Roof Moisture Problems

The primary purpose of the roof-covering material is to keep moisture out of the home. Too much roof moisture in the home can cause a number of problems.

Material Damage From Roof Moisture: Decay, Corrosion and Leakage

Roof moisture can damage many different kinds of materials commonly found in homes. In a granular material such as drywall, water is absorbed into the spaces between the particles, reducing the material’s strength.

This is why ceiling drywall sags when it becomes saturated from roof moisture issues.

In cellulose-based products such as wood, wood rot (which is properly called wood decay) can take place when material moisture levels reach about 20%. Since most houses are wood structures, decay can be a significant problem, especially if it continues undetected for a long time.

Corrosion is another concern. Most of the metal fasteners and connectors that hold roof framing together are made of metal, making them vulnerable to damage from corrosion due to roof moisture.

Because roofs may leak into attics or the interiors of walls, evidence of roof moisture leakage is not always visible.

Human Health and Roof Moisture

Human health is another concern with roof moisture issues. Mold is caused by fungi which become active at about 20% moisture level. Mold fungi reproduce by releasing microscopic spores into the indoor air, which can cause health problems if they’re inhaled.

The immune systems of healthy people are usually able to handle elevated levels of mold spores. People with asthma, allergies, lung disease, or compromised immune systems can develop serious or fatal fungal infections.

Comfort Levels in Your Home

Higher relative humidity inside a home is perceived by people as heat. This is why 85° F in Biloxi, Mississippi, where the air is very humid, will feel hotter than 85° F in Death Valley, where the air is very dry. In fact, in Death Valley, 85° F will feel cool.

The same holds true for the inside of your home. If the air inside your home is humid because a roof leak from roof moisture has allowed moisture intrusion, during the cooling season, comfort levels will be lower and cooling costs will be higher, since the air conditioner will be running more often.

During the heating season, dry is more comfortable than damp.

Forms of Roof Moisture

The types of roof moisture problems commonly found in homes can vary with the type of climate in which the home is located. Homes located in hot and humid climates, such as Key West, Florida, and in cold and dry climates, such as Steamboat Springs, Colorado, will often experience moisture in different forms, as well as different types of roof moisture problems.

Solid Roof Moisture Examples

Ice and snow are examples of roof moisture as a solid. As water turns to ice, it expands by about 10%, creating a powerful force that can crack materials that are too brittle to flex. As ice, moisture can form dams that cause melt-water to back up beneath roofing materials and cause leaks. Efforts to remove ice dams may damage roof-covering materials.

As snow, it adds weight to roofs and holds moisture against the roof.

Liquid Form of Roof Moisture

As a liquid, water falls down from the sky, bounces upward from the surfaces it hits, and moves in unexpected directions — sideways, backward and upward — as when roof drainage is dammed by blockages or absorbed by materials.

Gas

Water in the form of a gas is called “moisture vapor” and consists of microscopic droplets suspended in the air. These droplets can be carried through very small openings by air currents.

Cooking, bathing, washing clothes, even human respiration all put moisture into indoor air. All the water used to water plants will eventually wind up in indoor air. If this water vapor has no easy route to the home’s exterior, comfort levels and air quality can suffer.

Moisture vapor created in the home can be absorbed by the roof deck. The roof moisture causes it to expand and buckle shingles as the spaces between sheathing panels become smaller.

Moisture vapor can also enter the home from outside. Improper attic or roof venting practices can cause roof moisture from hot, humid, outdoor air to condense on the roof framing. This condensation can then be moved into the home by gravity and the gradient forces we’re about to discuss.

Moisture Movement

A number of different forces can affect the ways that moisture moves from one place to another.

Roof Moisture and Gravity

The most obvious force is gravity. Water moves downhill. Gravity can create problems, such as when it tries to move moisture past roofing materials protecting a home interior. Or, it can help prevent them, such as when it moves water quickly off of a steep roof.

Roof Moisture Gradients

Other forces that move moisture include several gradients. A “gradient” is the movement of something across an area of difference. Gradients are named according to the force that causes the movement.

