<![CDATA[To schedule an inspection, call our 207-956-0065

<![CDATA[To schedule an inspection, call our 207-956-0065 - Home Inspector Blog]]>Thu, 17 Aug 2023 21:15:39 -0400Weebly<![CDATA[Tim Bright of Brightech Property Inspections LLC is now a Board-Certified Master Inspector]]>Wed, 25 Jan 2017 03:31:20 GMThttp://brightechpropertyinspections.com/home-inspector-blog/tim-bright-of-brightech-property-inspections-llc-is-now-a-board-certified-master-inspectorr

Contact:
Tim Bright Certified Master Inspector®
Brightech Property Inspection LLC
(207) 400-1770
tim@mehomeinspection.com
www.brightechpropertyinspections.com

FOR IMMEDIATE RELEASE:
Timothy Bright Earns Certified Master Inspector® Designation

BRIDGTON, Maine. (Jan. 24, 2017) – Brightech Property Inspections LLC is pleased to announce that Owner Timothy Bright is now credentialed as a Certified Master Inspector (CMI)®, which is the inspection industry’s top professional designation.
The Master Inspector Certification Board has awarded the Certified Master Inspector (CMI)® designation to Mr. Bright for demonstrating the highest level of competency by completing 1,000 fee-paid inspections and/or hours of inspection-related Continuing Education, for having been in the inspection business for at least three years, for abiding by the industry’s toughest Code of Ethics, and for agreeing to periodic background checks.
Mr. Bright wishes to thank his clients and colleagues for their continued support of Brightech Property Inspections LLC.
###
Brightech Property Inspections LLC has been serving the Bridgton area for the past several years, specializing in through home inspections that educate and guide you in your home buying, selling or general building maintenance process.

]]><![CDATA[Dryer Vent Safety]]>Tue, 28 Apr 2015 18:35:32 GMThttp://brightechpropertyinspections.com/home-inspector-blog/dryer-vent-safety1Clothes dryers evaporate the water from wet clothing by blowing hot air past them while they tumble inside a spinning drum. Heat is provided by an electrical heating element or gas burner. Some heavy garment loads can contain more than a gallon of water which, during the drying process, will become airborne water vapor and leave the dryer and home through an exhaust duct (more commonly known as a dryer vent).

A vent that exhausts moist air to the home's exterior has a number of requirements:

It should be connected. The connection is usually behind the dryer but may be beneath it. Look carefully to make sure it’s actually connected.
It should not be restricted. Dryer vents are often made from flexible plastic or metal duct, which may be easily kinked or crushed where they exit the dryer and enter the wall or floor. This is often a problem since dryers tend to be tucked away into small areas with little room to work. Vent hardware is available which is designed to turn 90° in a limited space without restricting the flow of exhaust air. Restrictions should be noted in the inspector's report. Airflow restrictions are a potential fire hazard.
One of the reasons that restrictions are a potential fire hazard is that, along with water vapor evaporated out of wet clothes, the exhaust stream carries lint – highly flammable particles of clothing made of cotton and polyester. Lint can accumulate in an exhaust duct, reducing the dryer’s ability to expel heated water vapor, which then accumulates as heat energy within the machine. As the dryer overheats, mechanical failures can trigger sparks, which can cause lint trapped in the dryer vent to burst into flames. This condition can cause the whole house to burst into flames. Fires generally originate within the dryer but spread by escaping through the ventilation duct, incinerating trapped lint, and following its path into the building wall.

InterNACHI believes that house fires caused by dryers are far more common than are generally believed, a fact that can be appreciated upon reviewing statistics from the National Fire Protection Agency. Fires caused by dryers in 2005 were responsible for approximately 13,775 house fires, 418 injuries, 15 deaths, and $196 million in property damage. Most of these incidents occur in residences and are the result of improper lint cleanup and maintenance. Fortunately, these fires are very easy to prevent.

The recommendations outlined below reflect International Residential Code (IRC) SECTION M1502 CLOTHES DRYER EXHAUST guidelines:
M1502.5 Duct construction.
Exhaust ducts shall be constructed of minimum 0.016-inch-thick (0.4 mm) rigid metal ducts, having smooth interior surfaces, with joints running in the direction of air flow. Exhaust ducts shall not be connected with sheet-metal screws or fastening means which extend into the duct.

This means that the flexible, ribbed vents used in the past should no longer be used. They should be noted as a potential fire hazard if observed during an inspection.
M1502.6 Duct length.
The maximum length of a clothes dryer exhaust duct shall not exceed 25 feet (7,620 mm) from the dryer location to the wall or roof termination. The maximum length of the duct shall be reduced 2.5 feet (762 mm) for each 45-degree (0.8 rad) bend, and 5 feet (1,524 mm) for each 90-degree (1.6 rad) bend. The maximum length of the exhaust duct does not include the transition duct.
This means that vents should also be as straight as possible and cannot be longer than 25 feet. Any 90-degree turns in the vent reduce this 25-foot number by 5 feet, since these turns restrict airflow.

A couple of exceptions exist:

The IRC will defer to the manufacturer’s instruction, so if the manufacturer’s recommendation permits a longer exhaust vent, that’s acceptable. An inspector probably won’t have the manufacturer’s recommendations, and even if they do, confirming compliance with them exceeds the scope of a General Home Inspection.
The IRC will allow large radius bends to be installed to reduce restrictions at turns, but confirming compliance requires performing engineering calculation in accordance with the ASHRAE Fundamentals Handbook, which definitely lies beyond the scope of a General Home Inspection.

M1502.2 Duct termination.
Exhaust ducts shall terminate on the outside of the building or shall be in accordance with the dryer manufacturer’s installation instructions. Exhaust ducts shall terminate not less than 3 feet (914 mm) in any direction from openings into buildings. Exhaust duct terminations shall be equipped with a backdraft damper. Screens shall not be installed at the duct termination.

Inspectors will see many dryer vents terminate in crawlspaces or attics where they deposit moisture, which can encourage the growth of mold, wood decay, or other material problems. Sometimes they will terminate just beneath attic ventilators. This is a defective installation. They must terminate at the exterior and away from a door or window. Also, screens may be present at the duct termination and can accumulate lint and should be noted as improper.
M1502.3 Duct size.
The diameter of the exhaust duct shall be as required by the clothes dryer’s listing and the manufacturer’s installation instructions.
Look for the exhaust duct size on the data plate.
M1502.4 Transition ducts.
Transition ducts shall not be concealed within construction. Flexible transition ducts used to connect the dryer to the exhaust duct system shall be limited to single lengths not to exceed 8 feet (2438 mm), and shall be listed and labeled in accordance with UL 2158A.
In general, an inspector will not know specific manufacturer’s recommendations or local applicable codes and will not be able to confirm the dryer vent's compliance to them, but will be able to point out issues that may need to be corrected.]]><![CDATA[House Numbering ]]>Wed, 11 Mar 2015 11:04:27 GMThttp://brightechpropertyinspections.com/home-inspector-blog/house-numberingEver wonder about your house number? Often, the previous owner installed the number and the new owner never had to think about it, leaving them clueless as to why it was placed where it is or why a particular color or size was chosen. These numbers are more important than you probably realize, and a lot of thought goes into making sure they are visible.

House numbers should be clear enough so that police, the fire department, paramedics, etc., can quickly locate properties in an emergency. Numbers are often the only way that first-responders can identify their intended destinations. Your city might even have laws requiring your house number to be of a certain size or color. Also, think of the poor pizza delivery guy who runs late because he can’t find your house, or frustrated party guests who have to knock on neighbors’ doors before they find yours.

