Developing Kilometers-long Gravity Heat Pipe for Geothermal Energy Exploitation
Abstract
At medium-deep and deep depths of Earth crust lays vast and so far mostly untapped reserves of geothermal energy. This energy source has the potential of meeting humanity’s needs for thousands of years. However, its large-scale deployment has been hindered by a lack of effective and dependable exploitation technologies. Gravity heat pipes have recently garnered significant attention due to their exceptional heat transfer capability and their ability to harness geothermal heat without water-mining. Nevertheless, the challenge of extending gravity heat pipes to depths sufficient for deep geothermal energy exploitation still persists. In this study, we introduce an innovative ladder-structure inner pipe design to overcome this shortcoming. This design incorporates a series of stepped ladders and small condensate guiding pipes, allowing for the development of super-long gravity heat pipes (SLGHPs). Combined with an optimal working fluid, this novel structure enables kilometers-long gravity heat pipes. As a direct outcome of this innovation a 4,149-meter SLGHP using ammonia as the working fluid was constructed and installed in a geothermal well. The SLGHP geothermal system demonstrated the ability of a continuous heat output exceeding 1 MW, with a heat flux across the radial section of the SLGHP reaching 4x107 W/m2. Furthermore, an ammonia vapor-driven power generator was developed and integrated with the SLGHP system. During a 72-hour test, this generator successfully produced electricity at a steady rate of approximately 7 kW. The breakthrough design of SLGHPs holds the potential of unlocking Earth’s deep geothermal energy reserves, providing a sustainable and reliable energy source for generations to come.