TY - BOOK
T1 - CTF User's Manual (V.4.2)
AU - Salko Jr, Robert K.
AU - Avramova, M.
AU - Wysocki, Aaron J.
AU - Hu, Jianwei
AU - Toptan, A.
AU - Porter, Nathan
AU - Blyth, Taylor S.
AU - Dances, Christopher A.
AU - Gomez, Ana
AU - Jernigan, Caleb
AU - Kelly, Joeseph
PY - 2020
Y1 - 2020
N2 - This document describes how a user should go about using the CTF pre-processor tool to create an input deck for modeling rod-bundle geometry in CTF. The tool was designed to generate input decks in a quick and less error-prone manner for CTF. The pre-processor is a completely independent utility, written in Fortran, that takes a reduced amount of input from the user. The information that the user must supply is basic information on bundle geometry, such as rod pitch, clad thickness, and axial location of spacer grids - the pre-processor takes this basic information and determines channel placement and connection information to be written to the input deck, which is the most time-consuming and error-prone segment of creating a deck. Creation of the model is also more intuitive, as the user can specify assembly and water-tube placement using visual maps instead of having to place them by determining channel/channel and rod/channel connections. As an example of the benefit of the pre-processor, a quarter-core model that contains 500,000 scalar-mesh cells was read into CTF from an input deck containing 200,000 lines of data. This 200,000 line input deck was produced automatically from a set of pre-processor decks that contained only 300 lines of data.
AB - This document describes how a user should go about using the CTF pre-processor tool to create an input deck for modeling rod-bundle geometry in CTF. The tool was designed to generate input decks in a quick and less error-prone manner for CTF. The pre-processor is a completely independent utility, written in Fortran, that takes a reduced amount of input from the user. The information that the user must supply is basic information on bundle geometry, such as rod pitch, clad thickness, and axial location of spacer grids - the pre-processor takes this basic information and determines channel placement and connection information to be written to the input deck, which is the most time-consuming and error-prone segment of creating a deck. Creation of the model is also more intuitive, as the user can specify assembly and water-tube placement using visual maps instead of having to place them by determining channel/channel and rod/channel connections. As an example of the benefit of the pre-processor, a quarter-core model that contains 500,000 scalar-mesh cells was read into CTF from an input deck containing 200,000 lines of data. This 200,000 line input deck was produced automatically from a set of pre-processor decks that contained only 300 lines of data.
KW - 21 SPECIFIC NUCLEAR REACTORS AND ASSOCIATED PLANTS
KW - 97 MATHEMATICS AND COMPUTING
U2 - 10.2172/1737480
DO - 10.2172/1737480
M3 - Commissioned report
BT - CTF User's Manual (V.4.2)
CY - United States
ER -