Consider the following recommendations:

The numbers should be large, within reason. Try to make them at least 5 or 6 inches tall. Smaller numbers may not be visible from the street if you have a large front yard. Replacement house numbers can be purchased from hardware stores and online.
The numbers should be of a color that contrasts with their background. Reflective numbers are great because they are easier to see at night. Brown on black or white on yellow may look swanky but are bad choices for the purpose.
Try not to put house numbers behind any trees, shrubs, or anything else that may obscure their view from the street.
Make sure that the number faces the street that is listed in the house’s address. It does emergency workers no good if the house number faces a different street than the one the workers are traveling on.
Is your house not visible from the road? Then the number should be placed at the driveway's entrance.
The next time you hire an InterNACHI inspector, ask him whether your numbers are adequate. Inspectors should know the laws in your area and be able to offer you a professional opinion.

Keep in mind that you may need to make adjustments.

Even if your house number is currently adequate, InterNACHI believes that it might need adjustment in the future. The following are common reasons why you may need to adjust your number in the future:

The addresses assigned to houses by the city occasionally change, and you must adjust your numbers accordingly.
The trees or shrubs in front of your house have grown so much that the number is no longer visible.
House numbers installed in the winter may be visible during that season, but become blocked by budding vegetation by spring or summer.

Maintain your house numbers, along with the rest of your home's exterior.

Keep your numbers clean. They may not be reflective or contrasting if they are covered in mud.
Trim back vegetation as needed.
Don’t let piles of snow obscure the numbers. If this happens, raise the number so this situation does not happen again.

In summary, house numbers serve a critical function for emergency personnel and should be clearly displayed.]]><![CDATA[Easy child safety tips: Get rid of cords, cover outlets]]>Tue, 10 Feb 2015 20:25:40 GMThttp://brightechpropertyinspections.com/home-inspector-blog/easy-child-safety-tips-get-rid-of-cords-cover-outletsNick Gromicko wants you and your children to be safe inside your home. Outside, too.

Gromicko of tiny Nederland, Colorado, is an activist for the home inspection industry -- those clipboard, measure-tape toting specialists who check out a property before you buy it. He is also the founder of InterNACHI, the International Association of Certified Home Inspectors, a trade association with more than 12,000 members.

In the "Safe Home" guide, he lists these suggestions for keeping babies and children safe, including tips from mini blinds cords to gates.

12 Safety Devices to Protect Your Children

Many hazards can be prevented by using simple child-safety devices. Any safety device you buy should be sturdy enough to prevent injury to your child, yet easy for you to use. It's important to follow installation instructions carefully.

If you have older children in the house, be sure they re-secure safety devices. Remember, too, that no device is completely childproof; determined youngsters have been known to disable them.

You can childproof your home for a fraction of what it would cost to have a professional do it. Safety devices are sold at hardware stores, baby equipment shops, supermarkets, drug stores, home and linen stores, and through online and mail-order catalogs.

Here are some child-safety devices that can help prevent many injuries to young children:

Use safety latches and locks for cabinets and drawers in kitchens, bathrooms and other areas to help prevent poisonings and other injuries. Safety latches and locks on cabinets and drawers can help prevent children from gaining access to medicines and household cleaners, as well as knives and other sharp objects.

Look for safety latches and locks that adults can easily install and use, but that are sturdy enough to withstand pulls and tugs from children. Safety latches are not a guarantee of protection, but they can make it more difficult for children to reach dangerous substances. Even products with child-resistant packaging should be locked away out of reach; this packaging is not childproof.

According to the International Association for Child Safety (IAFCS), which maintains a childproofing blog, "Installing an ineffective latch on a cabinet is not an answer for helping parents with safety. It is important to understand parental habits and behavior. While a latch that loops around cabinet knob covers is not expensive and easy to install, most parents do not consistently re-latch it."

Parents should be sure to purchase and install safety products that they will actually adapt to and use.

Use safety gates to help prevent falls down stairs and to keep children away from dangerous areas. Look for safety gates that children cannot dislodge easily, but that adults can open and close without difficulty. For the top of stairs, gates that screw into the wall are more secure than "pressure gates."

New safety gates that meet safety standards display a certification seal from the Juvenile Products Manufacturers Association (JPMA). If you have an older safety gate, be sure it doesn't have "V" shapes that are large enough for a child's head and neck to fit into.

Use door locks to help prevent children from entering rooms and other areas with possible dangers, including swimming pools.

To prevent access to swimming pools, door locks on safety gates should be placed high, out of reach of young children. Locks should be used in addition to fences and alarms. Sliding glass doors with locks that must be re-secured after each use are often not an effective barrier to pool access.

Door knob covers, while inexpensive and recommended by some, are generally not effective for children who are tall enough to reach the doorknob; a child's ingenuity and persistence can usually trump the cover's effectiveness.

Use anti-scald devices for faucets and showerheads, and set your water heater temperature to 120 degrees to help prevent burns from hot water. A plumber may need to install these.

Use smoke detectors on every level of your home and near bedrooms to alert you to fires. Smoke detectors are essential safety devices for protection against fire deaths and injuries. Check them once a month to make sure they're working. If the detectors are battery-operated, replace the batteries at least once a year, or consider using 10-year batteries.

Use window guards and safety netting to help prevent falls from windows, balconies, decks and landings. Check these safety devices frequently to make sure they are properly installed, secure and maintained. There should be no more than 4 inches between the bars of the window guard.

If you have window guards, be sure at least one window in each room can be easily used for escape in case of a fire. Window screens are not effective for preventing children from falling out of windows.

Use corner and edge bumpers to help prevent injuries from falls against the sharp edges of furniture and fireplace hearths. Be sure to look for bumpers that stay securely attached.

The Guardian Angel Outlet is available for $20 on Amazon.com or GuardianAngelSafety.com
Use receptacle or outlet covers and plates to help prevent electrical shocks and possible electrocution. Be sure the outlet protectors cannot be easily removed by children and are large enough so that children cannot choke on them if they do manage to remove them.

Use a carbon monoxide (CO) detector outside bedrooms to help prevent CO poisoning. Consumers should install CO detectors near sleeping areas in their homes. Households that should use CO detectors include those with gas or oil heat and those with attached garages.

Cut window blind cords to help prevent children from strangling in blind-cord loops. Window blind cord safety tassels on miniblinds and tension devices on vertical blinds and drapery cords can help prevent deaths and injuries from strangulation in the loops of the cords. Inner cord stops can help prevent strangulation in the inner cords of window blinds.

Cordless is best, according to the IAFCS.

For older miniblinds, cut the cord loop, remove the buckle, and put safety tassels on each cord. Be sure that older vertical blinds and drapery cords have tension or tie-down devices to hold the cords tight. When buying new miniblinds, vertical blinds and draperies, ask for safety features to prevent child strangulation.

Use door stops and door holders to help prevent injuries to fingers and hands. Door stops and door holders on doors and door hinges can help prevent small fingers and hands from being pinched or crushed in doors and door hinges.
Be sure any safety device for doors is easy to use and not likely to break into small parts, which could be a choking hazard for young children.

Use a cell or cordless phone to make it easier to continuously watch young children, especially when they're in bathtubs, swimming pools, or other potentially dangerous areas. Cordless phones help you watch your child without leaving the vicinity to answer a phone call. Cordless phones are especially helpful when children are in or near water, whether it's in the bathtub, the swimming pool or at the beach.

http://www.oregonlive.com/hg/index.ssf/2015/02/easy_child_safety_tips.html#incart_river]]><![CDATA[Maine Home Inspection Reports: What to Expect]]>Mon, 29 Dec 2014 18:25:02 GMThttp://brightechpropertyinspections.com/home-inspector-blog/maine-home-inspection-reports-what-to-expectInfluenced by the changes in the economic and legal environments over the past 30 years, home inspection reports have changed to accommodate increased consumer expectations, and to provide more extensive information and protection to both inspectors and their clients.

Development of Standards

Prior to the mid-1970s, inspection reports followed no standard guidelines and, for the most part, there was little or no oversight or licensure. As might be imagined, without minimum standards to follow, the quality of inspection reports varied widely, and the home inspection industry was viewed with some suspicion.

With the founding of the American Society of Home Inspectors (ASHI) in 1976, home inspection guidelines governing inspection report content became available in the form of a Standards of Practice. Over time, a second, larger trade association, the International Association of Certified Home Inspectors (InterNACHI), came into existence, and developed its own standards.