Thermal Gradient

According to the “thermal” gradient, moisture is moved by differences in temperature. Moisture moves from warm areas toward cold areas.

Roof moisture on a warm, wet roof will try to migrate toward a cool, air-conditioned home interior.

Pressure Gradient

The “pressure” gradient describes the tendency of moisture, often in the form of vapor, to move from areas of high air pressure to areas of low air pressure.

Air pressure inside a home can be lowered by whole-house fans, exhaust fans in dryers, bathrooms and kitchens, or by the combustion exhaust systems of furnaces, boilers and hot water heaters.

All of these devices push indoor air to the outside. If it’s humid outside, this condition can draw moisture-laden air into the home.

Concentration Gradient

The “concentration” gradient describes the tendency of moisture to move from areas of high concentration to areas of low concentration. In other words, moisture moves from wet areas toward dry areas.

Thanks to

Kenton Shepard and Nick Gromicko

Structural Insulated Concrete Walls

Insulated Concrete for Exterior and Structural Walls

According to the National Association of Home Builders (NAHB) and the Portland Cement Association (PCA), concrete homes account for approximately one-sixth of all new-home construction, and in areas such as Florida and Louisiana, they are particularly favored because of their greater resistance to hurricanes and tornadoes.

Contractors and buyers alike are attracted to their durability, strength, and heat-retention qualities. Let’s take a look at how homes constructed using concrete – in their common application as insulated concrete forms or ICFs – measure up against wood-frame homes.

Does the greater initial cost of insulated concrete forms pay off in the long run?

Proponents of insulated concrete forms claim that the initial higher cost of building with concrete as opposed to the more common wood-frame construction is justified by the savings on lower heating and cooling costs, lower property insurance, and lower maintenance costs.

A variety of factors affects the cost-benefit of insulated concrete forms, including:

the cost of wood compared to concrete for the local area;
the thickness of the walls;
the number and types of windows in the home;
ceiling insulation;
the sizing and efficiency of the heating and cooling equipment; and
the climate in the region where the home is constructed.

The U.S. Department of Housing and Urban Development (HUD) found in 2001 that using insulated concrete forms in construction added about 3% to 5% to the purchase price of a typical wood-frame home. These estimates should be treated with caution, however; a study by the PCA found that additional costs associated with insulated concrete form construction depend on the skill of the crew, and greater savings are found on large-scale projects involving multiple homes, where the method and economy of scale come into play. Simply put, local contractors may take on an insulated concrete form project but may lack the necessary expertise for execution, resulting in added costs.

Additionally, the greater construction costs for a typical insulated concrete form home are not necessarily recouped by the savings on energy and home insurance alone.

Other Values Offered by Insulated Concrete Forms

Resistance to Hazards

The single most significant attribute in favor of concrete construction is its structural safety. Implicit in the average lower insurance cost for insulated concrete form homes is the understanding that ICF homes better withstand natural disasters, such as hurricanes, tornadoes and floods. Insulated concrete form homes typically “recover” from hurricanes far quicker than wood-frame homes, as the exterior walls may withstand a hurricane and only a new roof will be required following such an event. huntsville tornado damage 01 Structural Insulated Concrete Walls In comparison, wood-frame houses in the same areas are usually devastated by hurricanes, meaning
longer rehabilitation times for residents and lengthier processing times for insurance claims. Concrete offers far better compressive strength, and far greater resistance to windborne debris. Insulated concrete form walls have been tested for resistance to tornado conditions by subjecting them to the impact of a 2×4 wood stud traveling at 100 mph. Although it is possible to upgrade the impact resistance of standard wood-frame wall construction to levels suitable for protection against moderate hurricanes and less severe tornadoes, it is impractical to upgrade standard wood-frame wall construction to give comparable performance of ICF walls.

Insulated Concrete Forms and Fire

Concrete walls have superior fire resistance compared to wood-frame houses. Solid concrete insulated concrete form walls can generally sustain as much as four hours of extreme fire exposure, whereas typical wood-frame walls in houses generally do not exceed a one-hour fire rating. For housing, building codes typically require a minimum 15-minute rating, with the exception of special fire separation requirements for multi-family construction, apartments, and townhouse units, where a minimum one- to two-hour fire rating is required for walls between dwelling units.

