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На данном уроке мы рассмотрим расчет трубопровода в Ansys Mechanical, задав давление 1,2МПа внутри трубы, предварительно создав 3D модель в компас 3D. 00:00 Заставка канала 00:05 Создание 3D модели в компас 3D 01:34 Импорт 3D модели из компас 3D в Ansys Mechanical 06:19 Создание сетки 06:38 Создание условий расчета 09:39 Результат расчета Ссылка на Яндекс Дзен: 🤍 Уроки по Ansys: Урок № 2 - Расчет нагрузок на опору в Ansys Mechanical 🤍 Урок № 3 - Расчет истечения рабочей среды мимо шара в Ansys Fluent 🤍 Урок №4 - Расчет теплового распределение в Steady-state Thermal 🤍 Урок №5 - Расчет нагрузок на полиэтиленовую трубу и выбор материала в Ansys 🤍 Урок №6 - Создание расчета перетока жидкости мимо объекта в CFD CFX 🤍 Урок № 7- Расчет нагрузок на педальный узел в Ansys Mechanical 🤍 Урок №8 - Расчет столкновения одного объекта с другим при помощи Explicit Dynamics 🤍 Урок №9- Построение модели болтового соединения и расчет в Ansys 🤍 Урок №10- Cоздание одноступенчатого горения в Ansys 🤍 Урок №11- Cоздание вращения объекта в Transient Structial 🤍 Урок №12- Cоздание перетекания рабочий среды через тройник в Ansys Discovery 🤍
Видео урок по ANSYS Mechanical APDL Музыка Fantasy by Alex Stoner Music: 🤍taketones.com
Ansys – это универсальная программная система анализа, которая существует и развивается уже на протяжении последних 30 лет. Ansys является довольно популярной у специалистов в сфере автоматизированных предназначенных для решения различных инженерных задач расчетов анализа и симуляции физических процессов, решения линейных и нелинейных стационарных и нестационарных пространственных задач, механики деформируемого твердого тела и механики конструкции, включая нестационарные геометрические и физические нелинейные задачи контактного взаимодействия элементов конструкции, задачи механики жидкости и газа, теплопередачи и теплообмена, электродинамики акустики, а также механики связанных полей. Ansys позволяет создавать симуляции физических процессов задавая любые граничные условия и воздействия на них в тех или иных условиях, создавая или изменяя уже существующую геометрию. При этом затраты времени и финансовых средств на исследования объекта или процесса практически полностью заменяются путем использования данной программы. Ansys охватывает почти все существующие разделы физики и инженерии, достаточными для того, чтобы провести все эксперименты в условиях компьютерного моделирования. Источник: 🤍 🤍 – учебный портал Студии Vertex. На нем собрано большое количество уроков и статей по изучению программ Autodesk Inventor, SOLIDWORKS, КОМПАС-3D. 🤍 – интернет магазин курсов Студии Vertex по различным программам.
Пример расчета балки квадратного сечения под действием распределенной нагрузки
В этом видеоуроке вы познакомитесь с основами расчета прогиба вала в центробежного насоса в программном комплексе ANSYS Workbench
This is ANSYS 2020 tutorial for beginners. Video explains and demonstrates how to perform static structural analysis in the ANSYS workbench for the 2020 R2 release. This video will help you to understand the overall workflow required in ANSYS to run your first example. Please leave a comment if you have any questions. #ANSYSworkbench #ANSYS #notrealengineering Email id: notrealengineering🤍gmail.com "Music: 🤍bensound.com"
In this Ansys fluent tutorial for beginners we will learn how to do fluid flow and heat transfer analysis in rectangular duct using ansys fluent ansys fluent tutorial. if you want to join our solidworks course click on this link : 🤍 For More Ansys fluent tutorials click on this link : 🤍 Part file link : 🤍 Thank you for watching don't forget to subscribe ansys fluent tutorial for beginners ansys fluent flow through duct ansys fluent #ansys #ansysfluent #ansysflowthroughduct
The Finite Element Modeling of the Resistance Spot Welding Process Resistance spot welding is a complicated process, which involves the interaction of electrical, thermal, mechanical, and metallurgical phenomena. An axisymmetric finite element model to simulate this coupled process was developed, using isoparametric solid elements to represent the electrode and workpiece, and boundary elements to represent surface contact conditions. The model was used for analyzing the squeeze and weld cycles to determine the electrical, thermal, and mechanical responses. Predictions of the temperature distribution, thermal expansion and associated stresses, and weld nugget geometry were obtained from this model. Weld Strength ANSYS Welding induced stresses in a static structure Ansys Welding
The first in a series of video tutorials on using ANSYS to perform finite element analysis. In this introduction, we will model a fixed-fixed beam with a midspan load using Static Structural analysis. Learning objectives: 1. Define simple geometry using SpaceClaim. 2. Create a mesh with a specified element size. 3. Apply boundary conditions and loads. 4. Examine deformation and stress results.