InterNACHI has grown to dominate the inspection industry and, in addition to its Residential Standards of Practice, it has developed a comprehensive Standards of Practice for the Inspection of Commercial Properties. Today, most types of inspections from mold to fire door inspections are performed in accordance with one of InterNACHI's Standards of Practice.

As a consumer, you should take the time to examine the Standards of Practice followed by your inspector. If he is unaffiliated with any professional inspection organization, and his reports follow no particular standards, find another inspector.

Generally speaking, reports should describe the major home systems, their crucial components, and their operability, especially the ones in which failure can result in dangerous or expensive-to-correct conditions. Defects should be adequately described, and the report should include recommendations.

Reports should also disclaim portions of the home not inspected. Since home inspections are visual inspections, the parts of the home hidden behind floor, wall and ceiling coverings should be disclaimed.

Home inspectors are not experts in every system of the home, but are trained to recognize conditions that require a specialist inspection.

Home inspections are not technically exhaustive, so the inspector will not disassemble a furnace to examine the heat exchanger closely, for example.

Standards of Practice are designed to identify both the requirements of a home inspection and the limitations of an inspection.

Checklist and Narrative Reports

In the early years of the home inspection industry, home inspection reports consisted of a simple checklist, or a one- or two-page narrative report.

Checklist reports are just that; very little is actually written. The report is a series of boxes with short descriptions after them. Descriptions are often abbreviated, and might consist of only two or three words, such as “peeling paint.” The entire checklist might only be four or five pages long. Today, some inspection legal agreements are almost that long!

Because of the lack of detailed information, checklist reports leave a lot open to interpretation, so that buyers, sellers, agents, contractors, attorneys and judges may each interpret the information differently, depending on their motives.

In the inspection business, phrases that describe conditions found during an inspection are called "narratives." Narrative reports use reporting language that more completely describes each condition. Descriptions are not abbreviated.

Both checklist and narrative reports are still in use today, although many jurisdictions are now beginning to ban checklist reports because the limited information they offer has resulted in legal problems.

From the standpoint of liability, narrative reports are widely considered safer, since they provide more information and state it more clearly.

Many liability issues and problems with the inspection process are due to misunderstandings about what was to be included in the report, or about what the report says.

For example, in 2002, an investor bought a 14-unit hotel in California. The six-page narrative report mentioned that flashing where the second-story concrete walkway met the building was improperly installed, and the condition could result in wood decay. Four years later, the investor paid out almost $100,000 to demolish and replace the entire upper walkway. In some places, it was possible to push a pencil through support beams.

Although the inspector's report had mentioned the problem, it hadn't made clear the seriousness of the condition, or the possible consequences of ignoring it. Today, a six-page report would be considered short for a small house.
Development of Reporting Software

Years ago, when computers were expensive to buy and difficult to operate, inspection reports were written by hand. As computers became simpler to operate and more affordable, inspection software began to appear on the market.

Today, using this software, an inspector can chose from a large number of organized boilerplate narratives that s/he can edit or add to in order to accommodate local conditions, since inspectors in a hot, humid city like Tampa Bay, Florida, are likely to find types of problems different from those found by inspectors in a cold, dry climate, like Salt Lake City, Utah.

Using narrative software and checking boxes in categories that represent the home systems, an inspector can produce a very detailed report in a relatively short time.

For example, using a checklist report, an inspector finding a number of inoperable lights in a home would check a box in the "INTERIOR" section labeled something like “some lights inoperable,” and that would be the limit of the information passed on to the client.

Using inspection software, in the "INTERIOR" section of the program, an inspector might check a box labeled “some lights inoperable.” This would cause the following narrative to appear in the "INTERIOR" section of the inspection report:

“Some light fixtures in the home appeared to be inoperable. The bulbs may be burned out, or a problem may exist with the fixtures, wiring or switches.

If after the bulbs are replaced, these lights still fail to respond to the switch, this condition may represent a potential fire hazard, and the Inspector recommends that an evaluation and any necessary repairs be performed by a qualified electrical contractor.”
Standard disclaimers and other information can be pre-checked to automatically appear in each report.

Narrative Content

Narratives typically consists of three parts:

a description of a condition of concern;
a sentence or paragraph describing how serious the condition is, and the potential ramifications, answering questions such as, “Is it now stable, or will the problem continue?” or “Will it burn down the house?" and “When?”; and
a recommendation. Recommendations may be for specific actions to be taken, or for further evaluation, but they should address problems in such a way that the reader of the report will understand how to proceed.

“Typically” is a key word here. Some narratives may simply give the ampacity of the main electrical disconnect. There is no need for more than one sentence. Different inspectors would include what they think is necessary.

Report Content

Inspection reports often begin with an informational section which gives general information about the home, such as the client’s name, the square footage, and the year the home was built.

Other information often listed outside the main body of the report, either near the beginning or near the end, are disclaimers, and sometimes a copy of the inspection agreement, and sometimes a copy of the Standards of Practice. A page showing the inspector’s professional credentials, designations, affiliations and memberships is also often included. And it is a good idea to include InterNACHI's Now That You've Had a Home Inspection book.

Inspection reports often include a summary report listing major problems to ensure that important issues are not missed by the reader. It's important that the reader be aware of safety issues or conditions which will be expensive to correct. With this in mind, some inspectors color-code report narratives, although many feel that color-coding exposes them to increased liability and don't do this.

Software often gives inspectors the choice of including photographs in the main body of the report, near the narrative that describes them, or photographs may be grouped together toward the beginning or end of the report.

A table of contents is usually provided.

The main body of the report may be broken down into sections according to home systems, such as "ELECTRICAL," "PLUMBING," "HEATING," etc., or it may be broken down by area of the home: "EXTERIOR," "INTERIOR," "KITCHEN," "BEDROOMS," etc.

It often depends on how the inspector likes to work.

Sample Reports

Many inspectors have websites which include sample inspection reports for prospective clients to view. Take the time to look at them. Also often included is a page explaining the scope of the inspection. The inspection contract is usually included on the website, and it should give you a good idea of what will be included in the report.

In conclusion, for consumers to have realistic expectations about what information will be included in the home inspection report, follow these tips:

read the Standards of Practice;
read the Contract;
view a sample Inspection Report; and
talk with the inspector.

]]><![CDATA[Holiday Home Safety Tips]]>Tue, 09 Dec 2014 19:42:19 GMThttp://brightechpropertyinspections.com/home-inspector-blog/holiday-home-safety-tipsThe winter holidays are a time for celebration, and that means more cooking, home decorating, entertaining, and an increased risk of fire and accidents. InterNACHI recommends that you follow these guidelines to help make your holiday season safer and more enjoyable.

Holiday Lighting

Use caution with holiday decorations and, whenever possible, choose those made with flame-resistant, flame-retardant and non-combustible materials.
Keep candles away from decorations and other combustible materials, and do not use candles to decorate Christmas trees.
Carefully inspect new and previously used light strings, and replace damaged items before plugging lights in. If you have any questions about electrical safety, ask an InterNACHI inspector during your next scheduled inspection. Do not overload extension cords.
Don't mount lights in any way that can damage the cord's wire insulation. To hold lights in place, string them through hooks or insulated staples--don't use nails or tacks. Never pull or tug lights to remove them.
Keep children and pets away from light strings and electrical decorations.
Never use electric lights on a metallic tree. The tree can become charged with electricity from faulty lights, and a person touching a branch could be electrocuted.
Before using lights outdoors, check labels to be sure they have been certified for outdoor use.
Make sure all the bulbs work and that there are no frayed wires, broken sockets or loose connections.
Plug all outdoor electric decorations into circuits with ground-fault circuit interrupters to avoid potential shocks.
Turn off all lights when you go to bed or leave the house. The lights could short out and start a fire.

