CO2 saving processes
Waste Heat Recovery Unit
Increasing economic efficiency and reducing the CO2-emissions with energy recovery units in your industrial process.
How does a GEA Waste Heat Recovery Unit work?
The WHRU operates -often in conjunction with the Organic Ranking Cycle (ORC) due to the temperature ranges involved- transferring heat from flue gas to another medium through a heat exchanger, which can then be utilized locally or transported across the production site for various applications such as waste gas treatment, district heating or power generation.
GEA delivers customized heat exchanger designed for each specific application, adjusting to factors like gas flow velocity, pipe dimensions and flue gas composition. This tailored approach, backed by GEA's extensive industrial experience across diverse sectors, ensures optimal performance and efficiency for each unique WHRU installation.
Benefits of a Waste Heat Recovery Unit
- Optimized design.
- Self-cleaning operation for enhanced plant availability and efficiency.
- Continuous Online Cleaning System for managing high dust contents exceeding 10g/m³ std. as well as dry, sticky and/or abrasive dust.
- Operational cost reduction of up to 25%.
- Flexibility in Heat Transfer Media.
- Both for thermal oils and pressurized water systems.
WHRU in the Cement Industry
Process for WHRU in the Cement Industry
GEA has been supplying heat recovery systems for the cement industry for more than a decade.
Both on the raw gas side upstream of an emission control system as well as downstream of an emission control system: GEA offers tried and tested waste heat recovery system that do not impact your production process while recovering a large amount of waste heat. On the raw gas side with sticky dust an online cleaning system is applied to keep heat transfer at an optimum over years. With this, GEA supplied WHRUs up to 6.1 MW thermal power, converting it to 1 MW of electrical energy via the ORC process and/or powering your SCR as well.
Currently applied to the glass industry for power generation via an ORC or for heating purposes, the system is ready to utilize waste heat for a CEBO® Carbon Capturing unit instead.
WHRU in the Glass Industry
Process for WHRU in the Glass Industry
Thanks to GEA's expertise in emission control, the deposition of flue gas components on the heat exchanger surface is prevented to achieve very good heat transfer performance with minimum maintenance costs.
By additionally recovering heat from the clinker cooler side, either to operate a tail-end SCR unit or in combination with heat recovered from the kiln flue gas to supply the ORC process, thermal losses are reduced to an economical minimum. While GEA’s WHRUs already pays for itself by direct heating or electrical power generation now, it enables you to capture carbon dioxide emissions in the future by powering our CEBO® Carbon Capturing unit, complying with upcoming environmental regulations.
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GEA Insights
GEA opens new technology center, strengthening its position in the growing pharmaceutical applications market
Together with Mona Neubaur, Minister of Economic Affairs of the German state of North Rhine-Westphalia, GEA CEO Stefan Klebert has opened a new technology center for pharmaceutical freeze-drying systems in Elsdorf, Germany. GEA employs approximately 260 people at the facility, which combines research and development with production and service under one roof.
Energy saving is a key success factor when trying to achieve a reduction of the carbon footprint, it can be made by improving process efficiency to recover waste heat, not only from the production process, but also from the hot process gas that in many cases is simply released into the atmosphere, unutilized.
The saving of energy costs and the reduction of CO2 emissions by avoiding fossil fuels make an Energy Recovery Plant an investment that not only provides competitive advantages that positively impact the final product cost, but also helps preserve our environment for the future generations.
GEA offers WHR (Waste Heat Recovery) units alone or in combination with gas cleaning technologies as well, using heat exchanger systems suitable for waste gas conditions such as dust content.
These heat exchanger units have been used in diverse projects worldwide and have proven reliable and highly efficient.
Usually, the GEA energy recovery system consists of:
- Waste Heat Recovery Units
- ORC module
The heat recovered from the flue gas can be used for:
- power generation
- compressed air production by use of thermal oil
- local and district heating networks
- heat for industrial processes
Particular features
- Process-optimized heat recovery
- High serviceability
- High modular flexibility, apt for narrow spaces
- Quick ROI (Return of Investment), sustainable reduction of energy costs
- Electricity production by ORC (Organic Rankine Cycle) technology
Working Principle
Working Principle of Energy Recovery from Flue gasesThe largest sources of waste heat for most industries are exhaust and flue gases. Either as high-temperature gases from burners or at lower temperatures within the air treatment process.Cement industry
Waste heat can be recovered from the clinker cooler waste gas as well as the preheater waste gas. Different heat exchanger systems shall be used for the two waste gases, because of the difference in dust content.
The heat can be used for the operation of an ORC turbine for power generation or to generate hot thermal oil or water for other uses.
The use of the heat energy in the gas cleaning process in the SCR is possible as well:
Process for WHRU in the Cement Industry
Glass industry
Depending on the available gas temperature upsteam and downstream the gas cleaning, the waste heat can be recovered at two different stages of the cycle.
Process for WHRU in the Glass Industry
