Knob and Tube Wiring

Knob and Tube Wiring

by | Dec 18, 2012 | Electrical, Saftey

Knob and Tube   The majority of homes in Downtown Windsor were built prior to 1940.  As a result most still have knob and tube wiring. Knob and Tube  was an original form of wiring and was used from 1880 to the 1930s.

As existing Knob and Tube (K& T) wiring gets older, insurance companies may deny coverage due to a perception of increased risk.  Several companies will not write new homeowners policies at all unless all K&T wiring is replaced, or an electrician certifies that the wiring is in good condition. Also, many institutional lenders are unwilling to finance a home with limited ampacity (current carrying capacity) service (which, as noted above, often goes hand-in-hand with K&T wiring), unless the electrical service is upgraded.

It is usually easily seen in unfinished basements by the Cermamic knobs and tubes used.  Knob and tube wiring was eventually displaced from interior wiring systems because of the high cost of installation compared with use of power cables, which combined both power conductors of a circuit in one run (and which later included grounding conductors).

Many home owners have removed visible knob and tube from their basements, as some insurance companies felt the old exposed wiring was unsafe.  However removal of knob and tube from within walls and ceilings throughout a house is often not completed do to its expense. As well some insureace companies only require removal of exposed wiring.

 

steel armoured cable

I have seen some home owners run steel armoured BX conduit outside of walls to replace knob and tube. While this may provide a ground, it is  unattractive.

 

 

 

 

Another way of recognising the potential presence of knob and tube wiring in a home is two prog plug receptacles.  As knob and tube never had grounds, older plug receptacles had only 2 sockets without a ground.

2 prong2 prong plug (receptacle)

Two prong outlets are rather inconvenient as grounded plugs to not fit into them. In additon two prong plugs can create a safety hazard. The third prong on a plug is designed to give a fault path in the event the hot wire, or device that is connected to should short out.
The absence of a ground path can lead to a electrical shock. For example a metal light fixture could become energized on its exterior, and the lack of grounding will not allow the breaker to trip.

The problem is that you cant  necessarily just replace them with a three prong plug.  If the wiring system is not bonded to ground, then that would be an illegal fix. A three prong plug tester will show “open ground”.  In fact it is a good thing you can do yourself.

Plug Tester

Go around and check every plug in your house with a tester.  They are readily available, and only a few dollars.
In some cases the wiring is grounded and they just didn’t put three prong plugs, because they were cheaper.  In many cases there is no wire, or other grounding path.

It is likely that your old two prong plug is so loose that cords fall right out of it, or it is brittle and cracking.  Either way it should be replaced.  At this point you have two choices that are legal.  Replace it with a new two prong receptacle is one. The other is replace it with  a three prong plug, but only after verifying that you have a ground path.

What if you do not have a ground, but you want a 3 prong plug anyway?

GFI receptacleGFI receptacle

The answer GFI is to protect the circuit.  This can be done with a breaker, or a receptacle. It is possible  for a single GFI  outlet to protect the entire circuit that feeds off of it.
The reason that this is legal is because the GFI receptacle can detect minute levels of leakage current, and open the circuit. In fact it does it a lot faster than the breaker would. This is why they are required near sources of water, or outside.
There used to be a time  where someone would grab a drill while standing in a puddle and get killed.  With a GFI, they wouldn’t even feel a tingle. It would instantly shut off power.

Using an electrician is always recommended to ensure everything is completed to building code.

This is a very big deal if you want to sell your house.

 

 

 

Fire Safety and Prevention in Windsor Essex

by | May 7, 2012 | Saftey

Fire Safety and Prevention in Windsor Essex

Compliments of

 

Fire Prevention Tips

  • Do not plug too many appliances into an electrical outlet.
  • Make sure that combustibles are not too close to heaters, stoves and fireplaces.
  • Never smoke in bed, or leave a burning cigarette in an ashtray.
  • Do not use damaged or frayed electrical cords or extension cords.
  • Keep matches and lighters out of the reach of children.
  • Teach your children about the dangers of playing with fire.
  • Never use extension cords with heating or air conditioning equipment.
  • Purchase smoke alarms and fire extinguishers for each floor of your home.

Have an Emergency Escape Plan! Practice it frequently!

  • Develop an emergency exit plan and an alternate exit plan. The most obvious way out may be blocked by fire. A window will usually be the second way out of a bedroom. Make sure that screens or storm windows can be easily removed. If you live in a two story home, you should have an escape ladder for each occupied bedroom. Escape ladders are available for purchase, and they can easily be stored under a bed or in a closet.
  • Establish a meeting place outside your home to be sure everyone has escaped. Every family member should participate in practicing escape drills at least two times per year.
  • In the event of fire, do not stop to get dressed or gather valuables. Seconds count – do not search for the family pet.
  • Teach your family that in a fire they must stay low to the floor to avoid smoke and intense heat. Passageways may be completely filled with dense smoke, so everyone should practice exiting on their hands and knees while blindfolded.
  • Train family members to feel a closed door before exiting. If the door is warm, open it slowly, and close it quickly if heat or smoke rushes in.
  • Establish a rule that once you’re out, you never re-enter under any circumstances. As soon as two people have reached the meeting place, one should call 911 from a neighbor’s house.

Smoke Alarms

Through education and media campaigns, most people now realize the importance of smoke alarms, and most homes in North America have them.

Recommendations:
  • Purchase a smoke alarm for every floor of your home, and read the instructions on how to use it and where to position it.
  • Smoke alarms should be placed near bedrooms, either on the ceiling or six to twelve inches below the ceiling on the wall.
  • Local codes may require additional alarms. Check with your fire department or building code official.
  • Locate smoke alarms away from air vents.
  • Test your alarms regularly to ensure that they still work.
  • If you have a battery powered alarm, change the battery every six months when you change your clocks.
  • For maximum protection, install BOTH ionization and photoelectric smoke alarms in the home for the optimum detection of fast flaming fires and slow smoldering fires.