В этом видео показаны основные этапы работы в ANSYS Workbench и ANSYS CFX для решения задач гидрогазодинамики, в частности течения жидкости и газа. Рассмотрен интерфейс ANSYS Workbench, ANSYS CFX, Design Modeler, ANSYS Mesh, CFX-Pre, CFX-Solver и CFD-Post. #ANSYSCFX #ANSYSWorkbench #CFXPre
автор видео: Томаев Иван Строительная механика Исследование расчетного пакета МКЭ ansys mechanical тип конечного элемента: Балка Разбиение на 100 элементов.
На данном уроке мы рассмотрим создание нового материала в библиотеке Ansys. Также данный материал используем для расчета в Ansys mechanical. 00:00 Интро 00:05 Местонахождение материалов библиотеки Ansys 00:51 Свойства материала 01:55 Создание нового материала 04:05 Создание расчета в Ansys mechanical 04:33 Выбор нового материала 05:35 Результат расчета Урок №1 - Первичный расчет нагрузки на трубу в Ansys Mechanical 🤍 Урок № 2 - Расчет нагрузок на опору в Ansys Mechanical 🤍 Урок № 3 - Расчет истечения рабочей среды мимо шара в Ansys Fluent 🤍 Урок №4 - Расчет теплового распределение в Steady-state Thermal 🤍 Урок №5 - Расчет нагрузок на полиэтиленовую трубу и выбор материала в Ansys 🤍 Урок №6 - Создание расчета перетока жидкости мимо объекта в CFD CFX 🤍 Урок № 7- Расчет нагрузок на педальный узел в Ansys Mechanical 🤍 Урок №8 - Расчет столкновения одного объекта с другим при помощи Explicit Dynamics 🤍 Урок №9- Построение модели болтового соединения и расчет в Ansys 🤍 Урок №10- Cоздание одноступенчатого горения в Ansys 🤍 Урок №11- Cоздание вращения объекта в Transient Structial 🤍 Урок №12- Cоздание перетекания рабочий среды через тройник в Ansys Discovery 🤍
This video explores two different options for defining interaction between neighboring parts in an assembly. Shared topology or contact definition settings solve the problem of connecting parts efficiently in Finite Element Analysis. Simulation results can be misleading or wrong when neither of these options is used manually because the interaction of parts is not assumed by the program. // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses that include videos, handouts, simulation examples with starting files, homework problems and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask your own question. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍 0:00 - Introduction 1:40 - Connecting parts using Shared Topology in Ansys SpaceClaim 3:16 - Connecting parts using Contact Connections in Ansys Mechanical 4:40 - Choosing the right method for connecting parts 7:50 - Using the “Share” tool for Shared Topology in Ansys SpaceClaim 9:10 - Visualizing Shared Topology with “Show Connected Bodies” in Ansys SpaceClaim 13:33 - Demonstration of use of Contact Connections 17:13 - Modifying the Legend of Contour Displays using Top and Bottom Independent Bands
В видео-уроке представлена методика моделирования железобетонных конструкций в оболочке Ansys Workbench Mechanical с использованием моделей Вилама-Варнке (solid65) и Базанта (Microplane). Подробно рассматриваются аспекты моделирования, вызывающие у пользователей наибольшие трудности. Подробно описана методика расчета с использованием элемента solid65, даны рекомендации по настройке решателя и получению решения при плохой сходимости. Описана методика расчета входных параметров модели Microplane. Для отображения разрушенных областей использован объект пользовательского результата с заданным критерием разрушения. Моделирование и Цифровые Двойники: 🤍 SDT eLearning: 🤍 Инженерно-технический журнал CADFEM Review: 🤍 Присоединяйтесь к нам в соцсетях: 🤍 🤍 © АО «Моделирование и цифровые двойники»
Dynamic strength analysis of a piston in Ansys Transient Structural. 1) Построение индикаторной диаграммы 2) Моделирование поршня в Ansys SpaceClaim 3) Граничные условия в Transient Structural Ansys 2022 Ссылка на индикаторную диаграмму 🤍
softwareANSYS is a set of analytical tools that use the finite element method for modeling and analysis. The finite element method has been devised to solve complex problems with geometry, type of materials, and arbitrary loading. In this way, the complex models are first divided into smaller soluble components and then by combining the results obtained from the solution of each component together the whole model response is obtained at each point. The superiority of analyzing various issues on one hand and the upgrading of computer equipment on the other hand has led to the application of finite element method and consequently software based on it. The tools provided in ANSYS enable the analysis of various types of structures such as frames, tanks, dams, bridges ... and structural components such as steel joints, steel or concrete members, insulators, ... in various ways. These include static analysis, reciprocal loading, modal, time history, spectral, and so on. To simulate different reliance conditions sometimes several options are available as acceleration, displacement, force or anchor with different patterns that are constant or variable over time. Different behavioral models of brittle and aggregate materials such as dual- and multi-linear models of steel, the Drager-Prager model and the concrete fracture model have been predicted to be used in the field of nonlinear behavior.
