Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)Computational resources are commonly used in the research field, in order to facilitate data and services sharing. The frequent study of new research methodologies, the software diversity, simulators and data involved in experiments, lead to the necessity of environments that provide facilities for technology use and matching. Aiming to support the software diversity, the proposed solution is a scientific workflow environment that allows the researchers to create their own personalized workflows, using components provided by the development team as well as developed by themselves, regardless of the language being used. The basis for this environment is a component based software product line. The proposed extractive method for the product line development is supported by a software reengineering framework and uses existing modeling techniques. One case study was performed to evaluate some aspects, including the components reuse enhancement and the workflow customization capability. This study case had a positive result, showing that the proposed solution allows the researchers to customize their workflows. © 2013 IEEE. 7988CAPES,Conselho Nacional de Desenvolvimento Cientifico e Tecnologico (CNPq),Google,Governo Federal Brasil - Pais Rico Pais sem Pobreza,INES,Ministerio da Ciencia, Tecnologia e InovacaoConselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)Pallazi, D.C., (2010) Qdaontology - Abordagem para o Desenvolvimento de Ontologias Em E-science: Um Estudo de Caso Em Biologia, , Master's thesis, Universidade Federal de Juíz de Fora(2012) Portal UNISIM, , http://www.unisim.cepetro.unicamp.br/, Acesso em: 02 outDeelman, E., Gannon, D., Shields, M., Taylor, I., Workflows and e-science: An overview of workflow system features and capabilities (2009) Future Generation Computer Systems, 25 (5), pp. 528-540Ogasawara, E., Murta, L., Werner, C., Mattoso, M., Linhas de experimento: Reutilização e gerência de configuração em workflows científicos (2008) 2nd Wksp. on E-Science, pp. 31-40Kang, K.C., Kim, S., Lee, J., Kim, K., Shin, E., Huh, M., Form: A feature-oriented reuse method with domain-specific reference architectures (1998) Annals of Software Engineering, 5, pp. 143-168Cheesman, J., Daniels, J., (2001) UML Components, , Addison-WesleyKang, K., Kim, M., Lee, J., Kim, B., Feature-oriented re-engineering of legacy systems into product line assets - A case study (2005) Software Product Lines, pp. 45-56Ogasawara, E., Paulino, C., Murta, L., Werner, C., Mattoso, M., Experiment line: Software reuse in scientific workflows (2009) Scientific and Statistical Database Management, Ser. Lecture Notes in Computer Science, 5566, pp. 264-272. , M. Winslett, Ed. SpringerCosta, G.C.B., Braga, R., David, J.M.N., Campos, F., Arbex, W., PL-science: A scientific software product line (2013) Procedia Computer Science, 18, pp. 759-768(2012), http://www.mygrid.org.uk/, Acesso em: 27 julKang, K.C., Cohen, S., Hess, J., Novak, W., Peterson, S., Feature-oriented domain analysis (1990) CMU/SEI, Tech. Rep.Gomaa, H., (2004) Designing Software Product Lines with UML: From use Cases to Pattern-Based Software Architectures, , Addison WesleySochos, P., Riebisch, M., Philippow, I., The feature-architecture mapping (FArM) method for feature-oriented development of software product lines (2006) Proc. of the Annual IEEE Intl. Symposium and Wksp. on Engineering of Computer Based Systems, pp. 308-318. , IEEE Computer SocietyGayard, L.A., Rubira, C.M.F., Guerra, P.A.C., COSMOS*: A COmponent system MOdel for software architectures (2008) Instituto de Computação, UNICAMP, Tech. Rep. IC-08-04De Oliveira, D., Ogasawara, E., Seabra, F., Silva, V., Murta, L., Mattoso, M., GExpLine: A tool for supporting experiment composition (2010) Provenance and Annotation of Data and Processes, pp. 251-259. , SpringerAcher, M., Collet, P., Lahire, P., France, R., Managing variability in workflow with feature model composition operators (2010) Software Composition, pp. 17-33. , SpringerPetrel E&P Software Platform, , http://www.slb.com/services/software/geo/petrel.aspx/Foschiani, F.Y.S., (2012) Uma Abordagem de Linhas de Produtos de Software para Apoiar E-science, , Master's thesis, Instituto de Computação, UnicampKrueger, C.W., Easing the transition to software mass customization (2002) Intl. Wksp. on Software Product-Family Engineering, pp. 282-293. , SpringerKang, K., Kim, M., Lee, J., Kim, B., Feature-oriented re-engineering of legacy systems into product line assets - A case study (2005) Software Product Lines, pp. 45-56Berg, K., Bishop, J., Muthig, D., Tracing software product line variability: From problem to solution space (2005) Proc. of the Conf. of the SAICSIT. Republic of South Africa: Saicsit, pp. 182-191