Fire Extinguishers

To guard against small fires or to keep a small fire from developing into a big one, every home should be equipped with a fire extinguisher. Because almost all fires are small at first, they might be contained if a fire extinguisher is handy and used properly. You should take care, however, to select the right kind of fire extinguisher, because there are different ones for different kinds of fires. Install fire extinguishers on every level of the home and include the kitchen, basement and garage.

Selecting a Fire Extinguisher

Extinguishers are classified according to the class of fire for which they are suitable. The four classes of fires are A, B, C, D:

  • Class A fires involve common combustibles such as wood, paper, cloth, rubber, trash and plastics. They are common in typical commercial and home settings.
  • Class B fires involve flammable liquids, solvents, oil, gasoline, paints, lacquers and other oil-based products. Class B fires often spread rapidly. Unless they are properly suppressed, they can re-flash after the flames have been extinguished.
  • Class C fires involve energized equipment such as wiring, controls, motors, machinery or appliances. They can be caused by a spark, a power surge, or a short circuit and typically occur in locations that may be difficult to see or reach.
  • Class D fires involve combustible metals.

A typical home or office fire extinguisher should have an ABC rating.

Carbon Monoxide

One of the greatest threats to your safety is the quality of air within your home. Carbon monoxide (CO) is a subtle yet dangerous threat because the gas is colorless, odorless and tasteless.
Each year, hundreds of people die from carbon monoxide poisoning. Thousands of other people suffer the effects of the gas without realizing it. Because CO symptoms mimic the flu and other common illnesses, CO poisoning can be easily missed during a routine medical examination.
CO is produced when any fuel does not burn completely because of insufficient oxygen. Mild exposure to CO gives most people a slight headache, nausea, vomiting, fatigue (“flu-like” symptoms) followed by a throbbing headache, drowsiness, confusion, and fast heart rate. If the entire family becomes ill after a few hours in the home, and feels better when they leave the home, carbon monoxide poisoning should be suspected.
Possible sources of CO include:

  • Furnace or boiler
  • Gas or fuel-oil water heater
  • Gas or wood fireplace
  • Gas kitchen range
  • Plugged, rusted, disconnected, or defective chimneys or vents
  • Back drafting of combustion gases into the home
  • Automobiles in attached garages

Certain clues can indicate a carbon monoxide problem. Check to see if you have any of the following:

  • Rusting or streaking on chimney or vent
  • Loose or missing furnace panel
  • Soot on venting or appliances
  • Loose or disconnected venting
  • Debris or soot falling from chimney
  • Moisture on interior side of windows

CO can be produced and spill into your home without any of the preceding clues present. Heating appliances that appear to be operating correctly can still be sources of CO. Burning charcoal or wood produces CO that can spill into the home. Gasoline engines, when first started, produce large amounts of CO. Autos in attached garages are often sources of CO.

How To Protect Yourself

To avoid CO exposure in the home, it is important to:

  • Make sure heating appliances are installed and used in accordance with manufacturer’s instructions.
  • Make sure chimneys and vents draw all gases out of the home.
  • Have the heating system, chimney and vents inspected and serviced annually by a qualified heating contractor.
  • Never use charcoal grills indoors.
  • Never heat your home with a gas kitchen range.
  • Always use a kitchen range hood, vented to the outdoors, when cooking on a gas range.
  • Never warm-up or run vehicles or other gasoline engines in garages or indoors.

The Consumer Product Safety Commission recommends that every residence with fuel burning appliances be equipped with at least one CO alarm. For added protection, place one on every level of the home. Read and follow manufacturers’ instructions.
If your alarm indicates high levels of carbon monoxide in your home:

  • Immediately move outdoors to fresh air and do a head count
  • Call your emergency services
  • Do not re-enter the home until emergency service responders have arrived, aired out the house, and determined it is safe to re-enter
  • Correct the problem before starting the heating appliances
  • If a carbon monoxide alarm sounds again, repeat the above steps. Do not ignore alarms.

Fires are traumatizing and frightening, as is a carbon monoxide incident. It is essential to fully recognize the hazards of fire and carbon monoxide poisoning and to take preventative action. A regular home inspection, smoke and carbon monoxide alarms, fire extinguishers and an emergency exit plan will help you and your family live more safely.

Carbon Monoxide – CMHC

by | Jan 17, 2012 | Home Improvement, Home Repair, Saftey

Carbon Monoxide

The presence of carbon monoxide (CO) in our homes is dangerous. So, how can you protect your family from carbon monoxide? How do you choose the right CO detector for your home? The first step is to make sure that carbon monoxide never enters your home. The second step is to install at least one CO detector in your home.
This About Your House answers often-asked questions about carbon monoxide to help you make the right decision to make your home safe.

What Is Carbon Monoxide?

Carbon monoxide (CO) is a colourless and odourless gas. Because you can’t see, taste or smell it, it can affect you or your family before you even know it’s there. Even at low levels of exposure, carbon monoxide can cause serious health problems. CO is harmful because it will rapidly accumulate in the blood, depleting the ability of blood to carry oxygen.1

Where Does Carbon Monoxide Come From?

Carbon monoxide is a common byproduct of the combustion (burning) of fossil fuels. Most fuel-burning equipment (natural gas, propane and oil), if properly installed and maintained, produces little CO. The byproducts of combustion are usually safely vented to the outside. However, if anything disrupts the venting process (such as a bird’s nest in the chimney) or results in a shortage of oxygen to the burner, CO production can quickly rise to dangerous levels.
The burning of wood, kerosene, coal and charcoal produces CO. Gasoline engines produce CO. CO production is at a maximum during the startup of a cold engine. Starting, then idling, your car or gas mower in the garage can be dangerous. The fumes that contain CO can enter a home through connecting walls or doorways and can quickly rise to dangerous levels.

