Understand your home energy bill

What do gigajoules, kilowatts and BTUs have in common, and why should you care? What they have in common is that they are different measurements of the same thing, energy.

A watt is a unit of electricity, one amp moving in a one ohm conductor, pushed by a force of one volt.
A joule is one watt per second or a force of one kilogram meter per second.
A kilowatt hour is 1,000 watts per hour and 360 seconds X 1000 watts, 3,600,000 Joules.
The BTU (British Thermal Unit) is the amount of heat needed to raise the temperature of one cubic foot of water one degree Fahrenheit, which is also equal to 1055.06 joules
Even though by definition all seem to be measuring different things, they are actually measuring the same thing, energy.

You should care because your home heating bill is a measure of energy that you have to pay for. If you live in Edmonton your home is almost certainly heated by natural gas, you may also be using gas for heating water, cooking or drying laundry.

Natural gas sold in Edmonton is billed as gigajoules. Home gas meters read in cubic feet. Gas furnaces are rated by BTUs per hour, electric heaters use electricity measured in watts, but may also be sold by their BTU output.
One kilowatt hour is 3414 BTU.
A cubic foot of natural gas produces 1000 BTU of heat energy.
A gigajoule is 947,817 BTU.
277.8 kilowatt hours are also one gigajoule.

Electric heat from the grid in Edmonton will cost consumers roughly ten times more than using gas. The reason it costs more in Edmonton is that 91% of Alberta’s electricity is generated from fossil fuels, coal (43%) and natural gas (49%) (Canada Energy Regulator). If electricity is generated using fossil fuel it will always cost more than using fossil fuel directly for the same reason a pound of french fries will always cost more than a pound of raw potatoes.

Using a month’s bills from Epcor for electricity and Direct Energy for natural gas for February 2020 at the regulated rate for domestic consumption, the delivered cost of a gigajoule of natural gas was $7.34 vs $61.90 for a gigajoule (277.8 kilowatt hours) of electricity, including all the administrative, fixed and variable delivery costs charged by these utilities. The regulated rate varies, fixed rates are available month to month, but do not expect the overall ratio of electricity costing roughly ten times more than gas to change as long as Alberta uses gas to generate electricity.

The future of fossil fuel energy looks dim, as it should. Climate change and greenhouse gas emissions notwithstanding, fossil fuel is a non renewable resource. Since the 1970’s people who know have been predicting that fossil fuels will eventually be used up. So far they have been wrong about when, but few could deny that eventually they will be right. As to what will replace it, a betting person might put their money on solar energy, which is already providing nearly all of the energy we use right now, including fossil fuels, solar energy that was stored for millions of years.

As for being greenest today, the more people in Edmonton can use natural gas for heating homes or water, cooking or drying laundry instead of electricity from the grid, the less impact their energy use has on the environment, given that 91% of Alberta’s electricity comes from fossil fuels 43% of which is coal. And using natural gas directly costs a lot less money than using electricity. Every time energy is used a little bit of it gets away, not all of it is used for its intended purpose.

Most of the electricity that arrives in your home was produced in a power plant that burned either gas or coal to make heat. Most, but not all of that heat was used to turn water into steam. Most (60%) of that steam energy got away. 40% efficiency is the limit for steam power. Most, but not all of that generator motion was used to push electrons back and forth in our grid. Some of the electrical energy was lost as heat when it was transmitted. When electricity is used for things other than heat, there are also losses, turning on an incandescent light bulb can literally create more heat than light (energy).

If there is any good news, it is that much of the electricity we use for all the things we use electricity for, like lighting, computers, TVs, refrigerators and vacuum cleaners ends up as heat inside our homes, which is good news for Edmonton, as our furnaces do not have to work as hard, but not so good news for Miami where it makes their electrically powered air conditioners work even harder.

Getting the most out of your home inspection

If you attend, and you follow me, watch what I am doing, ask lots of questions, you will get the most value from your inspection. Your attendance is not a problem for me, it is your inspection, you are paying good money for it, you deserve to get full value. Your schedule is not a problem, East Side is open for business week days, weekends, most holidays, any time of day with daylight (necessary for exterior inspection).

To make sure you that you can focus on your inspection, try to attend by yourself, or (just) with your partner. If your home inspection becomes a social occasion with many friends and relatives, you may find it difficult to divide your attention between your soon to be new home and your guests. If you have small children of an age where they need constant attention or supervision maybe find a baby sitter to leave them with.

