This paper presents the prototype of the computer code, Atlantide, developed to assess the consequences associated with accidental events that can occur in a LPG storage plant. The characteristic of Atlantide is to be simple enough but at the same time adequate to cope with consequence analysis as required by Italian legislation in fulfilling the Seveso Directive. The application of Atlantide is appropriate for LPG storage/transferring installations. The models and correlations implemented in the code are relevant to flashing liquid releases, heavy gas dispersion and other typical phenomena such as BLEVE/Fireball. The computer code allows, on the basis of the operating/design characteristics, the study of the relevant accidental events from the evaluation of the release rate (liquid, gaseous and two-phase) in the unit involved, to the analysis of the subsequent evaporation and dispersion, up to the assessment of the final phenomena of fire and explosion. This is done taking as reference simplified Event Trees which describe the evolution of accidental scenarios, taking into account the most likely meteorological conditions, the different release situations and other features typical of a LPG installation. The limited input data required and the automatic linking between the single models, that are activated in a defined sequence, depending on the accidental event selected, minimize both the time required for the risk analysis and the possibility of errors. Models and equations implemented in Atlantide have been selected from public literature or in-house developed software and tailored with the aim to be easy to use and fast to run but, nevertheless, able to provide realistic simulation of the accidental event as well as reliable results, in terms of physical effects and hazardous areas. The results have been compared with those of other internationally recognized codes and with the criteria adopted by Italian authorities to verify the Safety Reports for LPG installations. A brief of the theoretical basis of each model implemented in Atlantide and an example of application are included in the paper.
[1]
C. Pietersen,et al.
Consequences of accidental releases of hazardous material
,
1990
.
[2]
G. A. Chamberlain.
Developments in design methods for predicting thermal radiation from flares
,
1987
.
[3]
Richard W. Prugh,et al.
Quantitative evaluation of fireball hazards
,
1994
.
[4]
D. M. Deaves,et al.
Current status and advances in flash fire modeling
,
1995
.
[5]
A. C. van den Berg,et al.
The multi-energy method : A framework for vapour cloud explosion blast prediction
,
1985
.
[6]
A. D. Johnson,et al.
A model for predicting the thermal radiation hazards from large-scale horizontally released natural gas jet fires
,
1994
.
[7]
Rex Britter,et al.
Fluid modeling of dense gas dispersion over a ramp
,
1988
.
[8]
Rex Britter,et al.
Workbook on the dispersion of dense gases
,
1988
.
[9]
Hans K. Fauske,et al.
Source term considerations in connection with chemical accidents and vapour cloud modelling
,
1988
.
[10]
Raymond A. Freeman,et al.
CCPS guidelines for chemical process quantitative risk analysis
,
1990
.
[11]
Nick May.
Project Report: Sex Stereotyping and the Early Years of Schooling
,
1983
.