Your search keyword '"Hopper RD"' showing total 2 results

1. IAEA/EPA International Climatic Test Program for Integrating Radon Detectors

Author

Steinhäusler F, Ronca-Battista M, and Hopper Rd

Subjects

Dosimeter, Meteorology, Epidemiology, Health, Toxicology and Mutagenesis, Instrumentation, Detector, chemistry.chemical_element, Radon, Particle detector, chemistry, Environmental science, Radiation monitoring, Dosimetry, Radiology, Nuclear Medicine and imaging, Relative humidity

Abstract

As an element of the joint IAEA-EPA International Radon Metrology Evaluation Program, a climatic test of long-term integrating radon detectors was conducted at the US EPA Radiation and Indoor Environments National Laboratory. The objective of this study was to test the performance of commonly used commercially available long-term {sup 222}Rn detector systems under extreme climatological conditions using filtered polycarbonate CR-39 plastic analyzed by the manufacturer using the track-etch method, unfiltered LR-115 film analyzed by the manufacturer, and Teflon{trademark} based electrets analyzed in the field by EPA using the manufacturer's equipment. The EPA environmental radon chambers were used to expose detectors to extreme cold and dry (less than 4.0 C air temperature and 25% relative humidity) and hot and humid (greater than 35 C air temperature and 85% relative humidity) climatic conditions. During phase 1 detectors were exposed to low temperatures and low humidities, and during phase 2 detectors were exposed to high temperatures and high humidities. Typical indoor equilibrium fractions (near 50%) and radon concentrations of about 150 Bq m{sup {minus}3} were maintained for each phase, which lasted 90 d. The results indicated that the optimal detector for extreme climatic conditions is dependent on the relative importance of bias andmore » precision. Overall, however, the filtered track-etch type detector produced the most reliable results under the extreme conditions.« less

Published

1999

2. Intercomparison of Radon and Decay Product Measurements in an Underground Mine and EPA Radon Laboratory

Author

Budd G, Braganza E, Hopper Rd, Ronca-Battista M, Steinhäusler F, and Stegner P

Subjects

Waste management, Epidemiology, Health, Toxicology and Mutagenesis, chemistry.chemical_element, Radon, Metrology, Uranium mine, chemistry, Environmental protection, Radiation monitoring, Environmental science, Dosimetry, media_common.cataloged_instance, Radiology, Nuclear Medicine and imaging, Decay product, European union, National laboratory, media_common

Abstract

The International Atomic Energy Agency (IAEA) in Vienna and the European Union (EU) in Bruxelles formed the "International Radon Metrology Programme" (IRMP, scientific secretary: F. Steinhausler, University of Salzburg, Austria). The IRMP is designed to assess and foster the improvement of radon and decay product measurements that are made around the world. Within the framework of the IRMP, the U.S. Environmental Protection Agency Radiation and Indoor Environments National Laboratory (EPA) in Las Vegas, Nevada, organized jointly with the U.S. Bureau of Mines an international intercomparison exercise at a former uranium mine (Twilight Mine, Colorado) and the EPA Radon Laboratory. The main objective of this exercise was to compare radon and radon decay product instruments under both well-controlled as well as widely fluctuating exposure conditions. The laboratory exposures occurred under relatively steady radon and decay product conditions, with a moderate equilibrium ratio, while the conditions in the mine fluctuated greatly and the equilibrium ratio was low. An additional purpose of the exercise was to provide a forum for manufacturers and measurement organizations worldwide to exchange information and plan improvements in their operations and calibration programs. Altogether 19 organizations from seven countries intercomparing 32 different radon and radon decay product instruments participated in this exercise. This paper summarizes the results from the analysis of the experimental data obtained in the Bureau of Mines Twilight Mine in July of 1994, as well as the results from the EPA Radon laboratory in August of 1994.

Published

1998