The proposed project is aimed to investigate an innovative heat pump utilizing the Ericsson thermodynamic cycle in early
concept stage. The proposed system is a new technology that could reduce the energy demands in many areas. The
proposed project fits the scope in engines & thermodynamic cycles, and energy efficiency.
The proposed mechanical heat pump utilizing the Ericsson thermodynamics cycle would have near Carnot Cycle ideal
efficiency due to unique innovations of the design:
1) Flat rotors that create the optimum heat exchange area;
2) Independent Induction Motor Generators allow continuously variable rotor rotational velocity and thus compression ratio,
volume, and compression rate, allowing near isothermal compression and expansion;
3) Continuous cycling of the fluid allows for near Isobaric heat exchange in varying conditions;
4) Efficient and simple Induction Motor-Generators - requiring no mechanical linkage and allowing the device to be
hermetically sealed with the inner stator within, greatly increasing service life;
5) Separate, compression, heat exchanger, and expander chambers mean no wasted work on 'dead air', and no thermal
creep between parts of the device, thus eliminating efficiency losses of other systems;
6) Continuous cycling with constant fluid compression, heat exchange, and expansion, unlike other systems;
7) Use of clearance seals eliminates traditional sealing issues. Only four moving parts, no valves, and hermetically sealing
the device and allows very long service life.
The proposed Ericsson heat pump would provide efficient and environmentally friendly cooling. The majority of coolers,
refrigerators, and air conditioners today are based on the vapour compression cycle using CFC's (Freon). Although
efficient, the use of CFC's has significant detrimental environmental issues and its discontinued use is mandated. The
proposed Ericsson system would provide an extremely low maintenance, highly efficient engine able to draw energy from
solar, geothermal, waste heat, and most any other energy source. The engine would be silent and vibration free, making it
applicable to many other applications.
The development of the proposed Ericsson heat pump/engine would provide huge global market opportunities for which the
UK can develop and grow innovative businesses to deliver world-leading solutions.
The unknown factors and risks in this development make it difficult for the partners to take on and the Innovate UK funding
would provide the essential support to enable the consortium expertise areas to come together and create a novel system
creating many jobs across the supply chain with energy consumption per unit cut by 40%, Payback time: 1.5 to 3 years,
and saving about 20 tonnes of CO2 per unit (5kW) per year, achieving UK's Government target.
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