2013 Moldex3D Global Innovation Talent Award Contest
Publish Date | 2013/07/23
FacebookTwitterLinkedInEmailShare
  • Event title: 2013 Moldex3D Global Innovation Talent Award Contest
  • Date: Jul 23, 2013-Dec 16, 2013
  • Location: Global
  • Event type: Past Events

主視覺-en

The Best Stage to Show Your Soft Power And Shine!

With Moldex3D CAE simulation software, any engineer can help their company create more value or benefits. In order to reward our users around the world, CoreTech System (Moldex3D) is hosting 2013 Moldex3D Global Innovation Talent Award. Just share practical application cases of Moldex3D, you’ll have a chance to win great prize, enjoy global exposure and recognition, and show potential customers and strategic partners your capabilities and core value. EN_Download pdf

We cordially invite you to participate this special opportunity to show the world your innovation talent of mastering CAE molding simulation tool, with unlimited possibility. Register NOW!

Contest Theme

All entries of successful stories, applying Moldex3D simulation software (any module) for design verification and optimization, are highly welcome.

Participants

The contest is divided into two categories: for professionals and for students. Each team may consist of up to 5 members, and each member needs to be from the same corporation or institution.

Requirements of Entry

  • Real cases and user’s experience with any module of Moldex3D simulation software, for new technology research, part design, mold design, mold manufacturing, or new product development.
  • Content shown could be one detailed analysis of product application, or the integrated application of a series of products.
  • Submissions may be submitted in one of the following languages: English or Chinese (simplified or traditional). Language used for submission will have no impact on one’s opportunity to win.
  • For category of Professionals, all products mentioned in the entries should be fully developed and ready to market.
  • All entries should be approved and agreed by the corporation/organization of participants.

Please note: All CAD models of the entries are required to be public disclosure, and consist no confidential content. Otherwise, the participants will be responsible for the consequences. Meanwhile, by submitting an entry to the competition, the participant transfers to CoreTech System (Moldex3D) Co., Ltd. the ownership in and to the submitted entry and grants an unlimited, non-exclusive, perpetual, irrevocable, royalty fee, worldwide license to CoreTech System (Moldex3D) to publish, use, amend, adapt, revise, distort and copy each entry to the public.

Important Dates

date-icon-en 2

Contest Prizes

The prizes will be awarded in two categories, Professional and Student, and the winners of each category will be announced on December 16, 2013. Winning entries from all categories will be prominently featured on event website, online publications, and social media platforms.

Professional Category

One (1) Grand Prize The winner will receive a medal and a US $3,300 cash prize
One (1) Second Prize The winner will receive a medal and a US $1,600 cash prize
One (1) Third Prize The winner will receive a medal and a US $800 cash prize
Special Prize The winner will receive a certificate of award and a US $300 cash prize

Student Category

One (1) Grand Prize The winner will receive a medal and a US $3,300 cash prize
One (1) Second Prize The winner will receive a medal and a US $1,600 cash prize
One (1) Third Prize The winner will receive a medal and a US $800 cash prize
Special Prize The winner will receive a certificate of award and a US $300 cash prize

Evaluation Criteria

Judging occurs in two rounds. Academic and industrial professionals will be invited to be the chairman and members of the judging team.

  • Initial Round Review: During the initial judging, only the Concept Introduction Forms are evaluated. Selected semi-finalists will be announced on October 18, 2013.
  • Second Round Review: The judges use the criteria below to evaluate all aspects of the entries.
    • Creative expression: Innovation and creativity of the theme (20%)
    • Tool application: Appropriate application with the modules and functions of Moldex3D simulation software (30%)
    • Practical value: Comparison of simulation analysis results and real parts (40%)
    • Overall performance: Complete and creative illustration of work (10%)

Registration and Submission

Registration
Submission
  • Full entry should be submitted no later than November 15, 2013.
  • Full entry consists of Agreement of Authorization, CAD model, and Report.
  • Report may consist of your research background, images of simulation and real part/mold, analysis results, ideas and executions of design changes, and its practical values, etc. (Download the Report Sample)
  • Late submission will be deemed as invalid entries.
Winners announced
  • Winners will be contacted via email and names displayed on our website no later than December 16, 2013.

Entry Submission

上傳程序示意圖-en

  1. Use FTP transfer software, like FileZilla (download at https://filezilla-project.org/download.php)
  2. Once installed, launch your software and fill in the following information.
    Host: ftp.moldex3d.com
  3. Zip your file and name it with your participant number, without any space and special symbol.
  4. Submit your zip file into the folder called “Moldex3D_Innovation_Talent_Award”.
    (The upload time will depend on your internet connection and could take several minutes. Please wait until the end of the transfer. )
  5. Email carolyhnren@moldex3d.com and ask for submission confirmation.