«Решение задачи механики хрупкого разрушения в Ansys Mechanical APDL 13.0» Моделирование и Цифровые Двойники: 🤍 SDT eLearning: 🤍 Инженерно-технический журнал CADFEM Review: 🤍 Присоединяйтесь к нам в соцсетях: 🤍 🤍 © АО «Моделирование и цифровые двойники»
ANSYS workbench is the numerical type of engineering problem solving software. used to simulate interactions of all disciplines of physics, structural, vibration, fluid dynamics, heat transfer and electromagnetic for engineers. This course covers the Mechanical analysis using ANSYS workbench. Course is about to correlate the Lerner with actual engineering problems. Able to make understand the problem definition and solve it. Course is basically covers the interface to ANSYS workbench for mechanical preference. Course Link : 🤍 For Learn full courses : 🤍 Any Help or instruction mail to : hello🤍sseacademy.com
This video lesson introduces preloaded bolt joints and the three types of connections available in Ansys Mechanical to represent them: contact, joint and beam connections. Each option offers a different balance of accuracy versus efficiency in calculating the forces and moments involved. The objective of this video is to help identify the required connection types for our model. // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses, including videos, handouts, simulation examples with starting files, homework problems, and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask questions. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍
While we may analyze single parts in most practical engineering applications, typically, we have an assembly of parts of different sizes made from different materials, all interacting with each other. Contact conditions allow us to define whether parts are bonded together, if they can slide relative to each other, or if they can separate from each other. In short, without contact, we can’t model realistic interactions between parts, so understanding the basics of contact is important in our journey to model physical systems more accurately. In this video, we focus our attention on setting up models with contact for linear or small deflection analysis, providing the foundation for our understanding of realistically representing part interactions. In Workbench, the contacts are automatically created and it’s always a good practice to check automatically created connections. We will do this via a short lecture and a walkthrough example using Ansys Mechanical. Also, we will show some tips and tricks to keep in mind when using contact conditions. // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses, including videos, handouts, simulation examples with starting files, homework problems, and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask questions. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍 0:00 - Introduction 4:10 - Augmented Lagrange Contact Formulation 4:57 - MPC Contact Formulation 7:46 - Contact Sizing 8:08 - Contact Tool 10:37 - Automatic Contact Detection 11:21 - Contact Body View & Syncing Views 12:36 - Exploded View 13:15 - Symmetry Conditions 15:00 - Thermal Condition and Environment Temperature 15:44 - Saving Nodal Forces under Output Controls 16:30 - Contact Force Reaction
This video introduces basic steps required to find out the maximum temperature achieved by component due to thermal load. From the beginning to 7.10, you will understand the process of carrying out steady-state thermal analysis on a component. From 7.10 to the end, you will learn the process of transferring thermal load on the mechanical side using Workbench coupling to find out stress and deformation. Learn more at 🤍ansys.com/studentcommunity
Моделирование и Цифровые Двойники: 🤍 SDT eLearning: 🤍 Инженерно-технический журнал CADFEM Review: 🤍 Присоединяйтесь к нам в соцсетях: 🤍 🤍 © АО «Моделирование и цифровые двойники»
