Electromagnetic Characterization of Cemented Paste Backfill in the Field and Laboratory

Thottarath, Sujitlal

28 July 2010

Cemented Paste Backfill (CPB) is a relatively new backfilling technology for which a better understanding of binder hydration is required. This research uses electromagnetic (EM) wave-based techniques to non-destructively study a CPB consisting of tailings, sand, process water and binder (90% blast-furnace slag; 10% Portland cement). EM experiments were performed using a broadband network analyzer (20 MHz to 1.3 GHz) in the lab and capacitance probes (70 MHz) in the lab and field. Results showed that the EM properties are sensitive to curing time, operating frequency and specimen composition including binder content. The volumetric water content interpreted from dielectric permittivity varied little with curing. Temporal variations in electrical conductivity reflected the different stages of hydration. Laboratory results aided interpretation of field data and showed that a reduction in binder content from 4.5% to 2.2% delays setting of CPB from 0.5 days to over 2 days, which has important implications for mine design.

Cemented Paste Backfill

electromagnetic waves

dielectric permittivity

electrical conductivity

capacitance probes

ECH2O-TE

0551

0428

0543

Electromagnetic Characterization of Cemented Paste Backfill in the Field and Laboratory

Thottarath, Sujitlal

28 July 2010

Cemented Paste Backfill (CPB) is a relatively new backfilling technology for which a better understanding of binder hydration is required. This research uses electromagnetic (EM) wave-based techniques to non-destructively study a CPB consisting of tailings, sand, process water and binder (90% blast-furnace slag; 10% Portland cement). EM experiments were performed using a broadband network analyzer (20 MHz to 1.3 GHz) in the lab and capacitance probes (70 MHz) in the lab and field. Results showed that the EM properties are sensitive to curing time, operating frequency and specimen composition including binder content. The volumetric water content interpreted from dielectric permittivity varied little with curing. Temporal variations in electrical conductivity reflected the different stages of hydration. Laboratory results aided interpretation of field data and showed that a reduction in binder content from 4.5% to 2.2% delays setting of CPB from 0.5 days to over 2 days, which has important implications for mine design.

Cemented Paste Backfill

electromagnetic waves

dielectric permittivity

electrical conductivity

capacitance probes

ECH2O-TE

0551

0428

0543

SENSOR CALIBRATION SYSTEM AND METHODOLOGY FOR TIP CLEARANCE MEASUREMENTS IN TURBOMACHINES

Santiago D Salinas (10941474)

08 June 2021

<p>With increasingly tighter tip clearances in modern turbomachinery, it is essential to precisely measure this parameter during turbomachinery characterization. Benefits from measuring tip clearances include monitoring the structural integrity of the machine and estimating aerodynamic losses incurred due to leakage flows. At present, capacitance probes are one of the most commonly used sensors for tip clearance measurements in turbomachines as they are accurate and robust. One of the main challenges when using capacitance probes is properly calibrating the sensors, which usually involves complex positioning systems and blade representative targets. This manuscript describes in detail the development of a methodology for in-house calibration of capacitance probes for tip clearance measurements. A novel calibration procedure that does not involve rotating components is investigated and compared against established calibration methods. First, a calibration bench was developed to demonstrate the static and dynamic performance of the acquisition system and perform quasi-static as well as dynamic calibrations in a controlled environment. An in-situ methodology was then developed to calibrate the sensors once installed in a two-stage rotating turbine rig. The proposed methodology does not require complex positioning systems and a regression analysis using a least squares scheme resulted in a coefficient of determination of 0.9998. The calibration was validated using specially designed instrumentation at various speeds that span the operating envelope of the rig. A Bayesian model that was developed to estimate measurement uncertainties for each method showed that uncertainties as low as ± 5μm can be achieved with the proposed system. The proposed methodology was used in a two-stage turbine rig. Measurements taken at three different circumferential locations were subsequently used to map the spatial distribution of tip clearances throughout the speed operational envelope of the turbine. Finally, a reduced order rotor displacement model was developed and fitted to capacitance probes data. The work presented in this thesis lays the foundation for high fidelity tip clearance measurement capabilities at the Purdue Experimental Turbine Aerothermal Laboratory and can be implemented into any rotating rig. </p>

Tip clearance

Capacitance sensors

Capacitance probes

Mechanical Engineering

Aerospace Engineering