Furthermore, concrete is not a fuel source that can contribute to fire growth and spread in a building. However, it is also important to realize that doors, windows, and other cavities can mean lower resistance to fire spread if not similarly fire-rated, in comparison to the walls. Regardless, fire resistance is a recognized benefit of insulated concrete form construction and can result in reduced fire insurance premiums.

Durability of Insulated Concrete Forms

In Ireland, where housing ownership is relatively high and the cost of wood compared to concrete is also relatively high, concrete housing is the preferred material for construction. An added appeal for those wishing to go with concrete is the perceived notion that concrete houses will last hundreds of years and thereby provide a legacy to future generations. While it is difficult to exactly quantify durability benefits in the varying use-conditions of building materials, concrete offers added resistance to moisture and other environmental factors. While wood is protected within the walls of the home, it is susceptible to rot in areas where water often penetrates the exterior weather-resistant barrier of a home.

Insulated Concrete Forms and Noise

A study conducted by the Public-Private Partnership for Advancing Housing Technology, or PATH, rated concrete’s sound-absorption qualities as “excellent,” while wood homes scored “average” to “good.” In order for a wood-frame home to obtain similar performance ratings, it is necessary to make certain modifications, such as using thicker gypsum board layers, resilient channels, or acoustic insulation. These enhancements can add about $0.70 per gross square foot of wall area, which accounts for an increase of about 20% in the cost difference between insulated concrete forms and standard wood-frame construction (see the table below). In addition, concrete’s dampening quality limits the vibration to exterior walls when doors or windows are slammed, for example.

Windows and Doors Used Insulated Concrete Forms

In traditional wood-framed homes, there is an added cost associated with installing the windows and doors. Additional material is required to support them, often with expensive micro-laminated headers or additional stud support. In comparison, the overall cost per square foot of fenestration and door construction decreases with concrete, as the concrete bonds better around the cavity and maintains structural support. However, a study of thermographic testing by the NAHB found that houses constructed with insulated concrete form walls have up to a 50% decrease in the required capacity of HVAC equipment because the greater insulative capacity of concrete allows for smaller heating and cooling systems. Finally, once the concrete is set, it is comparatively difficult and costly to saw through the concrete to create additional cavities or modifications for HVAC units or windows.

Cost Comparison Based on Performance

Another way of assessing the cost-benefit of insulated concrete form housing is to measure the cost of upgrading a wood-frame home to perform in a manner similar to a concrete home, shown in the following table.

Performance Characteristic	Increase in cost to upgrade or retrofit a typical wood-frame home to ICF standards
Fire protection	Not feasible or considered impractical
Sound-proofing	20%
Durability	20%
Energy efficiency	33%
Safety and hazard mitigation	50%

As seen above, the added costs of upgrading a wood-frame home to meet comparable performance levels of an insulated concrete form home show that concrete homes may offer greater value, depending on the consumer’s needs.

While it is commonly agreed that insulated concrete is a more expensive technique for home construction, it is generally incorrect to presume that the greater initial cost will be recouped by energy savings alone. The single biggest attribute in favor of insulated concrete is its structural integrity and ability to withstand severe environmental hazards. Rather than looking at any single element of the cost-benefit scenario, the greater all-round performance attributes of insulated concrete provide a compelling argument for its choice as a construction material in exterior walls.

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Wood Decay

Wood Rot and Decay

Facts about wood decay and decay fungi:

According to Ohio State University, replacement materials needed to repair damage caused by decay account for nearly 10% of U.S. annual wood production.
Carpenter ants, termites and other wood-destroying insects do not cause wood decay. These insects are, however, attracted to wood that has been softened by decay.
Decay fungi are active in temperatures between 77° F to 90° F, and need water, oxygen and a food source to survive.
Fungi that cause wood decay are called saprophytic, a term also applied to other organisms that consume decayed material. Many species of fungi, along with saprophytic beetles, worms, protists and bacteria are essential components of the decomposition and nutrient cycles.

