Replacing gas heating with reverse-cycle aircon leaves some people feeling cold. Why? And what's the solution?

Researchers^[1] and policymakers^[2] are advocating all-electric housing to reduce energy bills and emissions^[3]. Using energy-efficient reverse-cycle air conditioners^[4] is a core element of the shift from gas.

However, not everyone is happy with the change. “I just don’t feel warm,” said some people we interviewed^[5] after they switched to reverse-cycle air conditioning.

Others are very happy with the comfort, hundreds of dollars in savings^[6] and low lifetime carbon emissions^[7].

How can different people have such varied experiences with the same technology? Our computer modelling of air flows in the home offers an answer: the quality of the building’s insulation makes a big difference to how people feel with reverse-cycle heating.

Read more: All-electric homes are better for your hip pocket and the planet. Here's how governments can help us get off gas^[8]

What’s different about this heating?

Reverse-cycle air conditioners are different from traditional gas or electric heaters. They produce warm, not hot, air, and the unit is usually mounted high on a wall. This is a suitable position for cooling but not so effective for heating.

When cooling, output air cools the hot air near the ceiling and the air movement provides a complementary cool breeze.

In heating mode, the warm outlet air cools down as it flows along surfaces such as the ceiling, external walls, windows and floor and mixes with cool air. It is then drawn back to the air conditioner where it is reheated.

If the building is poorly insulated and has single-glazed windows, the surface temperatures in the home are low and heat losses and temperature drops are high. The cooled air flowing close to the floor creates a “wind chill” effect – it feels like a cold draught.

Also, our warm bodies radiate heat to the cold surfaces of the walls and windows. This means we tend to feel even colder when we are near them.

In contrast, the surfaces of insulated walls, ceilings, floors and windows stay warmer and allow much less heat loss. When the heated air touches them, it stays relatively warm as it flows back to the air conditioner to be reheated. The air circulating in the room is warmer, which reduces the “wind chill” effect.

Because the surfaces of insulated walls and windows are much warmer, our bodies also radiate much less heat to them, so we feel warmer.

Read more: Cooking (and heating) without gas: what are the impacts of shifting to all-electric homes?^[9]

Our modelling shows these effects

We modelled the heating energy and temperature distributions in a living room of a 1960s home. It had large areas of glazing on two side walls, an internal end wall and a reverse-cycle air conditioner mounted high on the external end wall.

Case 1 was uninsulated with single glazing. Case 2 had insulated walls, ceiling and floor and double glazing.

The temperature distributions are shown below.

References

1. ^{^} Researchers (theconversation.com)
2. ^{^} policymakers (www.premier.vic.gov.au)
3. ^{^} reduce energy bills and emissions (theconversation.com)
4. ^{^} reverse-cycle air conditioners (austclimate.com.au)
5. ^{^} interviewed (cur.org.au)
6. ^{^} hundreds of dollars in savings (renew.org.au)
7. ^{^} low lifetime carbon emissions (grattan.edu.au)
8. ^{^} All-electric homes are better for your hip pocket and the planet. Here's how governments can help us get off gas (theconversation.com)
9. ^{^} Cooking (and heating) without gas: what are the impacts of shifting to all-electric homes? (theconversation.com)
10. ^{^} Want an easy $400 a year? Ditch the gas heater in your home for an electric split system (theconversation.com)
11. ^{^} thermal performance (www.yourhome.gov.au)
12. ^{^} heat pumps (theconversation.com)
13. ^{^} Heat pumps can cut your energy costs by up to 90%. It’s not magic, just a smart use of the laws of physics (theconversation.com)