| 1. Identificação | ||||
| Tipo de Referência | Livro Editado (Edited Book) | |||
| Site | mtc-m21c.sid.inpe.br | |||
| Código do Detentor | isadg {BR SPINPE} ibi 8JMKD3MGPCW/3DT298S | |||
| Identificador | 8JMKD3MGP3W34R/448HPKB | |||
| Repositório | sid.inpe.br/mtc-m21c/2021/02.25.17.21 (acesso restrito) | |||
| Última Atualização | 2021:11.05.13.54.02 (UTC) simone | |||
| Repositório de Metadados | sid.inpe.br/mtc-m21c/2021/02.25.17.21.13 | |||
| Última Atualização dos Metadados | 2022:04.03.23.13.56 (UTC) administrator | |||
| Chave Secundária | INPE--/ | |||
| DOI | 10.1007/978-3-030-61761-5 | |||
| ISBN | 978-3-030-61760-8 978-3-030-61761-5 | |||
| Chave de Citação | DeiterdingDomiSchn:2021:CaCFMe | |||
| Título | Cartesian CFD Methods for Complex Applications  | |||
| Ano | 2021 | |||
| Data de Acesso | 20 maio 2024 | |||
| Tipo Secundário | LI | |||
| Número de Arquivos | 1 | |||
| Tamanho | 8291 KiB | |||
| 2. Contextualização | ||||
| Editor | 1 Deiterding, Ralf 2 Domingues, Margarete Oliveira 3 Schneider, Kai | |||
| Grupo | 1 2 COPDT-CGIP-INPE-MCTI-GOV-BR | |||
| Afiliação | 1 University of Southampton 2 Instituto Nacional de Pesquisas Espaciais (INPE) 3 Aix-Marseille Université | |||
| Endereço de e-Mail do Autor | 1 2 margarete.domingues@inpe.br | |||
| Título da Série | Sema Sima | |||
| Editora (Publisher) | Springer | |||
| Volume | 3 | |||
| Histórico (UTC) | 2021-02-25 17:21:45 :: simone -> administrator :: 2021 2021-07-02 02:27:10 :: administrator -> simone :: 2021 2021-07-06 11:22:35 :: simone -> administrator :: 2021 2021-08-09 04:54:11 :: administrator -> simone :: 2021 2021-11-05 13:54:24 :: simone -> administrator :: 2021 2022-04-03 23:13:56 :: administrator -> simone :: 2021 | |||
| 3. Conteúdo e estrutura | ||||
| É a matriz ou uma cópia? | é a matriz | |||
| Estágio do Conteúdo | concluido | |||
| Transferível | 1 | |||
| Tipo do Conteúdo | External Contribution | |||
| Palavras-Chave | cartesian CFD methods | |||
| Resumo | Cartesian discretization approaches are ubiquitous in computational fluid dynamics. When applied to problems in geometrically complex domains or fluidstructure coupling problems, Cartesian schemes allow for automatic and scalable meshing; however, order-consistent immersed boundary conditions and efficient dynamic mesh adaptation take forefront roles. This volume contains selected contributions from the four-session thematic mini-symposium on Cartesian CFD Methods for Complex Applications at ICIAM 2019 held in Valencia in July. The papers highlight cutting-edge applications of Cartesian CFD methods and describe the employed algorithms and numerical schemes. An emphasis is laid on complex multi-physics applications such as magnetohydrodynamics or aerodynamics with fluidstructure interaction, solved with various discretizations, e.g. finite difference, finite volume, multi-resolution or lattice Boltzmann CFD schemes. Software design and parallelization challenges are also addressed briefly. The volume is organized into two parts of three contributions each. Part one is focused on incompressible flows and has the following contributions: Bergmann et al. propose an adaptive finite-volume method with quad-tree discretization of the incompressible NavierStokes equations. Moving immersed bodies are modelled with volume penalization, and their interface is tracked using level sets. Test cases with flows around cylinders show the validity and precision of the approach. Fluid structure interaction for flexible insect wings is studied in the paper by Truong et al. A mass spring model is used for the wing structure. The fluid solver is based on a Fourier pseudospectral discretization with volume penalization to take into account the complex and time-varying geometry. Applications