Pioneer Plumbing has built a reputation of honesty with our long time returning customers. We’ve found that “doing the right thing” in all aspects of our company has brought us to where we are today, and will continue to guide us into the future. Don’t hesitate to call and ask us any plumbing, heating, ventilation, or gas related questions. Chances are if you have a tricky issue, we can solve it.
We have a few goals for our clients. One is to be available for you. It is very uncommon that when you call us we are unable to make it within the same day. We give our repeat customers priority service so if you’ve used us before and you have an emergency, we are going to do what we need to, to get someone there.
Two is to be upfront and honest. From our quotes to our service techs on site, we don’t like to beat around the bush. We will let you know our concerns, our recommendations, and our opinions on how we would handle each situation as if it were our own residence where the problem occurred. We won’t tell you the job is only a 2 hour repair when we have had situations where it turned into an all day repair.
Three is to stand behind our installations and repairs. With mechanical work, it is very common for jobs to get larger or go sideways as you get into them. If we give you a quote we will stand true to the price, if we complete a job for you and you are unhappy with the finished product, we will come back and make it right. In return, all we ask is that you communicate with our office respectfully and honestly so that we can make sure at the end of the day you are happy with our services!
So next time you have a plumbing, heating, cooling, or gas question, repair, or installation you would like quoted, give us a call! Were here to help.
Are you interested in ideas involving Fix Furnace?
Heating Repair And Regular Maintenance Tips
There are a few ways to maintain your furnace system. Chances are good the system shall be running all day long in winter. Actually, it is probably on more than it needs to be because it is incapable of maintaining an efficient environment. When troubleshooting and optimizing the heating segment of your furnace system, there are various areas to consider.
The Air Filter
This is what you typically hear people talking about most often, but so few individuals take the recommendation and do anything about it. If there is a obstruction, you either run the risk of not disbursing heat appropriately or perhaps igniting a fire.When the air filter becomes dirty air will not flow through as well which suggests the furnace must work overtime and will also mean a risk of fire. When your furnace works overtime, it is more expensive to operate. The fire situation is self-explanatory. Neither circumstance is good for the pocket book or your peace of mind..
Try The Blower
Check out the blower blades to make sure they are free of crap. Should there be any build-up of grime and dust, your fan will need to work harder to blow the air around, and your furnace will be overexerting itself. Meaning that the system is over taxed and costing extra money to run.
Fire Damper Function
Be certain to look at your fire damper for correct functioning. This will ensure that the fir risk is lowered and the system will work more proficiently.
Look For Holes In The Flex Duct
Air ducts get bumped into over the years. If a duct has collapsed or become blocked, your system will think that the proper temperature has been reached, which will not be true. When this happens the furnace works too much to do its job but is going to be incapable to attain the right temperature range.
Make Sure The Insulation Is Secure
It is easy to miss the insulation, but is probably the most common reason behind a system out of order. Take the time to focus on the insulation between the duct work and the outside to make sure it has not worked itself loose. If this happens, your system will not reach ideal temperatures and work too hard to try and accommodate.
Air Ducts Need To Be Sealed
See that the ductwork has not become detached from other sections. These detachments can cause spaces in the ventilation and cause a loss of heated air in your home, since it is going to be leaking out through the spaces.
Check For Leaks In The Return Air Inlets And The Zone Dampers
Make certain that that return air intakes are free of debris and dust so air can easily flow. Check your dampers verifying they are in the best place. During the year we may change the position of the damper for many reasons (i.e. getting into a tight space or arranging for storage). Check to see that the dampers are actually in the right position too.