Decorations

Use only non-combustible and flame-resistant materials to trim a tree. Choose tinsel and artificial icicles of plastic and non-leaded metals.
Never use lighted candles on a tree or near other evergreens. Always use non-flammable holders, and place candles where they will not be knocked down.
In homes with small children, take special care to avoid decorations that are sharp and breakable, and keep trimmings with small removable parts out of the reach of children.
Avoid trimmings that resemble candy and food that may tempt a young child to put them in his mouth.

Holiday Entertaining

Unattended cooking is the leading cause of home fires in the U.S. When cooking for holiday visitors, remember to keep an eye on the range.
Provide plenty of large, deep ashtrays, and check them frequently. Cigarette butts can smolder in the trash and cause a fire, so completely douse cigarette butts with water before discarding.
Keep matches and lighters up high, out of sight and reach of children (preferably in a locked cabinet).
Test your smoke alarms, and let guests know what your fire escape plan is.

Trees

When purchasing an artificial tree, look for the label "fire-resistant."
When purchasing a live tree, check for freshness. A fresh tree is green, needles are hard to pull from branches, and when bent between your fingers, needles do not break.
When setting up a tree at home, place it away from fireplaces, radiators and portable heaters. Place the tree out of the way of traffic and do not block doorways.
Cut a few inches off the trunk of your tree to expose the fresh wood. This allows for better water absorption and will help to keep your tree from drying out and becoming a fire hazard.
Be sure to keep the stand filled with water, because heated rooms can dry live trees out rapidly.
Make sure the base is steady so the tree won't tip over easily.

Fireplaces

Before lighting any fire, remove all greens, boughs, papers and other decorations from fireplace area. Check to see that the flue is open.
Use care with "fire salts," which produce colored flames when thrown on wood fires. They contain heavy metals that can cause intense gastrointestinal irritation and vomiting if eaten.
Do not burn wrapping papers in the fireplace. A flash fire may result as wrappings ignite suddenly and burn intensely.

Toys and Ornaments

Purchase appropriate toys for the appropriate age. Some toys designed for older children might be dangerous for younger children.
Electric toys should be UL/FM approved.
Toys with sharp points, sharp edges, strings, cords, and parts small enough to be swallowed should not be given to small children.
Place older ornaments and decorations that might be painted with lead paint out of the reach of small children and pets.

Children and Pets

Poinsettias are known to be poisonous to humans and animals, so keep them well out of reach, or avoid having them.
Keep decorations at least 6 inches above the child’s reach.
Avoid using tinsel. It can fall on the floor and a curious child or pet may eat it. This can cause anything from mild distress to death.
Keep any ribbons on gifts and tree ornaments shorter than 7 inches. A child could wrap a longer strand of ribbon around their neck and choke.
Avoid mittens with strings for children. The string can get tangled around the child’s neck and cause them to choke. It is easier to replace a mitten than a child.
Watch children and pets around space heaters or the fireplace. Do not leave a child or pet unattended.
Store scissors and any sharp objects that you use to wrap presents out of your child’s reach.
Inspect wrapped gifts for small decorations, such as candy canes, gingerbread men, and mistletoe berries, all of which are choking hazards.

Security

Use your home burglar alarm system.
If you plan to travel for the holidays, don’t discuss your plans with strangers.
Have a trusted friend or neighbor to keep an eye on your home.

]]><![CDATA[Private Water Wells]]>Wed, 19 Nov 2014 18:05:27 GMThttp://brightechpropertyinspections.com/home-inspector-blog/private-water-wellsIf your family gets drinking water from a private well, do you know if your water is safe to drink? What health risks could you and your family face? Where can you go for help or advice? The EPA regulates public water systems; it does not have the authority to regulate private drinking water wells. Approximately 15% of Americans rely on their own private drinking water supplies, and these supplies are not subject to EPA standards, although some state and local governments do set rules to protect users of these wells. Unlike public drinking water systems serving many people, they do not have experts regularly checking the water’s source and its quality before it is sent to the tap. These households must take special precautions to ensure the protection and maintenance of their drinking water supplies.

Basic Information

There are three types of private drinking water wells: dug, driven, and drilled. Proper well construction and continued maintenance are keys to the safety of your water supply. Your state water-well contractor licensing agency, local health department, or local water system professional can provide information on well construction. The well should be located so rainwater flows away from it. Rainwater can pick up harmful bacteria and chemicals on the land’s surface. If this water pools near your well, it can seep into it, potentially causing health problems. Water-well drillers and pump-well installers are listed in your local phone directory. The contractor should be bonded and insured. Make certain your ground water contractor is registered or licensed in your state, if required. If your state does not have a licensing/registration program, contact the National Ground Water Association.
To keep your well safe, you must be sure that possible sources of contamination are not close by. Experts suggest the following distances as a minimum for protection — farther is better(see graphic on the right):

septic tanks: 50 feet;
livestock yards, silos, septic leach fields: 50 feet;
petroleum tanks, liquid-tight manure storage and fertilizer storage and handling: 100 feet; and
manure stacks: 250 feet.

Many homeowners tend to forget the value of good maintenance until problems reach crisis-levels. That can be expensive. It’s better to maintain your well, find problems early, and correct them to protect your well’s performance. Keep up-to-date records of well installation and repairs, plus pumping and water tests. Such records can help spot changes and possible problems with your water system. If you have problems, ask a local expert to check your well construction and maintenance records. He or she can see if your system is okay or needs work.

Protect your own well area. Be careful about storage and disposal of household and lawn-care chemicals and wastes. Good farmers and gardeners minimize the use of fertilizers and pesticides. Take steps to reduce erosion and prevent surface water runoff. Regularly check underground storage tanks that hold home heating oil, diesel, or gasoline. Make sure your well is protected from the wastes of livestock, pets and wildlife.

Dug Wells

Dug wells are holes in the ground dug by shovel or backhoe. Historically, a dug well was excavated below the ground water table until incoming water exceeded the digger’s bailing rate. The well was then lined (cased) with stones, brick, tile, or other material to prevent collapse. It was covered with a cap of wood, stone or concrete. Since it is so difficult to dig beneath the ground water table, dug wells are not very deep. Typically, they are only 10 to 30 feet deep. Being so shallow, dug wells have the highest risk of becoming contaminated.To minimize the likelihood of contamination, your dug well should have certain features. These features help to prevent contaminants from traveling along the outside of the casing, or through the casing and into the well.

Dug Well Construction Features

The well should be cased with a watertight material (for example, tongue-and-groove pre-cast concrete), and a cement grout or bentonite clay sealant poured along the outside of the casing to the top of the well.
The well should be covered by a concrete curb and cap that stands about a foot above the ground.
The land surface around the well should be mounded so that surface water runs away from the well and is not allowed to pond around the outside of the wellhead.
Ideally, the pump for your well should be inside your home or in a separate pump house, rather than in a pit next to the well.

Land activities around a dug well can also contaminate it. While dug wells have been used as a household water supply source for many years, most are relics of older homes, dug before drilling equipment was readily available, or when drilling was considered too expensive. If you have a dug well on your property and are using it for drinking water, check to make sure it is properly covered and sealed. Another problem relating to the shallowness of a dug well is that it may go dry during a drought when the ground water table drops.

Driven Wells

Like dug wells, driven wells pull water from the water-saturated zone above the bedrock. Driven wells can be deeper than dug wells. They are typically 30 to 50 feet deep and are usually located in areas with thick sand and gravel deposits where the ground water table is within 15 feet of the ground’s surface. In the proper geologic setting, driven wells can be easy and relatively inexpensive to install. Although deeper than dug wells, driven wells are still relatively shallow and have a moderate-to-high risk of contamination from nearby land activities.
Driven Well Construction Features

Assembled lengths of 2- to 3-inch diameter metal pipes are driven into the ground. A screened “well point” located at the end of the pipe helps drive the pipe through the sand and gravel. The screen allows water to enter the well and filters out sediment.
The pump for the well is in one of two places: on top of the well, or in the house. An access pit is usually dug around the well down to the frost line, and a water discharge pipe to the house is joined to the well pipe with a fitting.
The well and pit are capped with the same kind of large-diameter concrete tile used for a dug well. The access pit may be cased with pre-cast concrete.