consider flapping bumblebee flight in laminar and turbulent flow. The paper by Kadri and Perrier presents a numerical scheme for incompressible NavierStokes equations in three dimensions using divergence-free wavelets. Constructions for these basis functions are given for no-slip and free-slip boundary conditions and divergence-free wavelets in dimension higher than three are given. Numerical examples illustrate the scheme for lid-driven cavity problems. The second part deals with compressible and weakly compressible flows and has likewise three contributions. Perron et al. propose an immersed boundary method for compressible flows using structured Cartesian grids. A direct forcing approach based on the use of ghost cells is chosen. Two flow configurations are considered, a supersonic flow around a blunt body to demonstrate the capability of mesh adaptation to increase the accuracy and a large eddy simulation of the flow around a three-dimensional high-lift airfoil. Comparisons with experimental data and a reference body-fitted computation are as well presented. Moreira Lopes et al. discuss the performance and detail verification and validation of a wavelet-adaptive magnetohydrodynamic solver, realized within the MPI-parallel AMROC (Adaptive Mesh Refinement in Object-oriented C++) framework. A prototype simulation fuses this solver with actual satellite date for space weather forecasting. Finally, Gkoudesnes and Deiterding report on the incorporation of the lattice Boltzmann method into the AMROC environment. The algorithmic details and verification of large eddy simulation with the wall-adapting local eddy-viscosity model for dynamically adapting meshes and with ghost cell-based embedded boundary conditions are presented. We thank all the speakers of the four sessions for making this mini-symposium a successful event, and we are grateful to the authors for their contributions. We are indebted to the numerous referees for their constructive and detailed reports. For all papers, we had three to four reviews, improving thus further the quality of this edited volume. | |||
| Área | COMP | |||
| Arranjo 1 | urlib.net > BDMCI > Fonds > Produção a partir de 2021 > CGIP > Cartesian CFD Methods... | |||
| Arranjo 2 | Projeto Memória 60... > Livros e livros editados > Cartesian CFD Methods... | |||
| Conteúdo da Pasta doc | acessar | |||
| Conteúdo da Pasta source | não têm arquivos | |||
| Conteúdo da Pasta agreement |
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| 4. Condições de acesso e uso | ||||
| Idioma | en | |||
| Arquivo Alvo | cartesian-cfd-methods-for-complex-applications-2021.pdf | |||
| Grupo de Usuários | simone | |||
| Grupo de Leitores | administrator simone | |||
| Visibilidade | shown | |||
| Permissão de Leitura | deny from all and allow from deny and allow from for and allow from all | |||
| 5. Fontes relacionadas | ||||
| Unidades Imediatamente Superiores | 8JMKD3MGPCW/46KUES5 8JMKD3MGPGW/45823FH | |||
| Lista de Itens Citando | sid.inpe.br/bibdigital/2022/04.03.23.11 4 | |||
| Divulgação | BNDEPOSITOLEGAL | |||
| Acervo Hospedeiro | urlib.net/www/2017/11.22.19.04 | |||
| 6. Notas | ||||
| Campos Vazios | archivingpolicy archivist booktitle callnumber city copyholder copyright creatorhistory descriptionlevel documentstage e-mailaddress edition format issn label lineage mark mirrorrepository nextedition notes numberofpages numberofvolumes orcid organization parameterlist parentrepositories previousedition previouslowerunit progress project resumeid rightsholder schedulinginformation secondarydate secondarymark serieseditor session shorttitle sponsor subject tertiarymark tertiarytype url versiontype | |||
| 7. Controle da descrição | ||||
| e-Mail (login) | simone | |||
| atualizar | ||||