If that is a tad too much to handle by yourself, we suggest you hire an area plumbing service licensed for furnace and heating repair. There will be a number of heating specialists close to you who can care for all of this quite skillfully. The most sage advice we can provide is to set up annual maintenance for that appliance.
https://www.google.com/maps?cid=3074062878359928777
https://plumber-vancouver-repair-service.business.site/
https://downtown.pioneerplumbing.com/
Pioneer Plumbing & Heating Inc
1101-1202 Harwood St
Vancouver BC, V6E 1S3
Phone: (778) 839-2040
Place ID ChIJfSdjui5zhlQRyb_bmeZDqSo
Business Hours:
Friday Open 24 hours
Saturday Open 24 hours
Sunday Open 24 hours
Monday Open 24 hours
Tuesday Open 24 hours
Wednesday Open 24 hours
Thursday Open 24 hours
Types of Heating Systems
Central Heat
Furnaces
The majority of North American households depend on a central furnace to provide heat. A furnace works by blowing heated air through ducts that deliver the warm air to rooms throughout the house via air registers or grills. This type of heating system is called a ducted warm-air or forced warm-air distribution system. It can be powered by electricity, natural gas, or fuel oil.
Inside a gas- or oil-fired furnace, the fuel is mixed with air and burned. The flames heat a metal heat exchanger where the heat is transferred to air. Air is pushed through the heat exchanger by the “air handler’s” furnace fan and then forced through the ductwork downstream of the heat exchanger. At the furnace, combustion products are vented out of the building through a flue pipe. Older “atmospheric” furnaces vented directly to the atmosphere, and wasted about 30% of the fuel energy just to keep the exhaust hot enough to safely rise through the chimney. Current minimum-efficiency furnaces reduce this waste substantially by using an “inducer” fan to pull the exhaust gases through the heat exchanger and induce draft in the chimney. “Condensing” furnaces are designed to reclaim much of this escaping heat by cooling exhaust gases well below 140°F, where water vapor in the exhaust condenses into water. This is the primary feature of a high-efficiency furnace (or boiler). These typically vent through a sidewall with a plastic pipe.
New furnace standards are currently under development by the U.S. Department of Energy, and are due to be finalized in the spring of 2016. The current furnace standards have not been updated since 1987.
Heating system controls regulate when the various components of the heating system turn on and off. The most important control from your standpoint is the thermostat, which turns the system — or at least the distribution system — on and off to keep you comfortable. A typical forced air system will have a single thermostat. But, there are other internal controls in a heating system, such as “high limit” switches that are part of an invisible but critical set of safety controls.
The best gas furnaces and boilers today have efficiencies over 90%
The efficiency of a fossil-fuel furnace or boiler is a measure of the amount of useful heat produced per unit of input energy (fuel). Combustion efficiency is the simplest measure; it is just the system’s efficiency while it is running. Combustion efficiency is like the miles per gallon your car gets cruising along at 55 miles per hour on the highway.
In the U.S., furnace efficiency is regulated by minimum AFUE (Annual Fuel Utilization Efficiency). AFUE estimates seasonal efficiency, averaging peak and part-load situations. AFUE accounts for start-up, cool-down, and other operating losses that occur in real operating conditions, and includes an estimate of electricity used by the air handler, inducer fan, and controls. AFUE is like your car mileage between fill-ups, including both highway driving and stop-and-go traffic. The higher the AFUE, the more efficient the furnace or boiler.
Boilers
Boilers are special-purpose water heaters. While furnaces carry heat in warm air, boiler systems distribute the heat in hot water, which gives up heat as it passes through radiators or other devices in rooms throughout the house. The cooler water then returns to the boiler to be reheated. Hot water systems are often called hydronic systems. Residential boilers generally use natural gas or heating oil for fuel.
In steam boilers, which are much less common in homes today, the water is boiled and steam carries heat through the house, condensing to water in the radiators as it cools. Oil and natural gas are commonly used.
Instead of a fan and duct system, a boiler uses a pump to circulate hot water through pipes to radiators. Some hot water systems circulate water through plastic tubing in the floor, a system called radiant floor heating (see “State of the Art Heating”). Important boiler controls include thermostats, aquastats, and valves that regulate circulation and water temperature. Although the cost is not trivial, it is generally much easier to install “zone” thermostats and controls for individual rooms with a hydronic system than with forced air. Some controls are standard features in new boilers, while others can be added on to save energy (see the “Modifications by Heating System Technicians” section on the heating maintenance page).
As with furnaces, condensing gas-fired boilers are relatively common, and significantly more efficient than non-condensing boilers (unless very sophisticated controls are employed). Oil-fired condensing boilers are uncommon in the U.S. for several reasons related to lower latent heat potential, and potential for greater fouling with conventional fuel oil.
Heat Pumps
Heat pumps are just two-way air conditioners (see detailed description in the cooling systems section). During the summer, an air conditioner works by moving heat from the relatively cool indoors to the relatively warm outside. In winter, the heat pump reverses this trick, scavenging heat from the cold outdoors with the help of an electrical system, and discharging that heat inside the house. Almost all heat pumps use forced warm-air delivery systems to move heated air throughout the house.
A ground-source heat pump heats and cools in any climate by exchanging heat with the ground, which has a more constant temperature.
There are two relatively common types of heat pumps. Air-source heat pumps use the outside air as the heat source in winter and heat sink in summer. Ground-source (also called geothermal, GeoExchange, or GX) heat pumps get their heat from underground, where temperatures are more constant year-round. Air-source heat pumps are far more common than ground-source heat pumps because they are cheaper and easier to install. Ground-source heat pumps, however, are much more efficient, and are frequently chosen by consumers who plan to remain in the same house for a long time, or have a strong desire to live more sustainably. How to determine whether a heat pump makes sense in your climate is discussed further under “Fuel Options.”
Whereas an air-source heat pump is installed much like a central air conditioner, ground-source heat pumps require that a “loop” be buried in the ground, usually in long, shallow (3–6′ deep) trenches or in one or more vertical boreholes. The particular method used will depend on the experience of the installer, the size of your lot, the subsoil, and the landscape. Alternatively, some systems draw in groundwater and pass it through the heat exchanger instead of using a refrigerant. The groundwater is then returned to the aquifer.
Because electricity in a heat pump is used to move heat rather than to generate it, the heat pump can deliver more energy than it consumes. The ratio of delivered heating energy to consumed energy is called the coefficient of performance, or COP, with typical values ranging from 1.5 to 3.5. This is a “steady-state” measure and not directly comparable to the heating season performance factor (HSPF), a seasonal measure mandated for rating the heating efficiency of air-source heat pumps. Converting between the measures is not straightforward, but ground-source units are generally more efficient than air-source heat pumps.
Direct Heat
Gas-Fired Space Heaters
In some areas, gas-fired direct heating equipment is popular. This includes wall-mounted, free-standing, and floor furnaces, all characterized by their lack of ductwork and relatively small heat output. Because they lack ducts, they are most useful for warming a single room. If heating several rooms is required, either the doors between rooms must be left open or another heating method is necessary. Better models use “sealed combustion air” systems, with pipes installed through the wall to both provide combustion air and carry off the combustion products. These units can provide acceptable performance, particularly for cabins and other buildings where large temperature differences between bedrooms and main rooms are acceptable. The models can be fired with natural gas or propane, and some burn kerosene.
Unvented Gas-Fired Heaters: A Bad Idea
Gas or kerosene space heaters that do not have an exhaust vent have been sold for decades, but we strongly discourage their use for health and safety reasons. Known as “vent-free” gas heating appliances by manufacturers, they include wall-mounted and free-standing heaters as well as open-flame gas fireplaces with ceramic logs that are not actually connected to a chimney. Manufacturers claim that because the products’ combustion efficiency is very high, they are safe for building occupants. However, this claim is only valid if you keep a nearby window open for adequate fresh air— which defeats the purpose of supplemental heat. Dangers include exposure to combustion by-products, as discussed in Ventilation, and oxygen depletion (these heaters must be equipped with oxygen depletion sensors). Because of these hazards, at least five states (California, Minnesota, Massachusetts, Montana, and Alaska) prohibit their use in homes, and many cities in the United States and Canada have banned them as well.