How Can I Eliminate Sources of Carbon Monoxide in My Home?

The most important step you can take to eliminate the possibility of CO poisoning is to ensure that CO never has an opportunity to enter your home. This is your first line of defence. Review this list to minimize the risk of CO in your home.

  • Have a qualified technician inspect and clean fuel-burning appliances yearly, before the cold weather sets in, to ensure they are in good working order.
  • Have a qualified technician inspect chimneys and vents yearly for cracks, blockages (e.g., bird’s nests, twigs, old mortar), corrosion or holes.
  • Check fireplaces for closed or blocked flues.
  • Check with a qualified technician before enclosing heating and hot water equipment in a smaller room, to ensure there is adequate air for proper combustion.
  • If you have a powerful kitchen exhaust fan or downdraft cooktop, have a qualified technician check that its operation does not pull fumes back down the chimney.
  • Never use propane or natural gas stove tops or ovens to heat your home.
  • Never start a vehicle in a closed garage; open the garage doors first. Pull the car out immediately onto the driveway, then close the garage door to prevent exhaust fumes from being drawn into the house.
  • Do not use a remote automobile starter when the car is in the garage; even if the garage doors are open.
  • Never operate propane, natural gas or charcoal barbecue grills indoors or in an attached garage.
  • Avoid the use of a kerosene space heater indoors or in a garage. If its use is unavoidable provide combustion air by opening a window while operating. Refuel outside after the unit has cooled.
  • Never run a lawnmower, snowblower, or any gasoline-powered tool such as a whipper snipper or pressure washer inside a garage or house.
  • The use of fossil fuels for refrigeration, cooking, heat, and light inside tents, trailers, and motorhomes can be very dangerous. Be sure that all equipment is properly vented to the outside and use electric or battery-powered equipment where possible.
  • Regularly clean the clothes dryer ductwork and outside vent cover for blockages such as lint, snow, or overgrown outdoor plants.
  • Reduce or eliminate the use of fondue heaters indoors.
  • If you live close to a road with heavy traffic, outdoor carbon monoxide levels can affect your indoor air quality, especially during rush hour. Such levels should not set off a CO alarm, but slightly elevated CO levels might be observable on some types of CO detectors with a digital display.

Carbon Monoxide Detectors

Are They Really Necessary?

If you take the actions above, you greatly reduce your risk of CO poisoning. But unanticipated dangerous incidents may still occur despite your best efforts to avoid CO. The installation of at least one CO detector in your home is a good safety precaution and in some municipalities, it is the law. A detector might be your second line of defence, but it is necessary. You should have one in your home today.

How Do CO Detectors Work?

There are three basic types of CO sensors — metal oxide, biomimetic and electrochemical. Note that while there may be performance differences between these technologies, all detectors are tested and approved for their operation. The retail cost of a detector will generally relate to the number of features included and its warranty conditions.
Metal-oxide-semi-conductor (MOS)
This is the original technology for detecting CO. Heated tin oxide reacts with CO to determine the levels of the toxic gas. There is no need to remember to check batteries as units must be connected to house power. Models that offer up to 20 hours of battery backup are available.
Biomimetic
Biomimetic detectors have gel-coated discs that darken in the presence of CO and the colour change sounds an alarm. This technology is less expensive and can be battery operated.
Electrochemical
In this type of detector, a chemical reaction with CO creates an electrical current that sets off an alarm. Electrochemical detectors are highly sensitive and offer accurate readings at all CO levels. Most units come with a continuous digital readout and a memory feature that allows you to check past CO levels. This technology offers a fast reset time. Most units sound an alert when the sensor needs to be replaced.

What Features Should I Look for When Purchasing a CO Detector?

Most CO detectors are designed to give an alarm when CO levels reach a high level in a short time. However, health agencies advise that long-term, low-level exposure is also of concern, especially for the unborn and young children, the elderly and those with a history of heart or respiratory problems.1 Detectors that can display both high and low levels are more expensive but they do provide greater accuracy and more information.
Here are some features to consider when purchasing a CO detector:

  • Look for a detector that is listed with the Canadian Standards Association (CSA) standard. The logos of the testing agency will be on the product.
  • Choose a detector with a memory if you want to monitor long-term, low-level exposure and short-term, high-level exposure. Even though product standards do not allow manufacturers to display low levels of CO, these units monitor and store this information. Peak levels, no matter what the level of concentration, can be viewed by pressing a button.
  • Battery-operated units allow detector placement in the most convenient location. However, any battery-operated device requires the user’s diligence in replacing worn-out batteries.
  • Do not connect plug-in units to an electrical outlet that is controlled by a wall switch.
  • No detectors will operate properly forever. Replace them at least every five years, unless the manufacturer specifies a shorter or longer life. Eventually, manufacturers may be required to print expiry dates on their CO detectors. This will ensure that you are purchasing an up-to-date product with a full sensor life.

Detector Sensitivity Issues

The standards organizations of Canada (CSA) and the United States (Underwriters Laboratories or UL) have coordinated the writing of CO standards and product testing. The standards as of 2010 prohibit showing CO levels of less than 30 ppm on digital displays. The most recent standards also require the alarm to sound at higher levels of CO than with previous editions of the standard. The reasoning behind these changes is to reduce calls to fire stations, utilities and emergency response teams when the levels of CO are not life threatening. This change will also reduce the number of calls to these agencies due to detector inaccuracy or the presence of other gases. Consequently, new alarms will not sound at CO concentrations up to 70 ppm. Note that these concentrations are significantly in excess of the Canadian health guidelines.
Detectors with a digital display and a “history” option can provide the true CO concentrations in a house. A low-level display would be useful for people with existing respiratory problems or for those who like to spot evolving problems, rather than having to wait for the situation to become serious. Low-level CO detection products are becoming commercially available. They will not be certified to CSA or UL standards, as these standards currently prohibit low-level displays.