To minimize this risk, the well cover should be a tight-fitting concrete curb and cap with no cracks, and should sit about a foot above the ground. Slope the ground away from the well so that surface water will not pond around the well. If there’s a pit above the well, either to hold the pump or to access the fitting, you may also be able to pour a grout sealant along the outside of the well pipe. Protecting the water quality requires that you maintain proper well construction and monitor your activities around the well. It is also important to follow the same land-use precautions around the driven well as described under dug wells.

Drilled Wells

Drilled wells penetrate about 100 to 400 feet into the bedrock. Where you find bedrock at the surface, it is commonly called ledge. To serve as a water supply, a drilled well must intersect bedrock fractures containing ground water.

Drilled Well Construction Features

The casing is usually metal or plastic pipe, 6 inches in diameter, that extends into the bedrock to prevent shallow ground water from entering the well. By law, the casing has to extend at least 18 feet into the ground, with at least 5 feet extending into the bedrock. The casing should also extend a foot or two above the ground’s surface. A sealant, such as cement grout or bentonite clay, should be poured along the outside of the casing to the top of the well. The well should be capped to prevent surface water from entering the well.
Submersible pumps, located near the bottom of the well, are most commonly used in drilled wells. Wells with a shallow water table may feature a jet pump located inside the home. Pumps require special wiring and electrical service. Well pumps should be installed and serviced by a qualified professional registered with your state.
Most modern drilled wells incorporate a pitless adapter designed to provide a sanitary seal at the point where the discharge water line leaves the well to enter your home. The device attaches directly to the casing below the frost line, and provides a watertight sub-surface connection, protecting the well from frost and contamination.
Older drilled wells may lack some of these sanitary features. The well pipe used was often 8, 10 or 12 inches in diameter, and covered with a concrete well cap either at or below the ground’s surface. This outmoded type of construction does not provide the same degree of protection from surface contamination. Also, older wells may not have a pitless adapter to provide a seal at the point of discharge from the well.

Hydrofracting a Drilled WellHydrofracting is a process that applies water or air under pressure into your well to open up existing fractures near your well, and can even create new ones. Often, this can increase the yield of your well. This process can be applied to new wells with insufficient yield and to improve the quantity of older wells.

How can I test the quality of my private drinking water supply?
Consider testing your well for pesticides, organic chemicals, and heavy metals before you use it for the first time. Test private water supplies annually for nitrate and coliform bacteria to detect contamination problems early. Test them more frequently if you suspect a problem. Be aware of activities in your watershed that may affect the water quality of your well, especially if you live in an unsewered area.

Human Health

The first step to protect your health and the health of your family is learning about what may pollute your source of drinking water. Potential contamination may occur naturally, or as a result of human activity.

What are some naturally occurring sources of pollution?

micro-organisms: Bacteria, viruses, parasites and other microorganisms are sometimes found in water. Shallow wells — those with water close to ground level — are at most risk. Runoff, or water flowing over the land surface, may pick up these pollutants from wildlife and soils. This is often the case after flooding. Some of these organisms can cause a variety of illnesses. Symptoms include nausea and diarrhea. These can occur shortly after drinking contaminated water. The effects could be short-term yet severe (similar to food poisoning), or might recur frequently or develop slowly over a long time.
radionuclides: Radionuclides are radioactive elements, such as uranium and radium. They may be present in underlying rock and ground water.
radon: Radon is a gas that is a natural product of the breakdown of uranium in the soil and can also pose a threat. Radon is most dangerous when inhaled, and contributes to lung cancer. Although soil is the primary source, using household water containing radon contributes to elevated indoor radon levels. Radon is less dangerous when consumed in water, but remains a risk to health.
nitrates and nitrites: Although high nitrate levels are usually due to human activities (see below), they may be found naturally in ground water. They come from the breakdown of nitrogen compounds in the soil. Flowing ground water picks them up from the soil. Drinking large amounts of nitrates and nitrites is particularly threatening to infants (for example, when mixed in formula).
heavy metals: Underground rocks and soils may contain arsenic, cadmium, chromium, lead, and selenium. However, these contaminants are not often found in household wells at dangerous levels from natural sources.
fluoride: Fluoride is helpful in dental health, so many water systems add small amounts to drinking water. However, excessive consumption of naturally occurring fluoride can damage bone tissue. High levels of fluoride occur naturally in some areas. It may discolor teeth, but this is not a health risk.

What human activities can pollute ground water?

Septic tanks are designed to have a leach field around them, which is an area where wastewater flows out of the tank. This wastewater can also move into the ground water.

bacteria and nitrates: These pollutants are found in human and animal wastes. Septic tanks can cause bacterial and nitrate pollution. So can large numbers of farm animals. Both septic systems and animal manure must be carefully managed to prevent pollution. Sanitary landfills and garbage dumps are also sources. Children and some adults are at higher risk when exposed to waterborne bacteria. These include the elderly and people whose immune systems are weak due to AIDS or treatments for cancer. Fertilizers can add to nitrate problems. Nitrates cause a health threat in very young infants called “blue baby syndrome." This condition disrupts oxygen flow in the blood.
concentrated animal feeding operations (CAFOs): The number of CAFOs, often called “factory farms,” is growing. On these farms, thousands of animals are raised in a small space. The large amounts of animal waste/manure from these farms can threaten water supplies. Strict and careful manure management is needed to prevent pathogen and nutrient problems. Salts from high levels of manure can also pollute ground water.
heavy metals: Activities such as mining and construction can release large amounts of heavy metals into nearby ground water sources. Some older fruit orchards may contain high levels of arsenic, once used as a pesticide. At high levels, these metals pose a health risk.
fertilizers and pesticides: Farmers use fertilizers and pesticides to promote growth and reduce insect damage. These products are also used on golf courses and suburban lawns and gardens. The chemicals in these products may end up in ground water. Such pollution depends on the types and amounts of chemicals used and how they are applied. Local environmental conditions (soil types, seasonal snow and rainfall) also affect this pollution. Many fertilizers contain forms of nitrogen that can break down into harmful nitrates. This could add to other sources of nitrates mentioned above. Some underground agricultural drainage systems collect fertilizers and pesticides. This polluted water can pose problems to ground water and local streams and rivers. In addition, chemicals used to treat buildings and homes for termites and other pests may also pose a threat. Again, the possibility of problems depends on the amount and kind of chemicals. The types of soil and the amount of water moving through the soil also play a role.
industrial products and waste: Many harmful chemicals are used widely in local business and industry. These can pollute drinking water if not well-managed. The most common sources of such problems are:
- local businesses: These include nearby factories, industrial plants, and even small businesses such as gas stations and dry cleaners. All handle a variety of hazardous chemicals that need careful management. Spills and improper disposal of these chemicals and other industrial wastes can threaten ground water supplies.
- leaking underground tanks and piping: Petroleum products, chemicals and waste stored in underground storage tanks and pipes may end up in the ground water. Tanks and piping leak if they are constructed or installed improperly. Steel tanks and piping corrode with age. Tanks are often found on farms. The possibility of leaking tanks is great on old, abandoned farm sites. Farm tanks are exempt from the EPA rules for petroleum and chemical tanks.
- landfills and waste dumps: Modern landfills are designed to contain any leaking liquids. But floods can carry them over the barriers. Older dumpsites may have a wide variety of pollutants that can seep into ground water.
household waste: Improper disposal of many common products can pollute ground water. These include cleaning solvents, used motor oil, paints, and paint thinners. Even soaps and detergents can harm drinking water. These are often a problem from faulty septic tanks and septic leaching fields.
lead and copper: Household plumbing materials are the most common source of lead and copper found in home drinking water. Corrosive water may cause metals in pipes or soldered joints to leach into your tap water. Your water’s acidity or alkalinity (often measured as pH) greatly affects corrosion. Temperature and mineral content also affect how corrosive it is. They are often used in pipes, solder and plumbing fixtures. Lead can cause serious damage to the brain, kidneys, nervous system, and red blood cells. The age of plumbing materials — in particular, copper pipes soldered with lead — is also important. Even in relatively low amounts, these metals can be harmful. The EPA rules under the Safe Drinking Water Act limit lead in drinking water to 15 parts per billion. Since 1988, the Act allows only lead-free pipe, solder and flux in drinking water systems. The law covers both new installations and repairs of plumbing.