Finally these are not rules, they are suggestions, it is your inspection, so make it the best you can make it.

New Homes, why it’s not easy being green

New homes and homes upgraded for energy efficiency in cold climates are more likely to have mold and moisture problems than older ‘inefficient’ homes.  Building codes that have incorporated energy efficiency requirements may have done so at the expense of maintaining healthy indoor air, especially when so little is being done to educate home owners on how a modern home works.  If the installed ventilation systems in new homes are not used or maintained, air can get stale.  Stale air has higher humidity and possibly unhealthy or even hazardous gases and vapors, the result of people pets and plants breathing and exhaling water vapor and carbon monoxide, showering, bathing and cooking.  Small amounts of potentially cancer causing ground gases like Radon may be seeping in through basements with inadequate or unused ventilation, building materials, paints, adhesives, carpets, flooring, cabinets may off-gas various solvents or water vapor as they age, which could be removed by a good ventilation system, provided people use it.

In places where outdoor temperatures remain at or below -18 C, or zero Fahrenheit, like Edmonton, home energy efficiency means reducing heat loss.  Heat is lost from homes in two major ways, heat energy transfering from hot to cold through exposed walls, windows, doors and ceilings, and through the loss of heated air replaced by outside cold air that has to be heated.  A small amount of heat energy is also lost through radiation, but that is negligible.

A house in winter is a box full of hot air, if left it will cool, the same as the cup of Starbucks left sitting. As indoor air comes in contact with walls, windows, etc., heat moves from the warm air to the cold surfaces.  Exterior walls windows and doors in turn pass the heat to outdoor air.  Left long enough all the indoor air and all surfaces in contact with it will reach the same temperature, whatever it is outside, (which is warmed infinitesimally, but not so the squirrels would notice).  The rate of cooling can be slowed by insulation the same as a not so green foam coffee cup.

Insulation in homes is mostly fiberglass batts, a type of fiberglass blanket installed between the studs, (the 2by sticks that make up exterior walls), and loose fiberglass blown into the attic.  Fiberglass is very thin strands of glass. Put your hand on a window when it is cold out, glass is not a very good insulator, the actual insulation is provided by trapped air, which is a very good insulator, the fiberglass just keeps the air from moving (the same is true for that foam cup, trapped air is actually doing the insulation).  Fiberglass and its cousins, mineral wool, cellulose, wood chips etc., have a insulation rating of about R3.5 per inch, (excuse the imperial measurement, but that is what most people are familiar with).  So, an ordinary house with 2X4 walls will have walls that are approximately R12, and if they have about 12 inches (300 mm ) of attic insulation, for a ceiling rated at R40.  With the exception of the R40 attic insulation, it is also pretty much the way we have been insulating homes in Alberta for 100 years.

New homes have different attics than older homes.  Older homes made roofs and attics using rafters and joists, 2by lumber that had to sized deeper for the loads it was expected to carry, a typical joist depth (the lumber the ceiling was fastened to) was 6 inches (150 mm), filled with wood chips for an R rating of about 19.

New homes are built with trusses instead of rafters and joists.  Trusses are engineer designed triangles of thin lumber, like those toothpick bridges they made you build in elementary school.  All those triangles make access to attics difficult, storing stuff is no longer an option, but otherwise useless attics are easy and tempting to pack with insulation.

So insulation wise, a new home does not necessarily have much more insulation in the walls than great granny’s Edmonton* 1920 new house had, but do have more attic insulation over the top floor ceiling.   This is all good, great granny’s builder was no dummy, he knew how to build a house for an Edmonton winter, but don’t automatically assume that today’s new home construction is advanced as say, the way today’s new cars are made over  cars made 100 years ago.

A dirty little secret is that home builders don’t like to spend money on stuff that can’t be seen, because Mr. or Ms. Newhomebuyer aren’t eager to hand over more money on stuff they can’t see.  It is usually easier for a new home sales person to convince buyers to upgrade to granite counter tops than triple glazed windows and energy efficient ventilation.  Another dirty little secret is that even though attic insulation has gone from R19 in 1920 to R40 in 2016, that does not make much difference in heat loss, but it does sound good.

A ceiling is a horizontal wall with no windows or doors.  Heat loss happens over exposed cold surfaces, a function of area, consider a 2000 square foot two story square house, each story 9 feet high, and four outside walls 31 feet wide, total exposed wall area is 31 X 9 X 4 X 2 stories, or 2200 square feet of exposed no better than R12 wall vs 31 X 31, 1000 square feet of ceiling exposed not quite to the exterior, but to an unheated attic that still has a roof to provide a bit of weather protection.