Where Do I Put a CO Detector?

Most manufacturers specify where you should locate their CO detector. In general, the best place to put the detector is where you will hear it while sleeping. CO is roughly the same weight as air and distributes evenly throughout a room, so a detector can be placed at any height in any location, as long as its alarm can be heard. Additional units could be installed in several other locations around the home, such as a child’s bedroom; check the following list before installing.
To avoid both damage to the unit and to reduce false alarms, do not install CO detectors:

  • in unheated basements, attics or garages
  • in areas of high humidity
  • where they will be exposed to chemical solvents or cleaners, including hair spray, deodorant sprays, etc.
  • near vents, flues or chimneys
  • within 2 m (6 ft.) of heating and cooking appliances
  • near forced- or unforced-air ventilation openings
  • within 2 m (6 ft.) of corners or areas where natural air circulation is low
  • where they can be damaged, such as an outlet in a high traffic area
  • where directly exposed to the weather.

Testing Your CO Detector

Most CO detectors have a test button that should be pressed once a week to confirm that the device is in operation. Detectors with displays can be tested with a known source of CO such as smoke from an incense stick. Hold the CO source about 20 – 25 cm (8 – 10 in.) away and watch the digital display respond to the presence of even a small amount of CO, but an alarm will most likely not sound with this test.
There are CO detector test kits available, where CO detectors are sold, that provide a vial containing a high level of CO (1,000 ppm) and a plastic tent to house the unit during the test. This test only proves that your detector will sound an alarm with a very high level of CO.

What Do I Do if I Hear the Carbon Monoxide Detector Alarm?

Do not ignore the CO detector’s alarm if it sounds. Treat each alarm as serious and respond accordingly. CO detectors are designed to sound an alarm before a healthy adult would feel any symptoms. Infants, the elderly and those with respiratory and heart conditions are at particular risk and may react to even low levels of CO poisoning.1

Response to an Obvious Source of CO

If your detector sounds an alarm and you have an obvious source of CO, such as an unvented kerosene heater:

  • evacuate the house, including pets and do a head count
  • if anyone is suffering from flu-like symptoms, call 911
  • remove or turn off the source
  • ventilate the house
  • reset the alarm
  • do not re-occupy the house until the alarm ceases
  • take steps to avoid this situation in the future.

Response to an Unknown Source of CO

If your CO detector is sounding an alarm and there is no obvious source of CO:

  • evacuate the house, including pets and do a head count
  • if anyone has flu-like symptoms, call 911; if there are no health problems, call your gas utility, heating contractor or the fire department to have your house tested
  • if you live in a single-family home: do not ventilate your home, turn off fuel-burning appliances or reset your CO detector prior to someone testing your home. Many CO alarm calls have been classified as “false alarms” because the homeowner had ventilated the home and turned off the equipment before firefighters or technicians could measure the CO levels and find the source
  • if you live in a duplex, row house, apartment, or otherwise attached house, do ventilate the house and turn off fuel-burning appliances. In this case, the safety of your neighbours is more important than trying to find the CO source
  • have a qualified service technician inspect and repair all fuel-burning appliances, if they are identified as being the CO source
  • do not re-occupy the house unless those who tested the house inform you that the danger is over.

Symptoms of Carbon Monoxide Poisoning2

Be sure that all members of your family know the symptoms of CO poisoning:

Mild Exposure

Flu-like symptoms such as headache, running nose, sore eyes, etc.

Medium Exposure

Drowsiness, dizziness, vomiting. The sense of disorientation and confusion may make it difficult for some victims to make rational decisions like leaving the home or calling for assistance.

Extreme Exposure

Unconsciousness, brain damage, death.

Continued Low-level Exposure to CO

While this may be not lead to observable symptoms, you should still avoid such exposure.
Table 1 — Carbon monoxide concentrations and their effects

CO concentration in parts per million (ppm) Effects
0 – 2 Normal conditions in and outside Canadian houses.
10 Recommended exposure limit over a 24-hour period.3
25 Recommended exposure limit over a 1-hour period.3
30 CO detectors are not allowed to sound alarm unless this concentration is maintained for more than 30 days.2
70 CO detectors must sound alarm within 1 to 4 hours.2
150 CO detectors must sound alarm within 10 to 50 minutes.2
200 Slight headache, fatigue, dizziness and nausea after 2 to 3 hours. CO detector alarm must sound within 35 minutes.4
400 CO detectors must sound alarm within 4 to 15 minutes.2
800 Dizziness, nausea and convulsions within 45 minutes, death within 2 to 3 hours.4
1,600 Death within 1 hour.4
13,000 Danger of death after 1 to 3 minutes.4
1 Canada. Health Canada, Exposure Guidelines for Residential Indoor Air Quality (Ottawa: Ministry of Supply and Services Canada, 1989).
2 Canadian Standards Association, CAN/CSA 6.19-01: Residential Carbon Monoxide Alarming Devices (Canada: Canadian Standards Association, 2001).
3 Canada. Health Canada, Residential Indoor Air Quality Guideline: Carbon Monoxide (Ottawa: Minister of Health, 2010). Available online at http://www.hc-sc.gc.ca/ewh-semt/pubs/air/carbon_mono/index-eng.php
4 T. H. Greiner, Carbon Monoxide Poisoning (AEN-172) (Ames: Iowa State University of Science and Technology, 1997).
Last revised: 2011
Avoid Basement Flooding Windsor Real Estate

Avoid Basement Flooding Windsor Real Estate

by | Jan 4, 2012 | Blog, Home Maintenance, Mold, Plumbing, Saftey

Avoiding Basement Flooding

Compliments of www.cameronpaine.com

Basement flooding is unfortunately a common occurrence in many parts of Canada. But the good news is that many types of basement flooding may be avoided. This publication explains some of the practical steps you can take to avoid basement flooding.

