Role of Rate and Temperature on Fracture and Mechanical Properties of PCD

Petrovic, Marin; Carolan, Declan; Ivanković, Alojz

doi:10.4028/www.scientific.net/kem.452-453.153

Cited by 9 publications

(15 citation statements)

References 3 publications

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“…where α = a / h, Pin is the breaking load and f(α) is a fitting function of α as outlined in (Petrovic et al, 2011).…”

Section: Low-rate Testsmentioning

confidence: 99%

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Thermal decohesion model validity for polycrystalline advanced ceramics

Petrovic¹,

Kljuno

2017

Int. j. adv. appl. sci.

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“…where α = a / h, Pin is the breaking load and f(α) is a fitting function of α as outlined in (Petrovic et al, 2011).…”

Section: Low-rate Testsmentioning

confidence: 99%

“…The low-rate three point bend flexural tests were performed using a standard screw-driven tensile testing machine (Petrovic et al, 2009;Petrovic et al, 2011). The plane strain fracture toughness is determined by the load at initiation method according to ASTM E1820-01 fracture standard:…”

Section: Low-rate Testsmentioning

confidence: 99%

Thermal decohesion model validity for polycrystalline advanced ceramics

Petrovic¹,

Kljuno

2017

Int. j. adv. appl. sci.

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“…tensile strength, transverse rupture strength, compressive strength, impact strength, fracture toughness and elastic constants as described below. The quasi-static Young's modulus of two grades of PCD has been determined at room temperature in [3]. Clearly, however, the availability of fracture and mechanical properties of PCD at low rates and low temperatures is not sufficient to satisfy industrial and academic needs, due to their irrelevance to in-service drilling conditions.…”

Section: Introductionmentioning

confidence: 99%

The mechanical properties of polycrystalline diamond as a function of strain rate and temperature

Petrovic

Ivanković

2012

Journal of the European Ceramic Society

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Polycrystalline diamond (PCD) materials are used in various applications, mainly as cutting tools for machining non-ferrous metals and non-metallic materials and for rock drilling operations. A better knowledge of their mechanical properties is of fundamental importance to PCD manufacturers and end users. In order to understand and predict the behaviour and structural integrity of the tools containing PCD, it is first necessary to study the behaviour of the material as a function of loading rate and temperature.In this paper, material behaviour is determined under testing conditions which correspond more closely to those in actual drilling, which is a significant improvement over investigations to date. Young's modulus determined by four-point bending and a split-Hopkinson pressure bar apparatus was relatively constant with the rate, while a consistent decrease was observed with increase of temperature. The flexural strength was found to increase with the temperature, while decreasing with an increase in rate.

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“…Strain gauges used were of MicroMeasurements type ZC-NC-G1262-120, which are free filament kanthal alloy gauges bonded by ceramic adhesive and with the measurement range of up to 1150°C. Figures 1a and 1b for G6 and G30 material, respectively, and compared with previously published quasistatic results [3]. At least three repeats at each combination of rate and temperature were conducted.…”

Section: Methodsmentioning

confidence: 99%

“…The fracture toughness of PCD was evaluated at a temperature of 600°C and 3 different dynamic loading rates: 0.3 m/s, 1 m/s and 5 m/s. The load at initiation method was used in the analysis, as previously explained in [3,4], which is sufficiently accurate even for the dynamic tests as the specimens were instrumented with the minute strain gauges close to the crack tip from which the load was extracted. Strain gauges used were of MicroMeasurements type ZC-NC-G1262-120, which are free filament kanthal alloy gauges bonded by ceramic adhesive and with the measurement range of up to 1150°C.…”

Section: Methodsmentioning

confidence: 99%

High Rate and High Temperature Fracture Behaviour of Polycrystalline Diamond

Petrovic

Ivanković

2011

KEM

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Abstract. Polycrystalline diamond (PCD) materials have a variety of applications, mainly as cutting tools for machining non-ferrous metals and non-metallic materials. A significant application of PCD is in oil and gas industry for rock drilling operations. Other important areas, such as mining, have yet to reach their full potential. These cutters/tools are subjected to high operating temperatures, impact loads and abrasive wear during these operations, which may lead to their sudden failure. An advantage of these materials is that their structure and composition can be engineered to return properties required for specific applications and operations.In this study, the mechanical and fracture properties of two grades of PCD have been determined at dynamic loading rates up to 5 m/s and elevated temperature up to 600°C in laboratory conditions using three point bending (TPB) and split-Hopkinson pressure bar apparatus (SHPB). The results show Young's modulus to be completely rate insensitive, while fracture toughness changes significantly. Two dominant regions can be observed on the rate scale: one predominated by the conductivity of the material and the other predominated by the rate of fracture where binder degrades locally at the crack tip. This behaviour was related to the material microstructure, where similarities and differences in the fracture of two different grades of PCD are shown examining polished fractured specimens using scanning electron microscopy, revealing mechanisms of fracture over the range of loading rates.

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Role of Rate and Temperature on Fracture and Mechanical Properties of PCD

Cited by 9 publications

References 3 publications

Thermal decohesion model validity for polycrystalline advanced ceramics

Thermal decohesion model validity for polycrystalline advanced ceramics

The mechanical properties of polycrystalline diamond as a function of strain rate and temperature

High Rate and High Temperature Fracture Behaviour of Polycrystalline Diamond

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