Windows and doors have much lower R ratings, no better than R 3 for triple glazed windows, not quite R2 for double glazed or Great Granny’s double storm windows that had to be taken down and stored in the spring.  Windows, old or new provide a fraction of the insulation provided by an ordinary insulated 2X4 wall with siding.  A new home probably has more window area than Great Granny’s as well so that 2200 square feet of wall will add up to a lot less than R12 overall when windows and door area is factored in.   So, by all means insulate the heck out of the attic, but don’t expect a great improvement in heat loss.

One thing that has changed a lot since Great Granny moved into her new home is dealing with the second major source of heat loss, air leakage.   Older homes could be pretty drafty, especially around windows and doors or any other openings such as electrical outlets in exposed walls and ceilings.  Air leaking out is replaced by unheated air leaking back in which will need to be heated.

Home builders have been dealing with air leakage for about 50 years, as plastic films used for air barriers became cheap and available.  Sealing and caulking openings, like windows and doors when they are installed or replaced is fairly easy to do, like stuffing the attic with more insulation. As building codes change, requirements for air sealing are tougher, enabling those who write codes to pat themselves on the back for being green and saving energy at no cost (to the code writers).

New homes are very tight, if built right, very little air can get in or out.  If you are thinking this is good stuff, ask any kid what happens when you put a living frog in a screw top jam jar with no air holes.    We need fresh air, our homes need fresh air, and as homes got tighter, things needed to be done to ensure that a home received fresh air.

The basic requirement as of this writing is a fresh air intake duct and mechanical ventilation (fans) to bring in the fresh and remove stale air.  The most common way Edmonton builders comply to ventilation code is to insert a fresh air intake into the forced air heating system return air duct, so that whenever the air handler (furnace) fan is running, fresh air is brought in by the furnace and distributed through the heating duct system.  A ventilation switch operates an exhaust fan and the furnace fan at the same time when it switched on.  Homes that do not have forced air heating need to have an exhaust and intake fan operated by the ventilation switch. An HRV (heat recovery ventilator) is a self contained unit that can take care of bringing air and exhausting stale air, with the added benefit of using exhausted air to warm incoming air with a heat exchanger.   The most basic systems are operated by a switch which require the occupants to decide whether or not they need fresh air.  More sophisticated systems use automated programmable controls to ensure that a home’s air is exchanged on a regular basis.  The Canadian Home and Mortgage Corporation (CMHC) recommends an indoor air change every 3 hours.

Most homes built before 2010 in Alberta had an ‘automated’ air exchange system operated by the chimney.  Most homes in Alberta are still heated by fire (just like those jolly old caves used our great great great… and on so great grannies).  For the last 70 years the fire has been natural gas burned in a furnace, previously  we burned coal, wood and before that, flaming dried buffalo poop kept tipis nice and toasty.

A fire requires air to burn, it also produces smoke if you are burning coal, wood or buffalo droppings, but even clean burning natural gas produces water vapor and carbon dioxide, which has to be gotten rid of.  A chimney or an opening up high allows the hot products of combustion we don’t want to naturally rise up and out, carrying warm air with it, which was replaced by incoming cold air, leaking in from everywhere at first, and for the last few decades by combustion air intake ducts. By placing the furnace, chimney, and combustion air duct in the same room, usually the basement or part of it, the incoming combustion air also mixed with the air in the house, and indoor heated air went up the chimney.

The drive to save energy and make homes and appliances more efficient resulted in redesigned for energy efficiency furnaces that use no inside air, Today’s high efficiency gas furnace, the only kind available, draws all of its air for combustion from outdoors, extracts most of the heat from the exhaust before blowing it back outside through a plastic vent pipe at the side of the house instead of a chimney, so no more heated air flying out chimneys and no more automated ventilation.

New homes have an adequate ventilation systems, provided people use them.  You may be saving a few pennies on your gas bill by keeping fresh air out of your house, but the possible health costs or damage to your home will give a 21st Century meaning to the phrase penny wise, pound foolish.  It is fairly easy to keep indoor air fresh, use the systems that are installed in your home, make sure that the air intakes are free to draw in the kind of air you would prefer to breathe, and make a practice of  opening doors and windows every so often to let some fresh air in.

*Not necessarily true for regions that did not experience extremely cold winter temperatures.