Firefly Home Inspection, Inc.
* Air Quality
* Biological Pollutants
* Common Definitions
* Conserve Energy
* Constructed Wetlands
* EMFs in the Home
* Home Insurance Tips
* Mold Information
* Mold & Moisture
* Private Wells
* Septic Systems
* Water Quality
* Building a Home
* Energy Efficiency
* Foundation Insulation
* Historic Renovation
* Log Homes
* Electrical Safety
* Child Safety
* Holiday Safety
* Pool Safety
* Safety Checklist
* Senior Safety Tips
* 3 Mistakes
* Closing Process
* Things to Look For
* Prebuilt Homes
* What Really Matters
* Why Pay More?
* Ten Tips
Log Home Basics
Log homes may be site-built or pre-cut in a factory for delivery to the site. Some log home manufacturers can also customize their designs. Before designing or purchasing a manufactured log home, you need to consider the following for energy efficiency:
The R-Value of Wood
In a log home, the wood helps provide some insulation. Wood's thermal resistance or resistance to heat flow is measured by its R-value. The higher the R-value, the more thermal resistance.
The R-value for wood ranges between 1.41 per inch (2.54 cm) for most softwoods and 0.71 for most hardwoods. Ignoring the benefits of the thermal mass, a 6-inch (15.24 cm) thick log wall would have a clear-wall (a wall without windows or doors) R-value of just over 8.
Compared to a conventional wood stud wall [31 D2 inches (8.89 cm) insulation, sheathing, wallboard, a total of about R-14] the log wall is apparently a far inferior insulation system. Based only on this, log walls do not satisfy most building code energy standards. However, to what extent a log building interacts with its surroundings depends greatly on the climate. Because of the log's heat storage capability, its large mass may cause the walls to behave considerably better in some climates than in others. Logs act like "thermal batteries" and can, under the right circumstances, store heat during the day and gradually release it at night. This generally increases the apparent R-value of a log by 0.1 per inch of thickness in mild, sunny climates that have a substantial temperature swing from day to night. Such climates generally exist in the Earth's temperate zones between the 15th and 40th parallels.
Minimizing Air Leakage in Log Homes
Log homes are susceptible to developing air leaks. Air-dried logs are still about 15â€“20% water when the house is assembled or constructed. As the logs dry over the next few years, the logs shrink. The contraction and expansion of the logs open gaps between the logs, creating air leaks, which cause drafts and high heating requirements. To minimize air leakage, logs should be seasoned (dried in a protected space) for at least six months before construction begins. These are the best woods to use to avoid this problem, in order of effectiveness:
Controlling Moisture in Log Homes
Since trees absorb large amounts of water as they grow, the tree cells are also able to absorb water very readily after the wood has dried. For this reason, a log home is very hydroscopicâ€”it can absorb water quickly. This promotes wood rot and insect infestation. It is strongly recommended that you protect the logs from any contact with any water or moisture. One moisture control method is to use only waterproofed and insecticide-treated logs. Reapply these treatments every few years for the life of the house. Generous roof overhangs, properly sized gutters and downspouts, and drainage plains around the house are also critical for moisture control.
Building Energy Code Compliance for Log Homes
Because log homes don't have conventional wood-stud walls and insulation, they often don't satisfy most building code energy standardsâ€”usually those involving required insulation R-values.
However, several statesâ€”including Pennsylvania, Maine, and South Carolinaâ€”have exempted log-walled homes from normal energy compliance regulations. Others, such as Washington, have approved "prescriptive packages" for various sizes of logs, but these may or may not make sense in terms of energy efficiency. The American Society of Heating, Refrigerating, and Air Conditioning Engineers (ASHRAE) 90.2 standard contains a thermal mass provision that may make it easier to get approval in those states that base their codes on this standard. To find out the log building code standards for your state, contact your city or county building code officials. Your state energy office may be able to provide information on energy codes recommended or enforced in your state.
Building & Restoration of Log Cabins
The foundation of a log cabin is made of stone pillars. The stones provide a sturdy base to support the cabin and act as a barrier between the cabin and the earth. The stones may settle over time and the foundation is carefully examined for damage or wear and subsequently repaired during restoration.
Log cabin roofs are often gabled and are comprised of hand-split, wood shingles. The roofs often develop damage and leaks over the years and are commonly included in restoration.
Many log cabins have both a front and rear door. Due to the many times the doors are opened and closed over the years, the doors are often not in good working order and require repair during restoration. Both doors on the cabin can be comprised of boards that are hand-dressed, open inward and are fastened to the log structure with pegs.
The cabin features two windows, located on either side of the chimney. The windows hold glass panes, which most likely need to be replaced during the restoration of the cabin.
The cabin has a chimney that sank and deteriorated into many different pieces over the years. The chimney was rebuilt during cabin restoration.
Handcrafted log home
A home that is constructed of logs that are individually fit together.
Milled log home
Constructed of machine-lathed logs, and is also used to describe a log home built from a kit.
Insulated log home
Constructed with half-logs attached to a standard 2x6 frame structure.
The mixture used to fill the gaps between logs - can be natural materials or synthetic.
The normal loss of diameter in logs as they lose moisture.
The downward movement of log courses as the logs shrink.
The natural cracking of logs as they shrink.
Occur when two logs are placed end-to-end.
One layer of logs placed atop the entire foundation of the home.
Log wall exterior
The inspector shall inspect exterior surfaces of log walls, when such surfaces are visible, looking for:
The inspector shall inspect interior surfaces of log walls, when such surfaces are visible, looking for:
In addition to the items specified in NACHI Standards of Practice 2.1 and 2.2, the inspector shall inspect:
In addition to the items specified in NACHI Standards of Practice 2.4 and 2.6, the inspector shall inspect:
The inspector is not required to: