*Residential Service call's subject to $119.00 travel and diagnostic fee, Commercial Service call's subject to a $149.00 travel and diagnostic fee. Once diagnosed, necessary repairs will be quoted in accordance with standard flat rate repair price. Repair and quoted repair price may be accepted or declined by the customer at that time. Travel and Diagnostic fee will still apply in case customer declines repair. All calls are C.O.D. Overtime rates for Residential Service are $169.00, overtime rates for Commercial services are $179.00. These rates are for services performed after normal business hours Monday through Friday 8am-4:30pm.
If your air conditioning system is not properly installed, it simply cannot be expected to operate at peak performance and efficiency levels. Make sure that your air conditioner is carefully selected and expertly installed so that you get the exceptional performance you deserve from it. Call now to schedule your AC installation with a skilled Issaquah air conditioning installation professional.
When we’re in a customer’s home, we’re always on the lookout for things we can do to help them out and put a smile on their face. It could be as simple as changing a lightbulb or as involved as cleaning gutters, listing a car for sale online, or repairing a broken gate. There’s no limit to what we might do, and of course, there’s never any charge to help out. It’s good deeds for FREE!
For a scheduled or emergency HVAC repair, you can count on SMO Energy and our team of certified technicians. We’re ready 24 hours a day and seven days a week to fix your heating system and deliver the professional and courteous service you expect from our family-owned and operated business. Aside from your system shutting down, several other signs that your HVAC system needs repairs include:
This type of furnace is fueled by liquid propane gas, which is burned to push hot air through your home. A pilot light ignites the burners within a combustion chamber, which push heat into the heat exchanger and eventually through your entire home. Repairing this type of furnace can be more expensive than its electric alternative. For example here are some common propane gas repairs and their costs:
According to a 2015 government survey, 87% of the homes in the United States use air conditioning and 65% of those homes have central air conditioning. Most of the homes with central air conditioning have programmable thermostats, but approximately two-thirds of the homes with central air do not use this feature to make their homes more energy efficient.
Understanding all of your home’s heating and cooling parts for the North America climate is probably a little unrealistic, but there are a few things that can be helpful to you as a homeowner. If you’d like more information about your current system and whether an air handler or air conditioner is right for your home, give the experts at Service Experts a call at 866-397-3787 or set up a free appointment online today.
Any forced air system in your home - whether it is powered through electric or gas-generated energy - requires a blower motor. This component consists of an electric motor and fan, and is responsible for pushing air evenly through the furnace. As hvac.com points out, you can easily identify the blower motor in your furnace as the part that looks similar to a hamster wheel at the bottom of the unit. If it stops working, the air needed to heat your home will no longer be pushed through the furnace to be heated and distributed evenly. In that case, you need to inquire about potential repairs. Blower motor repair typically costs between $150 for a simple fix, and $450 for complete replacement and installation of the part. Where you land on that range depends on the exact damage.
Air-source heat pumps are more popular in milder winter climates where the temperature is frequently in the range of 4–13 °C (40–55 °F), because heat pumps become inefficient in more extreme cold. This is because ice forms on the outdoor unit's heat exchanger coil, which blocks air flow over the coil. To compensate for this, the heat pump system must temporarily switch back into the regular air conditioning mode to switch the outdoor evaporator coil back to being the condenser coil, so that it can heat up and defrost. A heat pump system will therefore have a form of electric resistance heating in the indoor air path that is activated only in this mode in order to compensate for the temporary indoor air cooling, which would otherwise be uncomfortable in the winter.
SEER is related to the coefficient of performance (COP) commonly used in thermodynamics and also to the Energy Efficiency Ratio (EER). The EER is the efficiency rating for the equipment at a particular pair of external and internal temperatures, while SEER is calculated over a whole range of external temperatures (i.e., the temperature distribution for the geographical location of the SEER test). SEER is unusual in that it is composed of an Imperial unit divided by an SI unit. The COP is a ratio with the same metric units of energy (joules) in both the numerator and denominator. They cancel out, leaving a dimensionless quantity. Formulas for the approximate conversion between SEER and EER or COP are available.
In the case of direct expansion equipment, the air passing over the indoor cooling coil heats the cold liquid refrigerant. Heating the refrigerant causes boiling and transforms the refrigerant from a cold liquid to a warm gas. This warm gas (or vapor) is pumped from the cooling coil to the compressor through a copper tube (suction line to the compressor) where the warm gas is compressed. In some cases, an accumulator is placed between the cooling coil and the compressor to capture unused liquid refrigerant and ensures that only vapor enters the compressor. The compression process increases the pressure of the refrigerant vapor and significantly increases the temperature of the vapor. The compressor pumps the vapor through another heat exchanger (outdoor condenser) where heat is rejected and the hot gas is condensed to a warm high pressure liquid. This warm high pressure liquid is pumped through a smaller copper tube (liquid line) to a filter (or filter/dryer) and then on to an expansion device where the high pressure liquid is reduced to a cold, low pressure liquid. The cold liquid enters the indoor cooling coil and the process repeats.