What You Can Do...
Private, individual wells are the responsibility of the homeowner. To help protect your well, here are some steps you can take:

Have your water tested periodically. It is recommended that water be tested every year for total coliform bacteria, nitrates, total dissolved solids, and pH levels. If you suspect other contaminants, test for those. Always use a state-certified laboratory that conducts drinking water tests. Since these can be expensive, spend some time identifying potential problems. Consult your InterNACHI inspector for information about how to go about water testing.

Testing more than once a year may be warranted in special situations if:

someone in your household is pregnant or nursing;
there are unexplained illnesses in the family;
your neighbors find a dangerous contaminant in their water;
you note a change in your water's taste, odor, color or clarity;
there is a spill of chemicals or fuels into or near your well; or
you replace or repair any part of your well system.

Identify potential problems as the first step to safe-guarding your drinking water. The best way to start is to consult a local expert -- someone who knows your area, such as the local health department, agricultural extension agent, a nearby public water system, or a geologist at a local university.

Be aware of your surroundings. As you drive around your community, take note of new construction. Check the local newspaper for articles about new construction in your area.

Check the paper or call your local planning and zoning commission for announcements about hearings or zoning appeals on development or industrial projects that could possibly affect your water.

Attend these hearings, ask questions about how your water source is being protected, and don't be satisfied with general answers. Ask questions, such as: "If you build this landfill, what will you do to ensure that my water will be protected?" See how quickly they answer and provide specifics about what plans have been made to specifically address that issue.

Identify Potential Problem SourcesTo start your search for potential problems, begin close to home. Do a survey around your well to discover:

Is there livestock nearby?
Are pesticides being used on nearby agricultural crops or nurseries?
Do you use lawn fertilizers near the well?
Is your well downstream from your own or a neighbor's septic system?
Is your well located near a road that is frequently salted or sprayed with de-icers during winter months?
Do you or your neighbors dispose of household waste or used motor oil in the backyard, even in small amounts?

If any of these items apply, it may be best to have your water tested and talk to your local public health department or agricultural extension agent to find ways to change some of the practices which can affect your private well.

In addition to the immediate area around your well, you should be aware of other possible sources of contamination that may already be part of your community or may be moving into your area. Attend any local planning or appeals hearings to find out more about the construction of facilities that may pollute your drinking water. Ask to see the environmental impact statement on the project. See if the issue of underground drinking water sources has been addressed. If not, ask why.
Common Sources of Ground Water ContaminationCategory Contaminant SourceAgricultural

animal burial areas
drainage fields/wells
animal feedlots
irrigation sites
fertilizer storage/use
manure spreading areas/pits, lagoons
pesticide storage/use

Commercial

airports
jewelry/metal plating
auto repair shops
laundromats
boat yards
medical institutions
car washes
paint shops
construction areas
photography establishments
cemeteries
process waste-water drainage
dry cleaners fields/wells
gas stations
railroad tracks and yards
golf courses
research laboratories
scrap and junkyards
storage tanks

Industrial

asphalt plants
petroleum production/storage
chemical manufacture/storage
pipelines
electronic manufacture
process waste-water drainage
electroplaters fields/wells
foundries/metal fabricators
septage lagoons and sludge
machine/metalworking shops
storage tanks
mining and mine drainage
toxic and hazardous spills
wood-preserving facilities

Residential

fuel oil
septic systems, cesspools
furniture stripping/refinishing
sewer lines
household hazardous products
swimming pools (chemicals)
household lawns

Other

hazardous waste landfills
recycling/reduction facilities
municipal incinerators
road de-icing operations
municipal landfills
road maintenance depots
municipal sewer lines
Storm water drains/basins/wells
open burning sites
transfer stations

]]><![CDATA[Lightning]]>Thu, 14 Aug 2014 01:40:40 GMThttp://brightechpropertyinspections.com/home-inspector-blog/lightningLightning is the "visible discharge of static electricity within a cloud, between clouds or between the earth and a cloud," as defined by Underwriters Laboratories. Lightning is unpredictable and a serious threat to buildings and their occupants virtually everywhere.

Facts about lightning:

Benjamin Franklin invented the first lightning rod in 1752 –- a kite outfitted with a metal key -- while waiting impatiently for the completion of a church on top of which he would mount a lightning rod.
Lightning comes up from the earth –- as well as down from the cloud -- from high vertical features such as chimneys and trees.
A typical lightning bolt carries 50,000 amps, tens of millions of volts, and can reach 50,000° F. “Superbolts” may be 100 times more powerful than typical bolts, and travel much farther, too; one such superbolt went from Waco to Dallas, Texas, after having traveled about 118 miles.
According to the National Weather Service, of the 34 people killed by lightning in the United States in 2009, all were outside when they were struck. Thus, homes provide a great deal of safety against lightning strikes. Interestingly, the same report indicates that 82% of lightning casualties were male.
Permanent injuries caused by lightning strikes are predominantly neurological and can include sleep disorders, attention deficits, numbness, dizziness, irritability, fatigue, depression, and an inability to sit for long periods of time.
Between 2002 and 2005, lightning caused an annual average of $213 million in property damage.

Types of dangers from lightning to houses and occupants:

damaged appliances from power surges;
electrocution risk for occupants;
fire risk to the building and occupants;
damage to the structure from water used to douse the fire by the fire department; and
damage to the structure and endangered health from mold colonies, if the building was not dried quickly following fire suppression.

Corrugated Stainless Steel Tubing (CSST)

CSST is a relatively new type of gas tubing that has been widely installed in houses and in commercial applications in recent years. Its small diameter makes it flexible and relatively easy to install when compared with traditional, rigid, heavy-walled pipes, although this same quality is believed to make it susceptible to fire due to lightning strikes. Lightning that travels down the CSST can burn holes in the tubing and allow gas leakage and fire. In the worst cases, gas leaks have led to disastrous gas explosions. CSST has been found to be susceptible to damage from direct and even nearby lightning strikes.

These claims have lead to a class-action lawsuit against manufacturers of CCST (Titeflex, Ward, OmegaFlex and Parker Hannifin) installed in homes as of September 5, 2006. Plaintiffs claim that the CSST tubing is not thick enough to prevent becoming damaged in the event of a lightning strike, and that CSST manufacturers failed to warn consumers about such dangers. The defendants claim that CSST is safe if properly installed, in accordance with local codes and the manufacturers’ instructions. According to the Lightning Protection Institute, dangerous CSST has been installed in more than a million homes in the United States.

Identification of CSST

Typically, these products may be visible in attic spaces, along floor joists, above basements, or connected to exposed appliances, such as water heaters. The piping can be identified by its manufacturer’s mark, each of which are listed below:

OmegaFlex's CSST is stamped with the marks “TRACPIPE” or “COUNTERSTRIKE.”
Parker Hannifin's CSST is stamped with the mark “PARFLEX.”
Titeflex's CSST is stamped with the mark “GASTITE.”
Ward's CSST is stamped with the mark “WARDFLEX.”

Additional bonding to ground is recommended for houses with CSST.

Safety tips for clients during thunderstorms:

Unplug sensitive appliances, such as computers and telephones, from electrical outlets and phone lines. Surge protectors are helpful, but they should not be relied upon during a storm.
Stay off corded phones, computers, and other electronic equipment that put you in direct contact with electricity. If you are unable to unplug them, turn them off. Lightning may strike nearby electric or phone lines and enter your home.
Unplug other appliances, such as air conditioners.
Stay away from windows.
Avoid washing your hands, bathing, doing laundry, and washing dishes -- activities that put you in direct contact with running water.