How Serious Is Basement Flooding?

Basement flooding is now being recognized as a potentially serious problem. There are many negative consequences associated with basement flooding, above and beyond the inconvenient mess and disruption of household routine. Research cites the following impacts:

  • Chronically wet houses are linked to an increase in respiratory problems.
  • Frequent occurrences of basement flooding can result in long-term damage to the building and equipment that may not be covered by insurance.
  • Insurance rates may rise to compensate for repeated basement flooding claims, and/or the minimum deductible may be increased significantly.
  • Property value may depreciate because the basement is prone to frequent flooding.

Before appropriate measures can be taken, it is important to identify the causes of basement flooding. These range from problems originating in the individual dwelling to problems associated with the municipal sewer systems that serve entire communities.

Why Do Basements Flood?

Water can enter your basement for a number of reasons. Water in your basement is most likely to occur during periods of heavy rainfall, or when snow is melting rapidly during a spring thaw. In these cases, your basement can be wet because of:

  • a leak or crack in your home’s basement walls;
  • poor lot drainage;
  • failure of the weeping tiles (foundation drains); and
  • overflowing eavestroughs or leaking/plugged downspouts.

Basement flooding may also occur because of:

  • a blocked connection between your home and the main sewer in the street;
  • a back-up of wastewater in the sewer system (or a combination of wastewater and rainwater from the sanitary or combined sewer system); and
  • failure of a sump pump (in some areas) used to pump weeping tile water.

Basements are also vulnerable to natural river flooding disasters, but these cannot be addressed by individual homeowners.

Flooding Basics

Municipalities attempt to prevent flooding by maintaining the public sewer system. Homeowners with private sewage systems (septic tank and field bed) can appreciate the need for regular maintenance, but unforeseen or accidental problems can occur in any type of system. Here is some municipal infrastructure terminology you should know:

Sanitary Sewer

A sanitary sewer is a pipe buried beneath the street that is designed to transport wastewater from your home. This consists of water from sanitary fixtures (toilets, sinks, etc.) and floor drains inside your house, and in some areas includes groundwater from weeping tiles around the foundation of your home.

Storm Sewer

A storm sewer is a pipe buried beneath the street that is designed to carry storm-related water runoff. Storm sewers are normally much larger than sanitary sewers because they are designed to carry much larger amounts of flow.

Figure 1 — Types of sewer systems serving houses in Canada
Figure 1 — Types of sewer systems serving houses in Canada

Sewer Backup

Extra storm-related water (from sources other than wastewater and groundwater) should flow into the storm sewer or soak slowly into the ground without entering the sanitary sewer. If excess storm water does enter the sanitary sewer system, it can overload this kind of system.
When the sewers are overloaded, the water level in the system rises above normal design levels, and this condition is referred to as “surcharge.” Basement flooding can occur if the home has sanitary fixtures or floor drains below the surcharge level (Figure 2).

Figure 2 — Basement flooding due to combined sewer backup
Figure 2 — Basement flooding due to combined sewer backup

Practical Measures to Avoid Basement Flooding

Basement flooding problems are best diagnosed by working your way down from the eavestroughs and downspouts, to the lot and foundation drainage, and then to the plumbing system — both inside your home and beyond its connection to the municipal sewer system.

Eavestroughs and Downspouts

Water pours out of your eavestroughs into downspouts. If the downspouts are dumping the water right beside your foundation, it drains directly to the weeping tile and can easily overload your home’s drainage. Make sure downspouts extend at least 1.8 m (6 ft.) from your basement wall. Also, be sure the water does not drain toward your neighbour’s basement walls. It should drain away from your house toward the street, rear yard, or back lane. If your downspouts are connected to your home’s sewer system, or weeping tile, disconnect them.
Clean debris from eavestroughs regularly. If they overflow even when clean, replace them with larger size eavestroughs and downspouts.

Lot Grading

If the land around your home slopes in toward the foundation, rainwater heads right for the weeping tile around the basement and can overload your foundation drainage system. The land around many homes settles over time, and then slopes in toward the foundation. If your lot slopes inward, you’ll want to fill in and grade the lot so that, for at least 1.8 m (6 ft.) out from around the foundation, the land slopes away from your house.
Build up the ground around your house so that water drains away from your basement walls. Also, examine sidewalks, patios, decks and driveways. These can settle over time and cause water to drain back towards your basement walls (Figure 3).

Figure 3 — Grading and planting
Figure 3 — Grading and planting

Extend downspouts so that water flows away from your house and does not collect next to the basement walls and windows.
Proper drainage helps to:

  • reduce the amount of water flowing to your home’s sewer system and to the main sewer system, and lessen the risk of sewer backup;
  • reduce water seepage into your home through basement windows and cracks in your basement walls;
  • keep the moisture content of the soil around and under your house stable to reduce the chances of cracking and shifting. If water collects next to your basement, it can make its way to the footings that support the basement walls. The increased moisture may cause the footings to heave or settle; and
  • extend the life of your sump pump by reducing the amount of work it has to do.

Be sure that any drainage improvements you make do not cause water to flow onto your neighbour’s property.

Floodproofing Devices

If your home drainage system or the neighbourhood’s drainage system overloads, you may still be able to prevent rain water and sewage from backing up into your basement by installing one or more floodproofing devices, such as sump pumps or back flow valves. Each installation is unique and some devices (back flow valves) may require a plumbing permit. Check with your municipal office or a qualified plumber before you proceed with any installation

Sump Pit Drainage System

A sump pit drainage system includes a sump pit, a sump pump and a discharge pipe. The sump pit, set into the basement floor, collects water from the weeping tiles around your basement. The pump pushes the water outside your house through the discharge pipe (Figure 4).

