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Simulation of Hydroforming using VDLOAD subroutine in Abaqus

(1)
 170.0

Explore the fundamentals of hydroforming simulation in Abaqus alongside the VDLOAD subroutine with our comprehensive guide. This tutorial unravels the essence of hydroforming, a specialized metal shaping technique applicable to diverse materials like steel, copper, and aluminum. Delve into the intricacies of sheet and tube hydroforming, crucial in manufacturing components for automotive, aerospace, and medical industries.

The workshop component specifically delves into advanced hydroforming simulation using the VDLOAD subroutine, emphasizing its role in specifying fluid pressure. Learn the application of the Smooth Amplitude option for defining part displacement without introducing dynamic changes during problem-solving. Conclude with a comparative analysis of simulation outcomes, exploring scenarios with and without fluid pressure, complemented by discussions on subroutine writing. This guide offers a straightforward exploration of hydroforming and VDLOAD, providing valuable insights for efficient and accurate simulations.

Hydroforming simulation in Abaqus

(1)
 39.0

Notice: This package will be available one week after purchase.

Hydroforming is a metal forming process that allows the shaping of various metals, such as steel, stainless steel, copper, aluminum, and brass. It is a cost-effective and specialized form of die molding that utilizes highly pressurized fluid to shape the metal. Hydroforming can be classified into two main categories: sheet hydroforming and tube hydroforming. Sheet hydroforming uses a single die and a sheet of metal, while tube hydroforming involves expanding metal tubes using two die halves. Hydroforming simulation in Abaqus is a valuable tool for optimizing the hydroforming process. It enables engineers to predict and analyze important factors such as material flow, stress distribution, thinning, and wrinkling during the forming process. By accurately simulating the hydroforming process, engineers can optimize key parameters like fluid pressure, die design, and material properties to achieve the desired shape with minimal defects. In this package, you will learn hydroforming process simulation with the SPH method and using time-pressure curve.

Lemaitre Damage model implementation with VUMAT Abaqus

(7)
 250.0

The Lemaitre damage model is now widely used to deal with coupled damage analyses for
various mechanical applications.

In this package, Firstly, we try to introduce the Lemaitre damage model, including damage mechanics and formulation of the Lemaitre damage model. Then, writing the Lemaitre subroutine is reached step by step. To do this job, the flowchart of the subroutine, Writing the subroutine line by line, implementation of the subroutine in one element and verification is done. In the last chapter, we implement this subroutine in a complex problem, the upsetting process.

 

ABAQUS Projects Package

(11)
 373.0

If you need common industrial simulations in the fields of forming, fracture, explosion, impact, etc., this package can provide you with comprehensive training along with an instructional video file and software file. You can quickly meet your educational needs in learning the elementary and intermediate level of Abaqus software using this package.

Simulation of forming in ABAQUS

(2)
 70.0

The forming in Abaqus is one of the most important manufacturing processes that can be used for producing different components. In this package, you will learn how to simulate the forming process in Abaqus and you can see the behavior of the material along this process. This package contains some examples that cover rolling, hydroforming, extrusion, ECAP, Cold forging, and drilling processes.

Notice: You can access this package 3 days after purchase. 

Forming simulations in ABAQUS

 170.0

 

In this training package, different types of forming simulations are presented along with different tips. These points include increasing the solution speed, different types of plasticity and damage models, different solvers, Lagrangian, CEL, and SPH methods and etc.

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