Modal analysis provides valuable insight into the dynamic characteristics of a structure. It provides engineers with information regarding how the design will respond to different types of dynamic loading and can be used, for example, to avoid resonant vibrations that can be harmful to the structure. The modal analysis calculates the natural frequencies and mode shapes of the structure. In addition, participation factors and effective mass provide information about the most prominent modes in certain directions that will be excited by the forces in those directions, and if enough modes have been extracted for further analysis such as harmonic, response spectrum or random vibration. // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses that include videos, handouts, simulation examples with starting files, homework problems and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask your own question. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍 0:00 - Intro 0:50 - Introduction to Modal Analysis 1:39 - Calculate Natural Frequencies and Mode Shapes 3:23 - Understanding Participation Factor 4:32 - Understanding Effective Mass
На данном уроке мы рассмотрим расчет нагрузок на опору в разделе Ansys Mechanical. 00:00 Заставка канала 00:05 Создание 3D модели в компас 3D 05:56 Импорт 3D модели из компас 3D в Ansys Mechanical 07:33 Создание сетки 09:00 Создание условий расчета 11:10 Результат расчета Ссылка на Яндекс Дзен: 🤍 Уроки по Ansys: Урок №1 - Первичный расчет нагрузки на трубу в Ansys Mechanical 🤍 Урок № 3 - Расчет истечения рабочей среды мимо шара в Ansys Fluent 🤍 Урок №4 - Расчет теплового распределение в Steady-state Thermal 🤍 Урок №5 - Расчет нагрузок на полиэтиленовую трубу и выбор материала в Ansys 🤍 Урок №6 - Создание расчета перетока жидкости мимо объекта в CFD CFX 🤍 Урок № 7- Расчет нагрузок на педальный узел в Ansys Mechanical 🤍 Урок №8 - Расчет столкновения одного объекта с другим при помощи Explicit Dynamics 🤍 Урок №9- Построение модели болтового соединения и расчет в Ansys 🤍 Урок №10- Cоздание одноступенчатого горения в Ansys 🤍 Урок №11- Cоздание вращения объекта в Transient Structial 🤍 Урок №12- Cоздание перетекания рабочий среды через тройник в Ansys Discovery 🤍
Remote points are used to simplify the behaviour and kinematics of certain portions of the geometry with a single point. They help the user in defining remote boundary conditions like remote displacement and remote force along with elements like joints, springs, beam connections, point masses, moment loads, etc. which simplifies the model by reducing the complexity and hence the focus is only on the geometrical portions of the model that are of primary interest. This course will discuss the proper use of remote points along with the different behaviours of remote points. Benefits of using remote points along with certain aspects which the user must be aware of when using them are discussed. // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses, including videos, handouts, simulation examples with starting files, homework problems and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask your own question. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍 0:00 - Introduction 1:19 - What are remote points and where are they used? 2:12 - How is a remote point associated with the scoped geometry? 3:36 - How do the MPC equations work? 5:04 - Rigid vs. Deformable Behavior of Remote Points 12:58 - Define a Revolute Joint 14:45 - Applying Remote Force 17:18 - Discussion on need to Promote Remote Points
Response spectrum is a mode superposition linear analysis that uses the results of a modal analysis with a known spectrum to calculate displacements and stresses in the model. Three types of input excitation spectrum are supported: displacement, velocity, and acceleration. The mode coefficients are calculated by the program from the modal analysis participation factors and the spectrum values, and this is used to combine the modal responses to estimate the overall peak response; there is no deformed shape nor output as a function of time or frequency. // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses, including videos, handouts, simulation examples with starting files, homework problems and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask your own question. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍 0:00 - Intro 00:16 - What is response spectrum analysis? 01:23 - Introduction of the input spectrum 01:45 - How to create a response input spectrum 02:42 - How the single-point response spectrum works 07:31 - How to choose the modes combination type 07:52 - How to apply response spectrum load
