Combined Heat and Power Technology

Combined Heat and Power Technology

CHP is the sequential production of two forms of useful energy — typically electricity and heat — from a single fuel source. CHP increases energy efficiency and reduces waste emissions by optimizing the use of heat that would otherwise be wasted when generating power. CHP systems can also improve power quality, reliability, and overall energy security.

Gas Heat Pump Rooftop Unit

CHP includes a large number of energy technologies. Thermodynamic analysis of these technologies (and combinations of technologies) can identify opportunities for efficiency gains. Also decisions of how to control temperature and how to split energy between power and heat can benefit from thermodynamic analysis to improve performance and reduce cost.

Natural gas power generation, particularly using turbines and advanced reciprocating engines, is an important segment of the energy production industry. These engines are used for distributed power generation, combined heat and power applications, and total energy systems. Maximizing efficiency and minimizing environmental impacts can translate into billions of dollars in savings for the U.S. economy.

Oak Ridge National Laboratory’s CHP Related R&D Experience Includes: 

  • Power Generation Technologies —internal combustion engines and turbines (including microturbines and steam turbines) 
  • CHP waste-heat-activated technologies – generation of hot water and steam, generation of chilled water through absorption cooling, industrial heat (process) applications 
  • Environmental - emissions controls, permitting 
  • Electric Grid - interconnection, microgrids, power quality, grid resilience 
  • Policy Issues - utility tariffs, interconnect processes 
  • Deployment Issues - Cost and performance benchmarking, market analysis, education and outreach, financing 

ORNL Research Focus Areas that Support CHP Related Technologies 

  • Additive manufacturing (heat exchanger production) 
  • Neutron science (heat exchanger performance/flow analysis) 
  • Advanced Computing, Data Infrastructure and Visual Analytics (grid modeling) 
  • Advanced Materials (catalyst materials) 
  • Equipment Performance Testing (environmental chambers, engine test labs, integrated systems laboratories)