Figure 4 — Typical sump pump installation
Figure 4 — Typical sump pump installation

Place your sump pump discharge pipe so that it:

  • drains somewhere onto your property where water can be absorbed, such as your lawn or flower bed; and
  • does not direct water onto neighbouring properties, lanes, sidewalks, or streets.

Sump Pit

  • Clean the pit each year after freeze-up. Weeping tile drainage may carry small amounts of soil, sand and debris into the pit from around your basement foundation.
  • Some water may remain in the pit and cause a musty smell if it sits for a long time. If so, you can flush the pit by adding fresh water until the pump removes the stale water.

Sump Pump

  • Check and test your pump each spring before the rainy season begins, and before you leave your house for a long time. Pour water into the pit to trigger the pump to operate.
  • Remove and thoroughly clean the pump at least once a year. Disconnect the pump from the power source before you handle or clean it.
  • Check the pit every so often to ensure it is free of debris. Most pumps have a screen that covers the water intake. You must keep this screen clean.

Sump Pump Discharge Pipe

  • Check the place where the discharge pipe leaves the house. If the pipe is discharging right against the basement wall, the water will drain down into the weeping tiles and continue to recycle through the system.
  • Check the discharge point regularly to make sure that nothing is blocking the flow.
  • If your pump runs frequently in the winter, and the resulting ice is causing hazardous conditions on the lawn and sidewalks, call your municipal office.

Backwater Valve
A backwater valve is a device that prevents sewage in an overloaded main sewer line from backing up into your basement. The valve automatically closes if sewage backs up from the main sewer (Figure 5). A properly installed backwater valve must be placed so that sewage backup will be stopped and not come out through other outlets in your basement, such as sinks, toilets, showers and laundry tubs.

  • Make sure that you can get at the valve at all times.
  • Check the valve regularly and remove any material that may prevent the valve from operating properly.

You will normally require a permit and inspection to install a back flow valve and sump pit. Since part of the basement floor will be dug up and since proper placement of these items is important, we recommend that you use a qualified plumbing contractor.

Figure 5 — Back flow valves and sump pumps are effective means of avoiding basement flooding
Figure 5 — Back flow valves and sump pumps are effective means of avoiding basement flooding

Additional Protection Measures

There are also several additional flood protection measures that may be considered.

Plumbing Fixture Maintenance

Have a qualified plumber inspect all floodproofing devices and plumbing fixtures (i.e. sump pumps, backwater valves, floor drains, etc.) regularly to ensure proper operation. Check the operating instructions for more detailed information and safety guidelines, or ask your plumber to explain the details of your system to you.

Backup Sump Pump

Severe storms are often accompanied by power blackouts. A battery powered backup sump pump may be a prudent investment. Most pumps are made to fit in beside the main sump pump and also have an audible alarm that warns the main pump has failed so that you can attend to its repair or replacement. There are also water powered backup sump pumps available that run by water flowing through the pump impeller.

Basement Finishes and Furnishings

In the event a risk of basement flooding is still possible, it is advisable to install impermeable floor and wall finishes, such as ceramic tile, to lessen damage and make cleanup easier. Make sure basement furniture has legs that keep the furniture fabrics above any accumulated flood water. Area rugs are a good alternative to full broadloom as these can be removed and properly cleaned in the event of flood damage.

Insurance — Just in Case

Insurance that fully covers basement flooding damage is an important means of financial protection to homeowners.
Most policies include or can include coverage for damage caused by sewer back-up. Make sure your policy includes sewer back-up insurance.
Check regularly with your insurance agent or broker to ensure you have appropriate and adequate insurance coverage, including any extensions in coverage that may be available, which were not previously attached.
Keep a detailed inventory of your residence. It will be invaluable in the event of loss.
Make sure your insurance policies and related records are in a safe location and easily available after an emergency or disaster event.

Acknowledgements

CMHC wishes to acknowledge the contributions of numerous Canadian municipalities to this publication. All of their public information bulletins were consulted during the development of this publication. Their assistance and cooperation are greatly appreciated.

Last revised: 2011.
What to do about a wet attic Windsor Real Estate

What to do about a wet attic Windsor Real Estate

by | Dec 21, 2011 | Blog, Energy Saving, Home Maintenance, Home Repair, Mold, Saftey

Attic Venting, Attic Moisture and Ice Dams

From CMHC Compliments of www.cameronpaine.com

It is rare for Canadians to visit their attics. For many years building codes have required high levels of attic insulation, making attics less-than-hospitable places. People usually go into their attics for one of two reasons: animal intruders, such as bats or squirrels, or water leaking through the top floor ceiling. This guide deals with water entry, such as roof leaks, ice dams, and attic condensation. Consult your local pest control expert to rid the attic of creatures.

What to Do If Water Comes Through Your Ceiling

Find out where the leak is in your ceiling by measuring its location from the nearest outside walls. Then, go into the attic through the attic hatch. It is often hidden in the ceiling of a closet or in the wall of an attached garage. If it is in a closet, move the clothes out of the closet so loose insulation won’t stick to them. Take a good flashlight and a tape measure.

When walking in the attic in older houses, step only on the wooden joists that cover the floor. The joists are usually spaced every 16 inches. They are often hidden under a pile of insulation. If you step off the joists, you will probably put your foot through the plaster or drywall ceiling below. Many houses, especially in warmer climates, have some type of floorboard over the joists. This makes walking easier but can make air sealing and insulating more complicated.

Floor section
Floor section
Figure 1: Typical attic floor insulations

Most houses built since the 1970s do not have attic rafters and joists, but trusses – usually at 24 inch centres – with the ceiling below attached to the lower chords. Walking in trussed attics is trickier than walking in older attics.