Most metals undergo plastic deformation when subjected to loads beyond their elastic limit. During this deformation, they lose overall stiffness but undergo strain hardening, which increases their yield strength. In applications viz, metal forming and forging, it is important to include this behavior to accurately capture the mechanics. In Ansys Mechanical, this behavior is captured using several plasticity models, and multilinear hardening is one of the most used. It is easy to set it up, but one must understand how to extract the model parameters from experimental data. In this video, we will learn to define this material model from experimental data. For demonstration purposes, we used the data for the 316L stainless steel material published in this peer-reviewed article: 🤍 Access starting files for this lesson here → 🤍 // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses, including videos, handouts, simulation examples with starting files, homework problems, and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask questions. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍
When the length of a structural member is much larger than the cross-sectional dimensions, a line body is well suited to model the behaviour. When deciding when to use a line body, it is important to understand how a beam responds to different loading conditions, and what types of deformation we can expect. In this video, we will discuss when to use beam elements, what makes them unique, along with special considerations for their proper usage. Finally, we will review results that are specific to beam elements. We will do this via a short lecture and a walkthrough example using Ansys Mechanical. Also, we will show some tips and tricks to keep in mind when using beam elements. // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses, including videos, handouts, simulation examples with starting files, homework problems and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask your own question. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍 00:00 – Introduction 01:27 – When to use line bodies? 04:27 – Why use line bodies? 06:47 – What makes line bodies unique? 07:40 – Considerations for beam elements 09:54 – Results obtained from Beam Elements 13:25 – Extract beam line body from solid geometry 15:40 – Beam offset in Mechanical 20:59 – Post-Processing beam section results 23:43 – Summary
In this lesson, we will show when to take advantage of symmetry. If the geometry, material orientation, loading, and expected response all exhibit symmetry about the same planes, we can take advantage of planar symmetry and only model a portion of the actual structure to reduce analysis run time and memory requirements. Using Symmetry Regions in Ansys Mechanical can give more accurate and more computationally efficient solutions. However, the Symmetry Region tool should not be used when all four symmetry requirements are not satisfied, such as in modal or linear buckling analyses where non-symmetric modes are needed to be calculated. // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses, including videos, handouts, simulation examples with starting files, homework problems and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask your own question. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍 0:00 - Intro 2:11 - General rule for a planar symmetry boundary condition 2:46 - Defining the Symmetry Region for planar symmetry 4:46 - Visual expansion of symmetry results to show a “full” model for the planar case 5:28 - Understanding the conditions when Symmetry Region shouldn’t be used 8:55 - How to Split bodies for symmetry in Ansys SpaceClaim? 11:20 - How to connect line bodies with solid bodies via Contact Region in Ansys Mechanical? 12:20 - How to create and align local Coordinate Systems based on geometry? 13:21 - How to create Symmetry Region in Ansys Mechanical? 14:14 - How to define Bolt Pretension load in Ansys Mechanical? 16:20 - How to visually expand symmetry model results to show a “full” model for a sector?
This video demonstrates how to perform modal analysis using ANSYS workbench 2020 R2 and obtain natural frequencies and mode shapes of the structure. Please leave a comment if you have any questions. #ANSYS #fem #modalanalysis You can download all the files from: 🤍 Email id: notrealengineering🤍gmail.com "Music: 🤍bensound.com"
