved by a balanced application of these simple principles.
Passive Annual Heat Storage overcomes the deficiencies of conventional earth-shelter and passive-solar design by isolating a large thermal mass of dry earth around the home with a large insulation watershed umbrella, so that the earth itself may be warmed up to room temperature. (fig. 5) To contain this heat we must cause the heat to flow between the earth and the home, rather than the earth and the out-of-doors. Therefore, all short conductive paths to the outdoors must be cut off. The insulation need not enclose all of the earth underneath and to the sides of the home because heat which flows 20 feet (6.1 m), or more, through the earth will be delayed long enough so that warm summer weather will arrive before last year's heat can make it all the way out from under the umbrella.
The home will establish its own average annual air temperature by controlling the summer heat input and the winter heat loss. Therefore, it will now produce a new deep-earth constant temperature all the way around the home. Since heat moving both in and out is under control, the home's operating temperature may be adjusted to any average temperature we wish.
The insulation watershed umbrella also keeps the entire earth environment around the home dry, preventing the heat in the earth from being washed away and making waterproofing a cinch.
COST
Passive annual Heat Storage, including the earth tube ventilating methods suggested in this book, are inherently INEXPENSIVE in comparison to the usual cost of building an earth- sheltered home. The insulation watershed umbrella is made by laminating layers of rigid insulation with at least three layers of polyethylene sheeting. It is, therefore, long lasting and relatively inexpensive to buy and install. Only a little more insulation is needed than with conventional methods of putting insulation on an underground home, since the subterranean surfaces will be left uninsulated. Also, waterproofing costs are reduced considerably, because the home sets in a dry environment.
A little insulation, a little plastic, a little pipe and a whole lot of thought about how they should be installed, make Passive Annual Heat Storage the least expensive energy management system anywhere.
Read on! The principles described in this book will greatly enhance the operation of any earth-bermed or earth-sheltered structure, and with a little design finesse, ANY STRUCTURE, as we shall see.
The rapidly advancing science of underground heat flow has opened the doors to a whole new array of home design methods that will make heaters and air conditioners to homes what paint is to a beautiful stone wall!