How does wood decay happen?

Fungi reproduce by manufacturing single-celled spores, similar to microscopic seeds. Spores are tough; they’re able to resist extreme conditions of white Wood Decay temperature and humidity and, under adverse conditions, they may go dormant for long periods. Spread primarily by air currents, they collect on horizontal surfaces. Decay fungi feed on the cellulose and lignin of which wood cell walls are composed. Their hyphae, which are threadlike tubes that penetrate the wood, secrete enzymes which dissolve at least part of the wood cell being fed upon, changing it into a form which can then be absorbed as food. Spores require a moisture content higher than the Fiber Saturation Point (FSP) of the wood species upon which they rest, typically between 27% and 30%. Once sufficient water and favorable temperatures are available, spores germinate and develop by extending a hyphal tube. As more spores germinate, fungi multiply to form a colony. Under the right conditions, colonies can expand quickly.

Common types of wood decay:

brown rot: This type of decay causes the wood to break down into brown cubes that split against the grain. Advanced stages of brown decay result in dry, powdery wood that is unable to support much weight, and crumbles easily.
white rot: This type of decay appears whitish, stringy and mushy, and tends to be more common in hardwoods.
dry rot: A misnomer, this term has been used to describe decayed wood that has since dried and ceased decaying. Some people may erroneously assume that the wood is still in the process of decay. Moisture is required for wood decay to occur, so no literal “dry rot” exists.

Identifying Wood Decay

Inspectors should check any areas suspected of containing decay by probing. A screwdriver works well for this. Wood with advanced decay will be soft and the probe will penetrate easily. Areas with incipient decay may be a little trickier to identify.

The pick test can also be used to identify decayed wood. To perform this test, a pointed tool, such as an ice pick, is inserted beneath the wood grain to pry loose a thin section of wood till it breaks free. Sound wood will snap crisply and typically breaks off to one side of the pick. Decayed wood will break with a dull sound and usually breaks above the pick’s point of insertion.

Although wood-destroying insects, such as termites, are attracted to decayed wood, they also inhabit sound wood. Always probe or use the pick test to confirm that what you’ve found is sound wood.

Wood Decay Prevention

If the decay hazard is high, select the heartwood of decay-resistant species, or use wood properly treated with a good preservative. (A list of decay-resistant species can be found later in this article.)
Proper grading can prevent water from seeping under the house.
Effective roof overhangs, gutters and downspouts should be installed.
No untreated wood should be placed within 18 inches of the ground.
Adequate cross-ventilation in crawlspaces will help eliminate dead air pockets, which contribute to wood decay.
A vapor barrier can be installed on the soil surface to help limit evaporation and return moisture to the soil, rather than allowing it to condense on the floor and above joists. Plastic sheets can cover the soil to act as satisfactory barriers.
Dehumidifiers and bathroom and kitchen fans will reduce indoor water vapor, and potentially dry wood enough to prevent decay.

Likely Wood Decay Locations:

stairs and attachment points to the house in decks;
improperly installed door thresholds, especially beneath sliding glass doors;
decks at or near grade;
ground-roof penetration;
roof penetrations with improper or corroded flashing;
beneath windows;
support post bases of decks;
near corrosion of fittings on plumbing;
in basements where housebibs may have burst;
in sub-floors at the base of toilets and tub corners;
the uphill side of chimneys;
sidewall and headwall locations; and
untreated wood in direct contact with concrete, masonry or soil.

Moisture can come from:

general moisture intrusion of building envelope;
plumbing leaks;
snowmelt;
improperly installed, damaged or corroded flashing;
ice dams;
finish grades that slope toward the foundation; and
foundation cracks.

Types of naturally resistant and non-resistant wood:

Resistant woods: teak, rosewood, oak, redwood, cedar, black locust, red mulberry and yews.
Non-resistant woods: hemlock, pine, maple, aspen, alder, elm, birch, buckeye, poplar and beech.

Wood decay is caused by fungi that are attracted to wet locations.

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Wood Decay

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Roof Moisture Problems