Modeling radon entry into houses with basements: Model description and verification
We model radon entry into basements using a previously developed three-dimensional steady-state finite difference model that has been modified in the following ways: first, cylindrical coordinates are used to take advantage of the symmetry of the problem in the horizontal plant; second, the configuration of the basement has been made more realistic by incorporating the concrete footer; third, a quadratic relationship between the pressure and flow in the L-shaped gap between slab, footer, and wall has been employed; fourth, the natural convection of the soil gas which follows from the heating of the basement in winter has been taken into account. The temperature field in the soil is determined from the equation of energy conservation, using the basement, surface, and deep-soil temperatures as boundary conditions. The pressure field is determined from Darcy's law and the equation of mass conservation (continuity), assuming that there is no flow across any boundary except the soil surface (atmospheric pressure) and the opening in the basement shell (fixed pressure). After the pressure and temperatures field have been obtained the velocity field is found from Darcy's law. Finally, the radon concentration field is found from the equation of mass-transport. The convective radon entry rate through the opening or openings is then calculated. In this paper we describe the modified model, compare the predicted radon entry rates with and without the consideration of thermal convection, and compare the predicted rates with determined from data from 7 houses in the Spokane River valley of Washington and Idaho. Although the predicted rate is much lower than the mean of the rates determined from measurements, errors in the measurement of soil permeability and variations in the permeability of the area immediately under the basement slab, which has a significant influence on the pressure field, can account for the range of entry rates inferred from the data. 25 refs., 8 figs.
- Research Organization:
- Lawrence Berkeley Lab., CA (USA)
- Sponsoring Organization:
- USDOE; USDOE, Washington, DC (USA)
- DOE Contract Number:
- AC03-76SF00098
- OSTI ID:
- 6103637
- Report Number(s):
- LBL-27742; CONF-900724-10; ON: DE91009330; TRN: 91-009222
- Resource Relation:
- Conference: Indoor Air '90: 5th international conference on indoor air quality and climate, Toronto (Canada), 29 Jul - 3 Aug 1990
- Country of Publication:
- United States
- Language:
- English
Similar Records
The Influence of a Subslab Gravel Layer and Open Area on Soil-Gas and Radon Entry into Two Experimental Basements
The influence of a subslab gravel layer and open area on soil-gas and radon entry into two experimental basements
Related Subjects
CONCRETES
RADIONUCLIDE MIGRATION
MATHEMATICAL MODELS
RADON 222
DIFFUSION
ENVIRONMENTAL TRANSPORT
SOILS
BASEMENTS
DARCY LAW
DATA COVARIANCES
FINITE DIFFERENCE METHOD
HEALTH HAZARDS
HEAT TRANSFER
INDOOR AIR POLLUTION
PERMEABILITY
PRESSURE GRADIENTS
RADIOECOLOGICAL CONCENTRATION
RESIDENTIAL BUILDINGS
STEADY-STATE CONDITIONS
TEMPERATURE GRADIENTS
THEORETICAL DATA
THREE-DIMENSIONAL CALCULATIONS
VALIDATION
AIR POLLUTION
ALPHA DECAY RADIOISOTOPES
BUILDING MATERIALS
BUILDINGS
DATA
DAYS LIVING RADIOISOTOPES
ECOLOGICAL CONCENTRATION
ENERGY TRANSFER
EVEN-EVEN NUCLEI
HAZARDS
HEAVY NUCLEI
INFORMATION
ISOTOPES
ITERATIVE METHODS
MASS TRANSFER
MATERIALS
NUCLEI
NUMERICAL DATA
NUMERICAL SOLUTION
POLLUTION
RADIOISOTOPES
RADON ISOTOPES
TESTING
540130* - Environment
Atmospheric- Radioactive Materials Monitoring & Transport- (1990-)