If you find vermiculite insulation in your attic, do not disturb it. Loose-fill vermiculite insulation may contain small amounts of asbestos, and you should consult a professional if it is going to be disturbed. CMHC’s information piece Asbestos provides additional guidance.

One further caution: if you find a significant amount of animal droppings from bats or birds, do not disturb them. They can grow molds that can cause several illnesses. To clean up droppings, you need good respiratory protection (masks) and clothing that can be bleached or discarded.

Find the water leak. Use the tape measure to roughly locate where the water is dripping through the ceiling below. Lift the insulation in this area to find the pooling water. Sometimes the water runs along the attic floor for quite a distance before coming through the ceiling.

Trace the water to its source. Look for leaks in the roof, especially around chimneys, plumbing vents, and attic vents – anything that penetrates the roof sheathing. Quite often the roof flashing is defective and needs replacement. If the sheathing (either boards, plywood, or composite board) along the lower edge of the roof is soaked and you can see a corresponding accumulation of ice on top of the roof, ice damming is occurring. This means that water is backing up under the shingles. Shingles are designed only to shed water running down, not up. Ice damming is covered at the end of this guide.

Your inspection may find that leakage is not the problem: the whole attic or part of it may be dripping with condensation or covered with frost.

Attic condensation and ice damming are related. Both can be caused by warm, moist air leaving the house and entering the attic. Attics will be in good shape if there are no holes, air leaks, or bypasses from the house to the attic and there is sufficient insulation to keep house heat from escaping. If you can ensure good air sealing and insulation, the attic will remain cool and dry, as if it were outside. For example, it is rare to see moisture problems or ice damming on the roof of a detached garage or unheated barn.

What To Do About a Wet Attic

There are many signs that an attic is wet. Prolonged wetness will rot out the roof sheathing. Often this is first noticed when re-shingling. If you have ceiling leaks only in the spring, it may be that ice has been forming on the sheathing all winter and it suddenly melts when a warm spell arrives. You may see water stains or evidence of mold on the sheathing, rafters, or trusses when you are inspecting the attic. You may find the insulation has been packed down or stained by water or ice. The smell of a moldy attic will enter the house under certain weather conditions, usually in summer.

The usual response is to increase attic ventilation. This is the wrong approach. In some cases, adding ventilation will actually pull more moist house air up into the attic and make the problem worse. The best way to fix a wet attic is to stop air movement, or leaks, from the house. Once this is done, the existing ventilation is usually more than enough to keep the attic dry.

It is important to stop air leaks because a heated house is much like a chimney. Both a house and chimney are containers of warm air surrounded by cold air. Both tend to draw air in at the bottom and expel it at the top. All winter, a heated house is trying to push air through the top floor ceiling into the attic. Block up those air leaks and keep the warmth in the house to save both energy costs and damage to your attic.

Air leaks are usually found at penetrations or discontinuities. Safety regulations prevent sealing of many types of pot lights in top floor ceilings. House air is dumped into the attic through them. Choose sealed pot lights or avoid them on the top floor.

Bathroom fans need to be ducted outside. Make sure that they are properly vented. If the ducts are located in the attic, ensure that they are solid metal rather than flex duct, insulated and sloped to the outside. Do not wrap the insulation in plastic as this will trap moisture.Taping the duct joints, or sealing them with mastic, is helpful for controlling leakage.

Plumbing stacks and chimneys are often sources of air leakage. Seal these where they pass through the attic floor. For metal chimneys inside a chase or for old masonry chimneys, you may need help from an expert to ensure proper sealing and avoidance of fire hazards. Seal holes made for electrical wiring and cable installations.

There will be little air leakage in the middle of sheet of drywall or in the middle of an unbroken plaster ceiling.There may be many air leaks where partition or bearing walls meet the ceiling or around the perimeter of the house where the attic floor (or top floor ceiling) meets the outside walls.

All discontinuities should be inspected and sealed if necessary. Look for bypasses.They are major air passages from any floor into the attic. Dropped ceilings in the room below will often conceal a direct connection to the attic. Concrete block party walls between row houses often move house air into the attic.

There are several ways to check for these large and unexpected leaks. The blower door tester can pressurize the house with a big fan and amplify the leakage. Searching the attic at night for lights from below can be helpful. Scanning batt insulation for dirty areas which have been filtering the air from below is also useful, although such straining seems to occur less frequently with blown insulation. Sometimes the holes are so big that you can see into the house below.

Some houses have heating or air conditioning ducts or equipment in the attic.These can be the major source of air leakage and heat loss in the attic. Good information on how to seal and insulate these devices has been published in Home Energy Magazine, available in some libraries.

Leaks can be sealed with caulking, expanding foam, plastic, or other methods. There are a number of publications giving details on sealing methods, including “Keeping the Heat In” from Natural Resources Canada, 1-800-387-2000 in Canada or (613) 995-2943 outside Canada. An electronic version is available on the web at: http://www.oee.nrcan.gc.ca/keep_heat_in/

In an older house, the most thorough way to air seal an attic floor is to clear away insulation from each joist bay and seal all discontinuities. If the attic joists are covered with floor boards, a thorough job includes lifting them to expose the ceiling below. Do this for the entire attic except for areas underlain by unbroken ceilings in a large room. It sounds difficult, but for most attics it should not take more than a day for a two-person crew. Wear good dust masks. Do the work in the fall when the attic is not too hot. Doing only obvious discontinuities without lifting all the insulation can be effective but may result in missing some air leakage paths.

While you are up there, why not put some more insulation down? Make sure that you have at least 300 mm (10 in.) of loose insulation or batts.There are only minor differences in the insulating quality of fiberglass, rock wool and cellulose.They all work well in attics.

