Numerical investigation on rock‐breaking mechanism and cutting temperature of compound percussive drilling with a single PDC cutter

Wang, Wei; Liu, Gonghui; Li, Jun; Zha, Chunqing; Lian, Wei; Gao, Rui

doi:10.1002/ese3.990

Cited by 12 publications

(2 citation statements)

References 32 publications

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“…Here, when . The yield surface conforms to the Mises yield criterion with regard to a circular yield surface 42 – 44 . where is the elastic–plastic damage yield function; is another form of partial stress, is the principal stress; is another form of internal cohesion; is the partial stress; is the tensile strength-compressive strength ratio; is the friction angle of yield surface on the - stress surface.…”

Section: Experimental Preparation and Load-damage Numerical Modelmentioning

confidence: 80%

Destabilization damage characteristics and infrared radiation response of coal-rock complexes

Li,

Shi,

Jiang

et al. 2024

Sci Rep

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To investigate the characteristics of destabilization damage in coal-rock complexes. Mechanical property tests were conducted on coal, rock, and their complexes. An infrared thermal camera was employed to real-time monitor the infrared (IR) radiation response signals during the destabilization damage process. A numerical model of coal-rock destabilization damage was developed, and its validity was verified. Deformed stress fields and displacement contours were obtained during the destabilization damage process. Upon destabilization, numerous cracks form at the base of the “coal” section, extending towards the interface, resulting in the formation of a wave-like deformation region. The differentiation in infrared thermal images is more pronounced in the “coal” section compared to the “rock” section. A high-stress region is evident at the interface, resulting in an area of high stress differentials. However, the bottom of the “coal” section also exhibits a region with high stress differentials and a more pronounced tendency towards destabilization damage. Displacement contours revealed that numerous units at the bottom of the “coal” section had slipped and misaligned, leading to the accumulation of damage and an elevation in the local damage level. It is a crucial factor contributing to the notable phenomenon of IR thermal image differentiation.

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Section: Experimental Preparation and Load-damage Numerical Modelmentioning

confidence: 80%

Destabilization damage characteristics and infrared radiation response of coal-rock complexes

Li,

Shi,

Jiang

et al. 2024

Sci Rep

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show abstract

“…Notwithstanding, the FEM, as a mature numerical method, has been successfully applied in PDC cutting simulations, as demonstrated in Refs. 24–29. It is also possible to combine the good features of both approaches in single code where the distorted finite elements are converted to particles governed with the smooth particle hydrodynamics method (coupled FEM/SPH method), as is done in the above‐mentioned numerical studies 3,5 on hybrid drilling techniques.…”

Section: Introductionmentioning

confidence: 99%

Numerical modelling of thermal jet assisted rock cutting with double PDC cutters

Saksala

2024

Num Anal Meth Geomechanics

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Preconditioning of rock for drilling operations is a potential method to facilitate the mechanical breakage and mitigate the tool wear. This paper numerically investigates one such preconditioning technique, namely, the thermal jet assisted rock cutting. For this end, a numerical method for solving the governing thermo‐mechanical problem is developed and validated. The continuum approach is chosen to describe the rock failure, being based on a damage‐viscoplasticity model with the Drucker–Prager yield surface and the modified Rankine surface as the tensile cut‐off. In the damage part, separate scalar damage variables are employed for tension and compression. The cutters are modelled as rigid bodies and their interaction with the rock is modelled by imposing contact constraints by the forward increment Lagrange multiplier method, which is compatible with the chosen explicit time integration scheme. A damage‐based erosion criterion is applied to remove the contact nodes surrounded by heavily damaged elements. The thermal jets are modelled with a moving external heat flux boundary condition. The global thermo‐mechanical problem is solved with a staggered approach explicitly in time while applying mass scaling to increase the critical time step. The novel 3D numerical simulations involving two cutters demonstrate the capabilities of the method with a special emphasis on cutter‐thermal jet configurations. Therefore, the present method provides a potential tool for the bit design in thermal jet assisted drilling.

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Cracking Behaviors of Rocks Subjected to the Dynamic Percussion of a Single PDC Cutter: A Finite-Discrete Element Study

Sun,

Huang,

Zou

et al. 2024

Rock Mech Rock Eng

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Numerical investigation on rock‐breaking mechanism and cutting temperature of compound percussive drilling with a single PDC cutter

Cited by 12 publications

References 32 publications

Destabilization damage characteristics and infrared radiation response of coal-rock complexes

Destabilization damage characteristics and infrared radiation response of coal-rock complexes

Numerical modelling of thermal jet assisted rock cutting with double PDC cutters

Cracking Behaviors of Rocks Subjected to the Dynamic Percussion of a Single PDC Cutter: A Finite-Discrete Element Study

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