Stress thermal CFD engineer

Имя

Валерий

Контакты

Доступны бесплатно после регистрации или входа

Общая информация

Проживание

Москва, м. Щелковская

Заработная плата

По договоренности

График работы

Полный рабочий день / Сменный график / Гибкий график / Удаленная работа

Образование

Высшее

Опыт работы

34 года 7 месяцев

Гражданство

Россия

Пол

Мужской

Возраст

62 года   (1 мая 1962)

Опыт работы

Период работы

октябрь 2008 — по настоящее время   (16 лет 5 месяцев)

Должность

Stress engineer

Компания

CAE-Services.net

Обязанности

Numerical simulation topics:

Strength and thermal strength simulations,

including hyperelastic materials (rubbers, polymers, foams, etc.), composites.

have experience in numerical modeling of stamping processes

The tasks of "theoretical mechanics", incl. rotor dynamics problems.

Thermal physics:

- Thermal physics of "solid state",

- heat transfer by radiation,

- conjugate heat exchange (convection).

Electromagnetic fields (classical electrodynamics);

calculations of operating parameters of cables, transformers, coils - capacitance, inductance, heat release for low frequency currents.

Piezoelectric tasks;

Problems about thermoelectric effects;

Solving problems of geometric (beam) optics, taking into account temperature fields.

Период работы

апрель 1995 — октябрь 2008   (13 лет 7 месяцев)

Должность

Stress engineer

Компания

CAD-FEM GmbH

Обязанности

Numerical simulation topics:

Strength and thermal strength simulations,

including hyperelastic materials (rubbers, polymers, foams, etc.), composites.

have experience in numerical modeling of stamping processes

The tasks of "theoretical mechanics", incl. rotor dynamics problems.

Thermal physics:

- Thermal physics of "solid state",

- heat transfer by radiation,

- conjugate heat exchange (convection).

Период работы

сентябрь 1986 — апрель 1995   (8 лет 8 месяцев)

Должность

Stress engineer

Компания

Research Institute

Обязанности

• Coupled stress / thermal simulations - propagation of explosion shock waves in elastoplastic media (soild) and interaction of shock waves with above-ground and underground structures, pipelines, tanks.

• Determination of parameters of motion underground constructions exposed to explosion shock waves.

• Stress simulations of steel and/or concrete building constructions.

• Stress simulations of shock absorbing systems for building constructions containing equipment and personnel.

Образование

Образование

Высшее

Окончание

1995 год

Учебное заведение

Sank-Peterburg State University

Специальность

Applied mathematics, PhD

Дополнительная информация

Иностранные языки

Английский (Разговорный)

Водительские права

Категории B, C

Командировки

Не готов к командировкам

Курсы и тренинги

Software:

• ABAQUS/Standard, ABAQUS/Explicit, ABAQUS/Implicit, ABAQUS/CAE (2007-present)

• ANSYS (Structural, Thermal, Workbench, Fatigue, DesignExplorer) (1986-2007)

• ANSA (2015-present)

• HyperMesh (2016-present)

• COMSOL (2000-2002)

• MCalibration (2016-present)

• AutoCAD (1997-present)

• SolidWorks (2001-present)

Навыки и умения

Stress and thermal simulations.

Equations states (material models) that I used performing stress / thermal simulations:

• Linear elasticity

• Porous elasticity

• Linear Viscoelasticity

• Hypoelasticity

• Hyperelasticity (including Mullins effect, Hysteresis,

• Hyperfoam (Hyperelasticity in elastometric foams)

• Linear viscoelasticity

• Nonlinear Viscoelasticity

• Permanent set in rubberlike materials

• Metal plasticity

• Classical metal plasticity

• Models for metals subjected to cyclic loading

• Annealing or melting

• Johnson-Cook plasticity

• Dynamic failure models

• Porous metal plasticity

• Cast iron plasticity

• Deformation plasticity

• Damage and failure for ductile metals

• Damage (initiation and for evolution) and failure ductile materials in low-cycle fatigue analysis

• Extended Drucker-Prager models

• Modified Drucker-Prager/Cap model

• Mohr-Coulomb plasticity

• Critical state (clay) plasticity model

• Crushable foam plasticity models

• Concrete

• Concrete smeared cracking

• Cracking model for concrete

• Concrete damaged plasticity

• Damage and failure for fiber-reinforced composites