Propagation of Cryogenic Thermal Fractures from Unconfined PMMA Boreholes

In cryogenic fracturing, a rock surface exposed to cryogenic fluids undergoes a large thermal gradient, and the resultant local tensile stress overcomes rock strength and initiates fractures. This study investigates the development of cracks generated from the cryogenic treatment of a borehole under no external confining stress on specimens. The experiments were performed on transparent PMMA specimens to observe fracture proliferation around boreholes. Liquid nitrogen was flowed through the boreholes to cool the borehole surface. The results show that initial fracture growth is characterized by abrupt starts and stops, and as the fracture propagates outward, the growth appears more continuous. In an early stage, horizontal/radial fractures and vertical fractures are the defining patterns. Horizontal fractures tend to be separated by a specific exclusion distance (i.e., spacing between cracks). While distinct horizontal/vertical fractures and exclusion distance manifest themselves at an early stage, fractures resulting from fracture interactions and curvatures can develop into complex shapes at later stages. Cryogenic thermal loading induces distinctively curved fractures. The tendency of curvature may prevent greater penetration. An increase in the borehole pressure during liquid nitrogen flow, however, can lessen fracture tortuosity and facilitate radial propagation. A high flow pressure and rate are also advantageous in that they accelerate cooling and fracture propagation.

Automated summary

Cryogenic fracturing involves exposing rock surfaces to cryogenic fluids, which creates large thermal gradients and generates local tensile stress that initiates fractures. Experiments conducted on transparent PMMA specimens show that initial fracture growth is abrupt, with distinct horizontal/radial and vertical fractures separated by specific distances. Fractures resulting from interactions and curvatures can develop into complex shapes, with cryogenic thermal loading inducing curved fractures. Increased borehole pressure during liquid nitrogen flow can lessen fracture tortuosity and promote radial propagation, while higher flow pressure and rate accelerate cooling and fracture propagation.