Katie Hawley scite author profile

Katie Hawley

3Publications

3Citation Statements Received

11Citation Statements Given

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Champlain College

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Paste backfill continuous pour: Red Lake operations case study

Oke¹,

Hawley²,

Belem³

et al. 2021

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Cemented paste backfill (CPB) has become known as a superior secondary ground support technique and mine tailings storage method for stoping. Extensive scientific research has been conducted by the authors on CPB to provide the Red Lake operation (RLO) of Evolution Mining with an optimised backfill placement process. CPB mechanical/viscous behaviour is governed by its plasticity, the tailings particle size distribution, particle shape, mineralogical composition, water content, and the type and dosage of binder used (e.g. cement and/or supplementary cementitious material). For the CPB design, it is necessary to have a thorough understanding of the combined effects of filling rate, self-weight consolidation (volume shrinkage/settlement), and binder hydration rate for each specific paste mixture. Due to these complex factors and interactions, a rational CPB material design process was assessed to demonstrate the safety aspects related to a continuous pour. For this purpose, an extensive field monitoring program was required to quantify the CPB performance and characteristics.There are two different ways of optimising the CPB design to maximise placement rate: (i) optimising the type and amount of binder added to the system, and (ii) optimising the CPB placement process underground. Optimisation of binder type and dosage is relatively easy as the required backfill stand-up strength is based on block dimensions, stope stability, and extraction sequencing. Optimisation of backfill placement is more difficult, as the understanding of the viscous/pseudo-plastic behaviour of the CPB is required throughout the pour. Typically, a three-stage (plug-cure-main) pouring strategy is implemented to mitigate the lack of understanding of the CPB behaviour during placement. The CPB plug (i.e. height of initial pour regime) is designed to mitigate the pressure on the backfill fence. Once this CPB plug has cured and reached the required shear strength, the backfill fence is no longer required, and the remainder of the stope void (main) can be filled. However, if the curing time of the in situ paste is accelerated due to the binder exothermic hydration process (volume shrinkage) and backfill self-weight consolidation (water drainage), it is possible to have a more aggressive pour regime provided that all the required design parameters, site procedures, company protocols, and critical controls are met.RLO implemented instrumentation, and an early-age CPB strength testing program to evaluate whether their CPB can be poured continuously or at least more aggressively. Four stopes were instrumented with total earth pressure cells (TEPCs) and piezometers to capture the pressures acting on the fill fence structures and the strengthening response of the CPB plug within the stopes. This paper summarises the results of each of the tests performed. Based on the results obtained from this study, it was concluded that RLO can safely conduct continuous CPB pours with appropriate safeguards and protocols in place. It is important to note that this pa...

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What If and Why Not: Reinvention Culture at Champlain College

Quinn

Hawley

Laackman

2019

New Drctns Hghr Edu

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Paste backfill thermal contraction: Red Lake operations case study

Oke¹,

Hawley²,

Belem³

et al. 2021

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One of the earliest attempts at field measurement within hydraulically placed cemented backfill occurred over 20 years ago. Recently, Thompson et al. (2014a) published their findings on capturing thermal expansion within cemented paste backfill (CPB) and cemented hydraulic backfill (CHB). They discovered that the total earth pressure within the CPB following placement is likely to increase at a rate of 30 kPa/°C (i.e. for an 11°C temperature increase). However, Thompson and his co-authors' research did not elaborate on the subsequent effects of thermal dissipation (or thermal contraction) in backfill. A comprehensive literature study concluded with no clear evidence of thermal dissipation phenomenon and its effects in backfill. It is hypothesised by the authors that if thermal expansion can occur, then thermal dissipation or contraction is also likely to occur.Red Lake operation (RLO) of Evolution Mining conducted a field program to capture the characteristics of the CPB during a transition from a plug-cure-main pour strategy to a more aggressive pour strategy (i.e. continuous pour operation). During this investigation, strong evidence of thermal contraction was observed in three of the four instrumented stopes. This paper presents detailed findings of two of the instrumented stopes.

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Katie Hawley

Paste backfill continuous pour: Red Lake operations case study

What If and Why Not: Reinvention Culture at Champlain College

Paste backfill thermal contraction: Red Lake operations case study

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