Where to look for leaks

  • around plumbing stacks or plumbing walls
  • chimneys through the attic
  • any light fixtures from the ceiling below
  • electric wiring
  • ducting for fans or heating systems
  • perimeter walls
  • partition walls
  • party walls
  • above pocket doors
  • above lowered ceilings
  • where the side of a cathedral ceiling meets an open attic
  • split level discontinuities
  • where additions meet an older section of the house
  • above rounded corners or staircases
  • balloon frame walls
Details
Figure 2: Leakage areas on split level houses

Attic Venting

If you have properly sealed the attic you should not need more attic ventilation. Attic ventilation is overrated. In winter, the cold outside air cannot hold much humidity or carry moisture away from the attic. In summer, attic temperatures are more affected by the sun and shingle colour than by the amount of ventilation.

Recent research shows that identical attics, with one unvented and the other vented to code, have much the same humidity and temperature. Attic computer models show that attics in damp coastal climates may actually be drier with less ventilation.

Building codes require attic ventilation. Ventilation may make a difference in a borderline situation. Attic ventilation is driven primarily by wind. To ensure thorough venting, have openings at the soffits and then higher on the roof at the ridge, gable end, or high on the roof surface. The requirement for attic vent sizing is nominally 1:300 (or one square foot of vent size for every 300 square feet of attic floor area). If you wish to improve your attic venting, ensure that it is as well distributed as possible. Do not worry about meeting the 1:300 requirement exactly. Vents should be screened to keep out animals and insects. If you are using soffit vents, make sure that there is a space between the roof sheathing and the insulation for the ventilation air to pass. Commercially available plastic or card board forms can be used, or the extruded polystyrene board option described in the Ice Damming section.

Ice
Figure 3: Insulating the outside edge of the attic floor

Ice Damming

Ice dams are the large mass of ice that collects on the lower edge of the roof or in the gutters. As more melting snow (or rain) runs down the roof, it meets this mass of ice and backs up, sometimes under the shingles and into the attic or the house.

Ice damming usually occurs with a significant depth of snow on the roof. If the attic temperature is above freezing, it warms the roof sheathing which melts the snow lying on the shingles. This water runs down the roof until it meets the roof overhang, which is not warmed by the attic and will be at the temperature of the surrounding air. If the air and the overhang are below freezing, then the water will freeze on the roof surface and start the ice dam.

Detail
Figure 4: Formation of an ice dam

An attic with no insulation will generally not have a problem with ice dams. The heat coming through the attic will tend to melt snow off as it lands and prevent much accumulation. A well-sealed and insulated attic will generally not have ice dams. Like the example of a detached garage, this generally results in a cool roof and no great amount of melting. Ice dams are more frequent if the roof is complicated by many valleys and dormers or there is a large roof overhang.

Ice dams will first show up where there is inadequate insulation or major air leaks. One way to find these locations is to look at the roof with the first heavy frost in fall or light snow. Watch where the snow melts off first and find out what is under that spot on the roof. One common sight in such conditions is a horizontal melt line across the roof of a storey-and-a-half house, where the short kneewall meets the ceiling. Other places would be beneath a roof-ducted exhaust fan or over a leaky attic access hatch. The basic relief for ice damming is to seal all attic air leaks and insulate thoroughly, the same solution as for attic condensation.

Many attics, including those under low-sloped roofs, do not have enough space for adequate insulation at the edge of the attic floor. If soffit insulation requires a baffle to keep a ventilation opening against the sheathing, often there will be only 100 mm (4 inches) of space for insulation. This will tend to melt the snow off just above the over hang and promote ice damming. Try to put the best insulation possible at that edge to reduce heat loss. Blown foam is ideal as it air seals as well as insulates.

Cut pieces of extruded polystyrene will help as well. Mount a piece of extruded polystyrene 25 mm (1 inch) from the sheathing to maintain the ventilation air space and fill between this board and the attic floor with good insulation.

Ice dams caused by cathedral ceilings are more difficult. The same principles apply to preventing ice dams — stopping house air leaks, good insulation, perhaps ventilation — but cathedral ceilings are harder to get to. If you have ice dam problems with cathedral ceilings, you can fix the problem when re-roofing. Remove the sheathing, seal and fill the cavities with insulation, and replace the roofing material. A well-sealed roof will not need ventilation. If you are uncertain whether the sealing can be done effectively, leave a ventilation channel under the sheathing from the soffit to the peak. Sometimes insulation can be added to the ceiling inside, although this approach will not catch the air leakage.

An extensive and expensive ice dam solution is to make the roof impermeable by using a self-sealing membrane under the shingles. Building codes require such membranes on the lower part of the roof in new houses. Note that these membranes do not stop ice dams, they just prevent the water from leaking through the roof sheathing. Ice damming can still create the unsightly ice build-up and possible damage to shingles and gutters, but you may be spared the leakage into the house.

Do all these ice damming solutions sound like too much work? There are many quicker solutions that are popular, but in the end have drawbacks. You can attach electric cables which will melt channels in the ice, sometimes alleviating a problem. Cables use a significant amount of electrical energy as well as being an eyesore on most roofs.

Removing gutters will keep them from becoming ice traps, but gutters are valuable: they keep roof water away from your basement. Attacking ice dams every winter with an axe or ice pick is a good way to shorten shingle life — and a good opportunity to fall off a ladder. At least one person has had success with filling nylon stockings with salt and laying them in the gutter. Some corrosion and environmental damage may result.

For some older houses with complicated roofs, it may be impossible to completely eliminate ice dams without resorting to some of the methods above. However, for most houses, the preferred solution is to keep house heat out of the attic, by air sealing and insulating, and avoid weaker alternatives. Spend the time to fix it properly and you will not have to worry about it again while you live in that house.

Additional Resources

Developed by Natural Resources Canada (NRCan), the ecoENERGY initiative provides a residential energy assessment service delivered by local organizations across Canada for a fee. Retrofits may be eligible for grants. To find a local service organization or grant information, visit http://www.ecoaction.gc.ca or call 1-800-387-2000.