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[1] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Numerical modeling of the casting solidification process in a mold taking into account the influence of an air gap with variable width, Journal of Applied Mathematics and Computational Mechanics, 23(2), 2024, pages 117-128.
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[2] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Numerical modeling of the solidification process with consideration of shrinkage cavities formation and the influence of solid phase content on the feeding of the casting, Journal of Applied Mathematics and Computational Mechanics, 22(2), 2023, pages 75-86.
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[3] |
Ewa Węgrzyn-Skrzypczak, Numerical solution of the heat advection equation in a two-dimensional domain using the discontinuous Galerkin method, Journal of Applied Mathematics and Computational Mechanics, 22(3), 2023, pages 57-68.
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[4] |
Ewa Węgrzyn-Skrzypczak, Investigation of the influence of liquid phase motion on the solidification process in the three-dimensional region, Journal of Applied Mathematics and Computational Mechanics, 20(1), 2021, pages 103-111.
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[5] |
Ewa Węgrzyn-Skrzypczak, The comparison of results obtained from the continuous and discontinuous Galerkin Method for the thermoelasticity problem, Journal of Applied Mathematics and Computational Mechanics, 20(3), 2021, pages 77-88.
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[6] |
Ewa Węgrzyn-Skrzypczak, Analysis of the three-dimensional thermoelasticity problem with the use of the continuous Galerkin method, Journal of Applied Mathematics and Computational Mechanics, 19(3), 2020, pages 111-121.
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[7] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Analytical validation of the finite element method model for Laplace equation, Journal of Applied Mathematics and Computational Mechanics, 18(3), 2019, pages 97-106.
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[8] |
Ewa Węgrzyn-Skrzypczak, Discontinuous Galerkin method for the three-dimensional problem of thermoelasticity, Journal of Applied Mathematics and Computational Mechanics, 18(4), 2019, pages 115-126.
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[9] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Analytical and numerical solution of the heat conduction problem in the rod, Journal of Applied Mathematics and Computational Mechanics, 16(4), 2017, pages 79-86.
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[10] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Modeling of thermal contact through gap with the use of Finite Element Method, Journal of Applied Mathematics and Computational Mechanics, 14(4), 2015, pages 145-152.
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[11] |
Ewa Węgrzyn-Skrzypczak,Tomasz Skrzypczak, Mathematical and numerical basis of binary alloy solidification models with substitute thermal capacity. Part I, Journal of Applied Mathematics and Computational Mechanics, 13(2), 2014, pages 135-140.
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[12] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Mathematical and numerical basis of binary alloy solidification models with substitute thermal capacity. Part II, Journal of Applied Mathematics and Computational Mechanics, 13(2), 2014, pages 141-147.
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[13] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Investigation of accuracy of the interface tracking method, Journal of Applied Mathematics and Computational Mechanics, 12(2), 2013, pages 105-110.
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[14] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Numerical model with explicit time integration scheme for tracking interfaces, Journal of Applied Mathematics and Computational Mechanics, 12(2), 2013, pages 111-116.
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[15] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Mathematical model and numerical solution of double diffusive natural convection system, Scientific Research of the Institute of Mathematics and Computer Science, 10(2), 2011, pages 225-229.
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[16] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Mathematical description of discontinuous Galerkin method in the theory of thermoelasticity, Scientific Research of the Institute of Mathematics and Computer Science, 9(2), 2010, pages 235-242.
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[17] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Mathematical and numerical model of 3D natural convection in a cube, Scientific Research of the Institute of Mathematics and Computer Science, 8(1), 2009, pages 185-191.
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[18] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Accuracy of numerical solution of heat diffusion equation, Scientific Research of the Institute of Mathematics and Computer Science, 7(1), 2008, pages 193-198.
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[19] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Modelling of the binary alloys solidification process with constitutional undercooling condition, Scientific Research of the Institute of Mathematics and Computer Science, 6(1), 2007, pages 261-268.
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[20] |
Adam Kulawik, Ewa Węgrzyn-Skrzypczak, Numerical model of progressive hardening process with tempering for C45 steel, Scientific Research of the Institute of Mathematics and Computer Science, 5(1), 2006, pages 63-68.
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[21] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Numerical analysis of the solidification process with natural convection of the liquid phase, Scientific Research of the Institute of Mathematics and Computer Science, 5(1), 2006, pages 185-190.
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[22] |
Ewa Węgrzyn-Skrzypczak, Tomasz Skrzypczak, Modelowanie przepływów cieczy z wykorzystaniem metody elementów skończonych, Scientific Research of the Institute of Mathematics and Computer Science, 1(1), 2002, pages 227-233.
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