If there was any doubt about the seriousness of the climate change threat, a series of alarming reports from the United Nations over the past two years have surely put them to rest: the scientific evidence overwhelmingly shows that climate change is happening and that it poses an existential threat to human life on earth.

Because they require to use so much energy in turning raw materials into usable goods, manufacturers play an essential role in the fight against climate change, and in many cases, they are responding by turning to technological innovations that help them reduce their reliance on fossil fuel energy.

One of the key ways in which this is happening is through efforts to make manufacturing processes more efficient.

The Importance of Efficiency for Reducing Fossil Fuel Use

In most industries, it is simply not possible to switch over to renewables immediately. But by reducing overall energy use, manufacturers can reduce the amount of fossil fuel resources needed to fuel their operations.

In many cases, this means tackling the huge amount of energy waste involved in heat exchange. Heating, drying, and cooling bulk solids is both essential for the production of most modern goods, and also incredibly energy-intensive.

For this reason, finding ways to make heat exchangers more efficient plays an important role in overall energy reduction strategies designed to make factories more energy efficient.

The problem is that most traditional heat exchange technologies rely on air, gas, or fluids that need to be heated or cooled, and there are few ways to do this effectively that don’t require huge energy inputs.

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How a Heat Exchange Revolution is Making Factories more Efficient

This has led some heat exchanger producers to turn to completely different materials to make heat exchanging more efficient.

Some of the most successful examples, which are currently playing an important role in making factories more efficient, are ceramic plate heat exchangers that use the power of gravity to effect heat exchanges.

Because ceramic plates are excellent at holding heat, they can be used to transfer and store energy in a much more predictable and controlled way. Studies have shown that heat exchange processes that rely on this kind of ceramic plate exchanger can reduce energy use by as much as ninety percent (you can click here if you want to read up for more info about how these heat exchangers work).

In the long term, avoiding the worst effects of climate change will require concerted efforts on the part of governments and industries around the world to switch over entirely to renewable energy sources like wind, solar, hydroelectricity, biomass, and nuclear power.

In the meantime, however, major progress on fossil fuel reductions can be made by making factories around the world more efficient without cutting into their productivity.

By helping manufacturers reduce the major energy investments involved in operating heat exchange functions, greener heat exchangers are leading the way in this struggle.