Lightning Protection Systems

Lightning protection systems are devices intended to divert lightning into low-resistance paths to or from the earth and away from non-conducting parts of a structure. For specific inspection instructions regarding these systems, see the National Fire Protection Agency’s NFPA-780.

Lightning Rods
Metal rods are fastened to the building to intercept electric discharges that might otherwise strike a building component itself, such as a chimney or metal roof. Electrical discharges striking the air terminal are directed through metal conductors to a grounding system and thence into the earth.

Controversy has existed for centuries concerning whether lightning rods should have blunt or sharp tips. Recent studies have found that moderately blunt metal rods are better lightning-strike receptors than sharper rods or very blunt rods.

In summary, lightning can be very dangerous to homes and occupants, although devices and measures exist to limit this danger.]]><![CDATA[Electrical Safety]]>Tue, 29 Jul 2014 09:02:13 GMThttp://brightechpropertyinspections.com/home-inspector-blog/electrical-safetyElectricity is an essential part of our lives. However, it has the potential to cause great harm. Electrical systems will function almost indefinitely, if properly installed and not overloaded or physically abused. Electrical fires in our homes claim the lives of 485 Americans each year and injure 2,305 more. Some of these fires are caused by electrical system failures and appliance defects, but many more are caused by the misuse and poor maintenance of electrical appliances, incorrectly installed wiring, and overloaded circuits and extension cords. Some safety tips to remember:

Never use anything but the proper fuse to protect a circuit.
Find and correct overloaded circuits.
Never place extension cords under rugs.
Outlets near water should be GFCI-type outlets.
Don't allow trees near power lines to be climbed.
Keep ladders, kites, equipment and anything else away from overhead power lines.

Electrical Panels

Electricity enters the home through a control panel and a main switch where one can shut off all the power in an emergency. These panels are usually located in the basement. Control panels use either fuses or circuit breakers. Install the correct fuses for the panel. Never use a higher-numbered fuse or a metallic item, such as a penny. If fuses are used and there is a stoppage in power, look for the broken metal strip in the top of a blown fuse. Replace the fuse with a new one marked with the correct amperage. Reset circuit breakers from "off" to "on." Be sure to investigate why the fuse or circuit blew. Possible causes include frayed wires, overloaded outlets, or defective appliances. Never overload a circuit with high-wattage appliances. Check the wattage on appliance labels. If there is frayed insulation or a broken wire, a dangerous short circuit may result and cause a fire. If power stoppages continue or if a frayed or broken wire is found, contact an electrician.

Outlets and Extension Cords

Make sure all electrical receptacles or outlets are three-hole, grounded outlets. If there is water in the area, there should be a GFCI or ground-fault circuit interrupter outlet. All outdoor outlets should be GFCIs. There should be ample electrical capacity to run equipment without tripping circuit breakers or blowing fuses. Minimize extension cord use. Never place them under rugs. Use extension cords sparingly and check them periodically. Use the proper electrical cord for the job, and put safety plugs in unused outlets.

Electrical Appliances

Appliances need to be treated with respect and care. They need room to breathe. Avoid enclosing them in a cabinet without proper openings, and do not store papers around them. Level appliances so they do not tip. Washers and dryers should be checked often. Their movement can put undue stress on electrical connections. If any appliance or device gives off a tingling shock, turn it off, unplug it, and have a qualified person correct the problem. Shocks can be fatal. Never insert metal objects into appliances without unplugging them. Check appliances periodically to spot worn or cracked insulation, loose terminals, corroded wires, defective parts and any other components that might not work correctly. Replace these appliances or have them repaired by a person qualified to do so.

Electrical Heating Equipment

Portable electrical heating equipment may be used in the home as a supplement to the home heating system. Caution must be taken when using these heating supplements. Keep them away from combustibles, and make sure they cannot be tipped over. Keep electrical heating equipment in good working condition. Do not use them in bathrooms because of the risk of contact with water and electrocution. Many people use electric blankets in their homes. They will work well if they are kept in good condition. Look for cracks and breaks in the wiring, plugs and connectors. Look for charred spots on both sides. Many things can cause electric blankets to overheat. They include other bedding placed on top of them, pets sleeping on top of them, and putting things on top of the blanket when it is in use. Folding the blankets can also bend the coils and cause overheating.

Children

Electricity is important to the workings of the home, but can be dangerous, especially to children. Electrical safety needs to be taught to children early on. Safety plugs should be inserted in unused outlets when toddlers are in the home. Make sure all outlets in the home have face plates. Teach children not to put things into electrical outlets and not to chew on electrical cords. Keep electrical wiring boxes locked. Do not allow children to come in contact with power lines outside. Never allow them to climb trees near power lines, utility poles or high tension towers.

Electricity and Water

A body can act like a lightning rod and carry the current to the ground. People are good conductors of electricity, particularly when standing in water or on a damp floor. Never use any electrical appliance in the tub or shower. Never touch an electric cord or appliance with wet hands. Do not use electrical appliances in damp areas or while standing on damp floors. In areas where water is present, use outlets with GFCIs. Shocks can be fatal.

Animal Hazards

Mice and other rodents can chew on electrical wires and damage them. If rodents are suspected or known to be in the home, be aware of the damage they may cause, and take measures to get rid of them.

Outside Hazards

There are several electrical hazards outside the home. Be aware of overhead and underground power lines. People have been electrocuted when an object they are moving has come in contact with the overhead power lines. Keep ladders, antennae, kites and poles away from power lines leading to the house and other buildings. Do not plant trees, shrubs or bushes under power lines or near underground power lines. Never build a swimming pool or other structure under the power line leading to your house. Before digging, learn the location of underground power lines.

Do not climb power poles or transmission towers. Never let anyone shoot or throw stones at insulators. If you have an animal trapped in a tree or on the roof near electric lines, phone your utility company. Do not take a chance of electrocuting yourself. Be aware of weather conditions when installing and working with electrical appliances. Never use electrical power tools or appliances with rain overhead or water underfoot. Use only outdoor lights, fixtures and extension cords. Plug into outlets with a GFCI. Downed power lines are extremely dangerous. If you see a downed power line, call the electric company, and warn others to stay away. If a power line hits your car while you are in it, stay inside unless the car catches fire. If the car catches fire, jump clear without touching metal and the ground at the same time.

MORE SAFETY PRECAUTIONS :

Routinely check your electrical appliances and wiring.
Hire an InterNACHI inspector. InterNACHI inspectors must pass rigorous safety training and are knowledgeable in the ways to reduce the likelihood of electrocution.
Frayed wires can cause fires. Replace all worn, old and damaged appliance cords immediately.
Use electrical extension cords wisely and don't overload them.
Keep electrical appliances away from wet floors and counters; pay special care to electrical appliances in the bathroom and kitchen.
Don't allow children to play with or around electrical appliances, such as space heaters, irons and hair dryers.
Keep clothes, curtains and other potentially combustible items at least 3 feet from all heaters.
If an appliance has a three-prong plug, use it only in a three-slot outlet. Never force it to fit into a two-slot outlet or extension cord.
Never overload extension cords or wall sockets. Immediately shut off, then professionally replace, light switches that are hot to the touch, as well as lights that flicker. Use safety closures to childproof electrical outlets.
Check your electrical tools regularly for signs of wear. If the cords are frayed or cracked, replace them. Replace any tool if it causes even small electrical shocks, overheats, shorts out or gives off smoke or sparks.

