Air Source Heat Pump
Heating and cooling typically combine to be a home’s biggest energy use and its biggest contributor to greenhouse gases. With super-efficient heat pump technology, however, you can stay comfortable and still tame your carbon footprint. A bonus is that some heat pumps can also cool your home when it gets too hot.
$6,000 - $15,000
About the technology
Is it New?: Heat pumps have been used for heating and cooling for decades in some areas. However, with improved technology (such as low-temperature heat pumps), they’re becoming more popular than ever and expanding into new regions.
How it Works: Heat pumps use electricity to move heat from one place to another, instead of creating the heat directly, as in a gas furnace or boiler. This is what makes them so efficient when compared to conventional heating systems.
Applicable Types of Heat Pumps: Various types of heat pumps are available to match a home’s particular needs. For example, air-to-air heat pumps (which can also provide cooling) can be used in many types of homes, including those with forced-air ventilation systems. Air-to-water heat pumps are more compatible with homes containing hydronic heating systems that employ radiators or underfloor heating.
Economics: Heat pumps are generally more expensive to install than a conventional space conditioning system, but incentives are sometimes available that can help with this higher cost. Also, you can sometimes save money on your energy bills going forward, especially if you’re switching from heating with electricity, propane/LPG, or oil. If you combine a heat pump with rooftop solar, the economics can improve even more.
Environment: Heat pumps almost always help to reduce your greenhouse gas emissions. This is because they use electricity, and in a very efficient way. Also, as grid-supplied electricity becomes cleaner over time, heat pumps will have an increasing environmental advantage over conventional heating systems.
Frequently Asked Questions (FAQ)
1. What is a heat pump?
A heat pump, such as a common refrigerator, is a device that moves heat from one place to another but does not generate any heat of its own. Usually the flow of heat follows the temperature gradient from higher to lower temperature. However, a heat pump uses a compressor, heat exchangers, and other components to evaporate and condense a refrigerant at selective places to move the heat against a temperature gradient, much like a water pump moves water against the force of gravity.
2. What are some everyday uses of heat pumps?
A refrigerator uses a small heat pump to move heat from the inside of the refrigerator to the surroundings, cooling your food. An air conditioner (AC), which moves heat from inside a house to the outside against a temperature gradient, is another example. Similarly, an air source heat pump (ASHP) moves heat from inside to outside during the summer, functioning as an AC. In the winter, it has a mechanism to reverse the flow of heat and move heat from the cold outside to the warm inside, acting as a space heater.
3. What are the major components?
A system has various components, including a compressor, outside and indoor heat exchangers, refrigerant (with associated piping), valves, and controls/wiring. These components work with a forced-air system, such as a blower that transfers the heat/cool to the interior of your home. Some heat pumps have integrated blowers and some rely on separate blowers and ducting.
4. What types of air source heat pumps are available?
The most common forms of air source heat pumps are: 1. ducted systems that use air ducts inside the house and a central heat exchanger to condition the air flowing through the ducts, and 2. split systems that use one or more registers inside the house to condition the space directly without using air ducts.
5. How does an air source heat pump differ from a gas furnace?
First, an air-source heat pump provides not only space heating, but also cooling. By reversing the thermodynamic cycle, this one device can help keep you comfortable in both the winter and summer. A heat pump is also more efficient because it’s designed to move heat, not create it. Operationally, a heat pump takes longer to heat a home from a low temperature than does a natural gas furnace. Accordingly, they’re generally used in a way that keeps a home at a more even temperature throughout the day.
When it comes to carbon pollution, air source heat pumps have an advantage over other types of space heaters because of their greater efficiency. The amount of the carbon reduction depends on the carbon intensity of the electricity used to power your heat pump and the energy source that you’re switching from (such as natural gas, electricity, etc.). If you add rooftop solar to your home, the carbon footprint of running a heat pump is drastically reduced.
6. Can you set back the temperature when heating with an air source heat pump?
It is advisable to use small setbacks with a heat pump since the heating process takes longer than with other forms of heating, such as a natural gas furnace. By maintaining a relatively uniform temperature, the temperature recovery time is reduced.
7. Are split systems more efficient than ducted systems?
In general, split systems are more efficient than ducted systems. This is partly because they avoid the energy losses associated with ducting, which can be substantial in some cases. Also, the temperature setting of each register inside the house can be controlled separately, so the heating or cooling of the house can be more easily fine-tuned, thereby saving energy.
1. How expensive are heat pumps?
The installed costs of air source heat pumps depend on a variety of factors, such as the type of heat pump, home size, location, need for additional wiring, etc. While they are typically more expensive than conventional heating or cooling systems, an advantage is that you only need one heat pump to cover both heating and cooling. Also, incentives can help to reduce a HP’s cost. For example, for income-qualified households, the Warmer Kiwi Homes programme offers rebates that can cover up to 80% of the cost of a heat pump (up to a maximum of $3,000) in certain situations. Numerous site-specific factors affect the installed costs of a heat pump, so it’s always a good idea to get cost estimates from local professionals.
2. Will I save money compared to a gas furnace for heating?
This depends on the prices of natural gas and electricity in your area, your typical winter temperatures, etc., but in general, you can expect to save money.
1. What kind of regular maintenance is needed?
Maintaining the efficient operation of your heat pump generally involves activities like periodic cleaning of debris and dust that has collected in and around coils, cleaning/replacement of filters, and checking of the condensate drain. Some experts suggest annual maintenance visits by a professional to identify issues before they become full-blown problems.
2. If the heat pump cools and heats year round, does it wear out more quickly than an air conditioner?
Covering both winter and summer means that a heat pump will log more operating hours than a traditional AC system. Accordingly, it would normally have a shorter expected lifespan, but it would depend on how often the cooling function of the heat pump is used.
1. Do heat pumps reduce greenhouse gases?
Yes, air source heat pumps almost always help to reduce GHG emissions. The amount of the reduction depends on the carbon intensity of the electricity used to power your system and the energy source (such as natural gas, electricity, etc.) you’re switching from. If you add rooftop solar to your home, the carbon footprint of running a heat pump can become negligible. Additionally, as grid-supplied electricity becomes cleaner over time, heat pumps will have an increasing environmental advantage over conventional heating systems.
1. How is a heat pump installed?
This will depend on the type of heat pump being installed. A ducted system’s installation is generally similar to that of a central AC system. A split system will require the additional step of mounting one or more indoor registers inside your home. Depending on the complexity of the system, projects often take from 1 day to a week.
2. Should I get a ducted system or a split system?
Split systems are normally recommended if the house does not have air ducts, or if extensive rework would be needed on the ducts. If existing ducts can be used, then a ducted system is often recommended.
3. How many indoor registers are needed with a split system?
In answering this question, a number of factors come into play such as house construction/orientation, number of rooms, and specific heating/cooling needs associated with each room. In some cases, a register will be needed in each room, but this is not always the case. Multiple registers (as many as eight) can be linked to an outside unit, and in larger homes, two outside units are sometimes employed.
1. What types of incentives are available?
For income-qualified households, the Warmer Kiwi Homes programme offers rebates that can cover up to 80% of the cost of a heat pump (up to a maximum of $3,000) in certain situations.