Electric Space Heaters
Portable (plug-in) electric heaters are inexpensive to buy, but costly to use. These resistive heaters include “oil-filled” and “quartz-infrared” heaters. They convert electric current from the wall socket directly into heat, like a toaster or clothes iron. As explained further under “Selecting a New System,” it takes a lot of electricity to deliver the same amount of useful heat that natural gas or oil can provide onsite. A 1,500- watt plug-in heater will use almost the entire capacity of a 15-amp branch circuit; thus, adding much additional load will trip the circuit breaker or blow the fuse. The cost to operate a 1,500-watt unit for an hour is simple to compute: it is 1.5 times your electricity cost in cents per kilowatt-hour. At national average rates—12¢ kWh for electricity— that heater would cost 18¢ per hour to run—and quickly cost more than its purchase price. On the other hand, for intermittent use, it is the “least-bad” solution when alternatives would require major investments to improve ductwork for a specific area, for example. Just remember, electric resistance heat is usually the most expensive form of heat, and it is, therefore, seldom recommended.
“Electric baseboard heat” is yet another kind of resistive heating, similar to a plug-in space heater except that it is hard-wired. It has two principal virtues: the installation cost is low, and it is easy to install individual room thermostats so you can turn down the heat in rooms that aren’t being used. Operating costs, as for all resistive systems, are generally very high, unless the house is “super-insulated.”
Wood-Burning and Pellet Stoves
Wood heating can make a great deal of sense in rural areas if you enjoy stacking wood and stoking the stove or furnace. Wood prices are generally lower than gas, oil, or electricity. If you cut your own wood, the savings can be large. Pollutants from wood burning have been a problem in some parts of the country, causing the U.S. Environmental Protection Agency (EPA) to implement regulations that govern pollution emissions from wood stoves. As a result, new models are quite clean-burning. Pellet stoves offer a number of advantages over wood stoves. They are less polluting than wood stoves and offer users greater convenience, temperature control, and indoor air quality.
Fireplaces
Gas (and most wood) fireplaces are basically part of a room’s décor, providing a warm glow (and a way to dispose of secret documents), but typically not an effective heat source. With customary installations that rely on air drawn from the room into the fireplace for combustion and dilution, the fireplace will generally lose more heat than it provides, because so much warm air is drawn through the unit and must be replaced by cold outside air. On the other hand, if the fireplace is provided with a tight-sealing glass door, a source of outside air, and a good chimney damper, it can provide useful heat.
State of the Art Heating
Radiant floor heat generally refers to systems that circulate warm water in tubes under the floor. This warms the floor, which in turn warms people using the room. It is highly controllable, considered efficient by its advocates, and is expensive to install. It also requires a very experienced system designer and installer, and limits carpet choices and other floor finishes: you don’t want to “blanket” your heat source.
Contact the Radiant Panel Association(link is external)
Ductless, Mini-Split, Multi-Split. Residential ductwork is relatively rare outside North America. “Ductless” heat pumps, which distribute energy through refrigerant lines instead of water or air, are widely used. Large field trials in the Pacific Northwest suggest that they can have good cold weather performance, and be very cost-effective where replacing electric resistance heating. Like ground-source systems, relative immaturity of the market helps assure that whole-house multi-split systems carry premium prices.
Combined heat and power (CHP) or cogeneration for houses is being seriously studied in some countries. The basic premise is to use a small generator to meet some of the electric demand of the house, and recover the waste heat (typically more than 70% of the heating value of the fuel) to heat the house (hydronic or water-to-air systems) and make domestic hot water. These systems are not yet widely available. They are likely to have the best economics in houses with high heating bills because the house cannot be feasibly insulated, such as solid stone or brick homes.
https://smarterhouse.org/heating-systems/types-heating-systems
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