In summary, household electrocution can be prevented by following the tips offered in this guide and by hiring an InterNACHI inspector.]]><![CDATA[Water Quality Testing]]>Thu, 10 Jul 2014 13:14:02 GMThttp://brightechpropertyinspections.com/home-inspector-blog/water-quality-testingDrinking Water

The United States has one of the safest water supplies in the world. However, national statistics don’t tell you specifically about the quality and safety of the water coming out of your tap. That’s because drinking water quality varies from place to place, depending on the condition of the source water from which it is drawn, and the treatment it receives. Now you have a new way to find information about your drinking water if it comes from a public water supplier (The EPA doesn’t regulate private wells, but recommends that well. owners have their water tested annually.) Starting in 1999, every community water supplier must provide an annual report (sometimes called a "consumer confidence report") to its customers. The report provides information on your local drinking water quality, including the water’s source, the contaminants found in the water, and how consumers can get involved in protecting drinking water. You may want more information, or you may have more questions. One place you can go is to your water supplier, who is best equipped to answer questions about your specific water supply.

What contaminants may be found in drinking water?

There is no such thing as naturally pure water. In nature, all water contains some impurities. As water flows in streams, sits in lakes, and filters through layers of soil and rock in the ground, it dissolves or absorbs the substances that it touches. Some of these substances are harmless. In fact, some people prefer mineral water precisely because minerals give it an appealing taste. However, at certain levels, minerals, just like man-made chemicals, are considered contaminants that can make water unpalatable or even unsafe. Some contaminants come from the erosion of natural rock formations. Other contaminants are substances discharged from factories, applied to farmlands, or used by consumers in their homes and yards. Sources of contaminants might be in your neighborhood or might be many miles away. Your local water quality report tells which contaminants are in your drinking water, the levels at which they were found, and the actual or likely source of each contaminant. Some ground water systems have established wellhead protection programs to prevent substances from contaminating their wells. Similarly, some surface-water systems protect the watershed around their reservoir to prevent contamination. Right now, states and water suppliers are working systematically to assess every source of drinking water, and to identify potential sources of contaminants. This process will help communities to protect their drinking water supplies from contamination.

Where does drinking water come from?

A clean, constant supply of drinking water is essential to every community. People in large cities frequently drink water that comes from surface-water sources, such as lakes, rivers and reservoirs. Sometimes, these sources are close to the community. Other times, drinking water suppliers get their water from sources many miles away. In either case, when you think about where your drinking water comes from, it’s important to consider not just the part of the river or lake that you can see, but the entire watershed. The watershed is the land area over which water flows into the river, lake or reservoir. In rural areas, people are more likely to drink ground water that was pumped from a well. These wells tap into aquifers, the natural reservoirs under the earth’s surface, that may be only a few miles wide, or may span the borders of many states. As with surface water, it is important to remember that activities many miles away from you may affect the quality of ground water. Your annual drinking water quality report will tell you where your water supplier gets your water.

How is drinking water treated?

When a water supplier takes untreated water from a river or reservoir, the water often contains dirt and tiny pieces of leaves and other organic matter, as well as trace amounts of certain contaminants. When it gets to the treatment plant, water suppliers often add chemicals, called coagulants, to the water. These act on the water as it flows very slowly through tanks so that the dirt and other contaminants form clumps that settle to the bottom. Usually, this water then flows through a filter for removal of the smallest contaminants, such as viruses and Giardia. Most ground water is naturally filtered as it passes through layers of the earth into underground reservoirs known as aquifers. Water that suppliers pump from wells generally contains less organic material than surface water, and may not need to go through any or all of these treatments. The quality of the water will depend on local conditions. The most common drinking water treatment, considered by many to be one of the most important scientific advances of the 20th century, is disinfection. Most water suppliers add chlorine or another disinfectant to kill bacteria and other germs. Water suppliers use other treatments as needed, according to the quality of their source water. For example, systems whose water is contaminated with organic chemicals can treat their water with activated carbon, which adsorbs or attracts the chemicals dissolved in the water.

What if I have special health needs?

People who have HIV/AIDS, are undergoing chemotherapy, take steroids, or for another reason have a weakened immune system may be more susceptible to microbial contaminants, including Cryptosporidium, in drinking water. If you or someone you know fall into one of these categories, talk to your healthcare provider to find out if you need to take special precautions, such as boiling your water. Young children are particularly susceptible to the effects of high levels of certain contaminants, including nitrate and lead. To avoid exposure to lead, use water from the cold tap for making baby formula, drinking and cooking, and let the water run for a minute or more if the water hasn’t been turned on for six or more hours. If your water supplier alerts you that your water does not meet the EPA’s standard for nitrates, and you have children under 6 months old, consult your healthcare provider. You may want to find an alternate source of water that contains lower levels of nitrates for your child.

What are the health effects of contaminants in drinking water?

The EPA has set standards for more than 80 contaminants that may be present in drinking water and pose a risk to human health. The EPA sets these standards to protect the health of everybody, including vulnerable groups like children. The contaminants fall into two groups, according to the health effects that they cause. Your local water supplier will alert you through the local media, direct mail, or other means if there is a potential acute or chronic health effect from compounds in the drinking water. You may want to contact them for additional information specific to your area. Acute effects occur within hours or days of the time that a person consumes a contaminant. People can suffer acute health effects from almost any contaminant if they are exposed to extraordinarily high levels (as in the case of a spill). In drinking water,microbes, such as bacteria and viruses, are the contaminants with the greatest chance of reaching levels high enough to cause acute health effects. Most people’s bodies can fight off these microbial contaminants the way they fight off germs, and these acute contaminants typically don’t have permanent effects. Nonetheless, when high-enough levels occur, they can make people ill, and can be dangerous or deadly for a person whose immune system is already weak due to HIV/AIDS, chemotherapy, steroid use, or another reason. Chronic effects occur after people consume a contaminant at levels over the EPA’s safety standards for many years. The drinking water contaminants that can have chronic effects are chemicals (such as disinfection byproducts, solvents, and pesticides), radionuclides (such as radium), and minerals (such as arsenic). Examples of these chronic effects include cancer, liver and kidney problems, and reproductive difficulties.

Who is responsible for drinking water quality?

The Safe Drinking Water Act gives the Environmental Protection Agency (EPA) the responsibility for setting national drinking water standards that protect the health of the 250 million people who get their water from public water systems. Other people get their water from private wells which are not subject to federal regulations. Since 1974, the EPA has set national standards for over 80 contaminants that may occur in drinking water. While the EPA and state governments set and enforce standards, local governments and private water suppliers have direct responsibility for the quality of the water that flows to your tap. Water systems test and treat their water, maintain the distribution systems that deliver water to consumers, and report on their water quality to the state. States and the EPA provide technical assistance to water suppliers and can take legal action against systems that fail to provide water that meets state and EPA standards.

What is a violation of a drinking water standard?

Drinking water suppliers are required to monitor and test their water many times, for many things, before sending it to consumers. These tests determine whether and how the water needs to be treated, as well as the effectiveness of the treatment process. If a water system consistently sends to consumers water that contains a contaminant at a level higher than EPA or state health standards regulate, or if the system fails to monitor for a contaminant, the system is violating regulations, and is subject to fines and other penalties. When a water system violates a drinking water regulation, it must notify the people who drink its water about the violation, what it means, and how they should respond. In cases where the water presents an immediate health threat, such as when people need to boil water before drinking it, the system must use television, radio and newspapers to get the word out as quickly as possible. Other notices may be sent by mail, or delivered with the water bill. Each water suppliers’ annual water quality report must include a summary of all the violations that occurred during the previous year.

How can I help protect my drinking water?

Using the new information that is now available about drinking water, citizens can be aware of the challenges of keeping drinking water safe and take an active role in protecting drinking water. There are lots of ways that individuals can get involved. Some people will help clean up the watershed that is the source of their community’s water. Other people might get involved in wellhead protection activities to prevent the contamination of the ground water source that provides water to their community. These people will be able to make use of the information that states and water systems are gathering as they assess their sources of water. Concerned citizens may want to attend public meetings to ensure that their community’s need for safe drinking water is considered in making decisions about land use. You may wish to participate when your state and water system make funding decisions. And all consumers can do their part to conserve water and to dispose properly of household chemicals.

From Water Quality - Int'l Association of Certified Home Inspectors (InterNACHI) http://www.nachi.org/waterquality.htm#ixzz34CxEpzsn]]>