На данном уроке мы рассмотрим столкновение одного параллелепипеда с другим при помощи Explicit Dynamics. Движение одного параллелепипеда задается скоростью 50м/с 00:00 Интро 00:05 Создание геометрии в разделе space claim 03:05 Создание сетки 03:31 Создание условий расчета 05:01 Результат 1-го расчета(с недостатком времени контакта объекта) 05:12 Изменение времени окончания движения объекта 06:23 Изменение времени окончания движения объекта 07:00 Результат расчета Ссылка на Яндекс Дзен: 🤍 Урок №1 - Первичный расчет нагрузки на трубу в Ansys Mechanical 🤍 Урок № 2 - Расчет нагрузок на опору в Ansys Mechanical 🤍 Урок № 3 - Расчет истечения рабочей среды мимо шара в Ansys Fluent 🤍 Урок №4 - Расчет теплового распределение в Steady-state Thermal 🤍 Урок №5 - Расчет нагрузок на полиэтиленовую трубу и выбор материала в Ansys 🤍 Урок №6 - Создание расчета перетока жидкости мимо объекта в CFD CFX 🤍 Урок № 7- Расчет нагрузок на педальный узел в Ansys Mechanical 🤍 Урок №9- Построение модели болтового соединения и расчет в Ansys 🤍 Урок №10- Cоздание одноступенчатого горения в Ansys 🤍 Урок №11- Cоздание вращения объекта в Transient Structial 🤍 Урок №12- Cоздание перетекания рабочий среды через тройник в Ansys Discovery 🤍
Specifying an appropriate element size for finite element meshes is critical to obtaining accurate results in a reasonable amount of time. Coarse meshes may give inaccurate results if the stress gradients are too large for the elements to capture properly. Too small of an element size will unnecessarily increase the computation costs and solution times. Ansys Mechanical has various tools to specify the element size to achieve the typical end goal of a mesh-independent solution, where the results do not change with further increases in mesh density. In this video, we will illustrate the effects element size has on derived results quantities, such as stress and strain. We will cover several of the mesh sizing options available. While the proper element size may not be known before the solution, there are post-processing settings, such as results averaging and nodal differences to check the appropriateness of the element size specified. We have a short lecture and then we get into Ansys Mechanical to illustrate the concepts on a mechanical part. // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses, including videos, handouts, simulation examples with starting files, homework problems and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask your own question. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍 0:00 - Intro 2:21 - Contour Results Display Options: Averaged, Unaveraged, Nodal Difference 6:27 - Engineering Data: Material View 7:41 - Bearing Load 10:35 - Multiple Viewports 13:30 - Mesh Transition 15:01 - Scoping Results to Surfaces
This video shows how bolt-preloading is applied by splitting a bolt into two parts and connecting them using a constraint equation to create a state of tension. This process can be performed easily in Ansys Mechanical using the Bolt Pretension Object feature of the software. // INTERESTED IN MORE? Visit Ansys Innovation Courses for free courses, including videos, handouts, simulation examples with starting files, homework problems, and quizzes. Visit today → 🤍 // DOWNLOAD FREE ANSYS SOFTWARE Ansys offers free student product downloads for homework, capstone projects, student competitions, online learning and more! Download today → 🤍 // QUESTIONS ABOUT THIS VIDEO OR USING ANSYS? Get help from Ansys experts and peers through the Ansys Learning Forum. Search for answers to common questions, browse discussion categories or ask questions. Visit today → 🤍 // STAY IN THE LOOP Follow our Ansys Academic LinkedIn showcase page for updates on learning resources, events, job opportunities, cutting-edge simulation content and more! Follow today → 🤍
Contact autoabraham🤍gmail.com for 1. CFD flow and thermal analysis using ANSYS FLUENT 2. Structural, Thermal & Modal Analysis in Ansys Workbench For Geometry, Mesh, FLUENT Case & Workbench files, visit 🤍 🤍 🤍
На данном уроке мы рассмотрим расчет нагрузок на педальный узел. Нагрузка задаваемая составляет 7кН. Ссылка на 3D модель: 🤍 00:00 Заставка канала 00:28 Импорт 3D модели из компас 3D в Ansys Mechanical 01:02 Создание сетки 01:13 Создание условие расчета 02:24 Результат расчета Ссылка на Яндекс Дзен: 🤍 Урок №1 - Первичный расчет нагрузки на трубу в Ansys Mechanical 🤍 Урок № 2 - Расчет нагрузок на опору в Ansys Mechanical 🤍 Урок № 3 - Расчет истечения рабочей среды мимо шара в Ansys Fluent 🤍 Урок №4 - Расчет теплового распределение в Steady-state Thermal 🤍 Урок №5 - Расчет нагрузок на полиэтиленовую трубу и выбор материала в Ansys 🤍 Урок №6 - Создание расчета перетока жидкости мимо объекта в CFD CFX 🤍 Урок №8 - Расчет столкновения одного объекта с другим при помощи Explicit Dynamics 🤍 Урок №9- Построение модели болтового соединения и расчет в Ansys 🤍 Урок №10- Cоздание одноступенчатого горения в Ansys 🤍 Урок №11- Cоздание вращения объекта в Transient Structial 🤍 Урок №12- Cоздание перетекания рабочий среды через тройник в Ansys Discovery 🤍
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