Looking beyond our GWP ‘tunnel vision’

What gets measured gets managed is a truism of our age. But in the case of refrigerants, is a heavy reliance on one measurement concealing the full sustainability story?

Adrian Bukmanis, founder of Veridian Refrigerant Management, believes so. He presented at AIRAH’s recent Future of HVAC Conference on the topic “No longer immaterial: The life-cycle impact of refrigerants.”

Material concerns

Bukmanis notes that when it comes to low-GWP refrigerants, the current focus on emissions in use. That is, the impact of refrigerant leaking from active HVAC&R equipment.

“This tends to give us a tunnelled view,” he says. “We should also consider the manufacturing emissions and the disposal emissions.”

For common high-GWP refrigerants, such as many HFCs, Bukmanis agrees that the bulk of the emissions are probably in the use phase, and the manufacturing and disposal emissions could be considered as relatively immaterial.

“However, if we’re looking at low-GWP refrigerants, and especially if we’re looking at synthetic or HFO refrigerants, we might find that the manufacturing and disposal is greater than the in-use emissions,” he says.

“We also have pollution impacts, both upstream and downstream, for synthetic refrigerants, that I would consider are not immaterial.”

There are number of tools available for evaluating refrigerants: global warming potential (GWP), total equivalent warming potential (TEWI), life cycle-climate performance (LCCP), and life-cycle assessment (LCA). Bukmanis says that if we want to look at all environmental impacts, LCA is perhaps the best tool available.

“But it’s hard to get this data, and hard to find the refrigerants in the databases,” he says. “You need to know their chemical names or structures. And it’s not consistent across the databases.

“There’s information for example for R134a, but it’s very hard to find information on R1234yf, given it’s heavily patented and there is little transparency in the manufacturing process.”

LCA is a useful tool, Bukmanis says, but it doesn’t provide all the answers.

Look under the bonnet

As an alternative, Bukmanis suggests we should consider how refrigerants are made.

Manufacturing HFCs is a complex process. They requires fluorine, a base hydrocarbon such as ethylene, and for some pathways sulfur, lime and chlorine – all of which must be extracted from mines or other sources. There’s also the electricity, steam and nitrogen that goes into production.

Partly because of this complexity (as well as the variables that come into play depending on where a refrigerant is manufactured), embodied emissions in refrigerants can vary widely. Estimates from the few studies that do exist suggest that 1kg of R134a could contain anywhere between 5kg and 87kg of embodied CO2e. In this case, upstream emissions are relatively small compared to potential in-use emissions.

For newer low-GWP refrigerants such as R1234yf that are shrouded in patents, the numbers are even harder to confirm. Bukmanis says, however, there are some well-established issues that should be considered.

“We do know that ozone depleting chemicals are used to make low-GWP fluorinated refrigerants, in particular the feedstocks HCFC-22 (R22) and carbon tetrachloride.”

Although ozone depleting substances are being phased out under the Montreal Protocol, their production is allowed for feedstocks, because in theory they are not emissive during the manufacturing process. But as Bukmanis points out, there is a small percentage that escapes.

Moreover, we are producing increasing quantities of these feedstocks – 800,000 tonnes of HCFC-22 in 2022, up from 200,000 tonnes in 2002. Hence even small fugitive emissions are starting to stack up.

“It surprises a lot of people that we’re now producing more ozone depleting substances than we’re actually producing HFCs,” says Bukmanis. “It’s becoming a material concern.”

There are also unwanted byproducts of the production process, for example R23 (GWP 14,600) and PFC318 (GWP 10,200). Global emissions charts for these chemicals show that they are both increasing. It is worth noting that another ozone depleting substance, dichloromethane, can be used as a feedstock in the manufacture of R32, which has become the default refrigerant for many types of air conditioners.

“Depending on how we do our assessment,” says Bukmanis, “we can end up with quite a large upstream impact.”

Going with the flow

As well as looking closely at upstream impacts, Bukmanis says the same scrutiny should be applied downstream for refrigerant disposal.

Australia is lucky to have a world-leading program and cutting-edge plasma arc facilities for destroying refrigerants at end of life. But that is not the case in the rest of the world, where most of the six million tonnes of the global refrigerant bank are found. And even in the best facilities, refrigerant destruction uses energy.

“The thing that makes synthetic refrigerants so good and gives them their stability and inertness also makes them really hard to break down,” says Bukmanis, “It can take more than 1,000kWh of electricity just to destroy one tonne of fluorinated refrigerant.”

Again, for high-GWP refrigerants, this downstream impact may be relatively small compared to in-use emissions, but for low-GWP options, it is more significant.

Finally, other environmental impacts need to be considered, says Bukmanis. This includes manufacturing, transport and distribution emissions, byproducts, and toxic releases.

In September 2021, the US EPA published an impact analysis of phasing down HFCs, which contemplated the toxic releases found near synthetic refrigerant manufacturing facilities.

“The health impacts are not immaterial,” says Bukmanis.

Similarly, refrigerant destruction can produce acid gases, dioxins/furins, particulates, CO2 off-gas and carbonyl fluoride.

And this is all before considering the environmental impacts during the operational phase. Concerns have been raised about HFO refrigerants breaking down into TFA – an ultra-short-chain PFAS – which is highly persistent and highly mobile in the environment.

Real zero

“We need to get to real zero,” says Bukmanis, “and not the bad net zero with a slow transition.

“All emissions need to be considered and we need to look beyond just the climate impacts. We also need to look for more transparency where we can. Those who have leverage and the ability to put some pressure on their suppliers should ask questions about where their refrigerants are coming from, and where and how they’re produced.

“And there needs to be a quick move away from fluorinated refrigerants to non-fluorinated alternative natural refrigerants. The production process and the disposal process are much easier with non-fluorinated refrigerants.”

Bukmanis gives the example of CO2, which in some facilities requires about 0.5kg to produce 1kg of CO2 at refrigerant grade. It can also be more easily repurposed at end of life.

“We need to look upstream and downstream,” Bukmanis says, “and then proceed carefully with our refrigerant selection.”

Photo by Jakob Søby on Unsplash

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