Host

CoreTech System (Moldex3D) Co., Ltd.

Contact

Ms. Carolyhn Ren
carolyhnren@moldex3d.com

Rules of Competition

  • To enter the competition, all participants must comply with the entry requirements. The participant acknowledges that failure to comply with the rules may result in his or her disqualification from the competition.
  • Participants shall declare that they own the copy right of their entries.
  • The participants should confirm that they have the right to submit the competition entry; all entries submitted by the participant are legal, and truthful and comply with all applicable laws, regulations, standards or codes of practice; all entries submitted do not infringe copyright, design, privacy, publicity, data protection, trademark, or any other rights of any third party.
  • The determination of the host shall be final in relation to the eligibility of any participant. No correspondence will be entered into about a decision regarding eligibility.
  • All entries will not be returned to the participants. Please keep your own copy.
  • All CAD models of the entries are required to be public disclosure, and consist no confidential content. Otherwise, the participants will be responsible for the consequences. Meanwhile, by submitting an entry to the competition, the participant transfers to CoreTech System (Moldex3D) Co., Ltd. the ownership in and to the submitted entry and grants an unlimited, non-exclusive, perpetual, irrevocable, royalty fee, worldwide license to CoreTech System (Moldex3D) to publish, use, amend, adapt, revise, distort and copy each entry to the public.
  • By submitting an entry to the competition, the participant transfers to CoreTech System (Moldex3D) Co., Ltd. the ownership in and to the submitted entry and grants an unlimited, non-exclusive, perpetual, irrevocable, royalty fee, worldwide license to CoreTech System (Moldex3D) to publish, use, amend, adapt, revise, distort and copy each entry to the public.
  • For any updated rules, please refer to our website: www.moldex3d.com
Back to Top

Compression molding simulation using Modelx3D for fiber reinforced materials

Presenter: U. Gandhi, Y. Song, Toyota Research Institute, North America


toyota Abstract:
The chopped fiber reinforced thermoplastic is desired material to meet the high production volume and lower cost targets that are typical for the automotive applications. Compression molding is one of the process that can help achieve these goals. However, predicting shrinkage and warpage of compression molded fiber reinforced polymer parts remains a challenge due to the anisotropic, nonlinear properties of the finished composite material and the related processing parameters during the molding. This presentation will showcase the research activities within Toyota research institute regarding the warpage prediction using Moldex3D for compression molded parts. Detailed fiber orientation analysis and warpage prediction from compression molding simulation is presented and also compared with the test results.
×

Benefits of Integrated Moldex3d mold filling simulation inside NX software

Presenter: Mark Anderson, Application Engineer, Siemens PLM Software


Siemens-Logo Abstract:
NX™ software from Siemens PLM Software is a next-generation solution that transforms the tooling development process with advanced automation. Knowledge-driven applications for tooling design, validation and manufacturing are fully integrated with the overall product development process in a managed environment that improves productivity, accelerates the process, reduces waste and cost and improves quality.

This presentation covers NX Mold Wizard product that applies Process Wizard technology to optimize the mold design process, delivering levels of productivity that dramatically outperform traditional CAD software. Providing a structured workflow based on expert best practices, automation of mold-specific design tasks and libraries of standard mold components. Additionally this session covers integrated Moldex3D mold filling simulation capabilities and how it benefits designers to easily check potential manufacturing defects without leaving the NX design environment.
×

activeGate Control technologies: Simulation and Case Studies

Presenter: Sal LoGrasso, Synventive


Synventive-logo Abstract:
Many injections molders use valve gated hot runner systems to mold their parts. Sequencing the actuators for a better filling pattern is a common practice among molders. When sequentially valve gating parts there is the possibility of molded in defects such as pressure transition marks on unpainted parts, reflection marks after a paint drying process, and hot spots directly opposite of the gate. These defects are a result of a change in pressures and the fact that polymer melt is compressible. These parts will usually be scrapped, costing the molder time and money.


This presentation shows how Moldex3D provides us with a way to not only predict when and where we will see these defects, but with the ability to simulate pin movement, allows us to see if the defects can be eliminated with Synventive activeGate controls.
 
×

Moldex3D’s Novel Simulation Capabilities

Presenter: Anthony Yang, Moldex3D North America


moldex3d-logo Abstract:
With each passing year, plastics industry is seeing new and smarter technologies emerging that help produce better quality parts. Moldex3D keeps in line with the latest technology that the industry is interested in and develops new modules for such technologies in each software release. With R14, Moldex3D has added several new features and technologies; this presentation will touch on some such innovative processes and some case studies showing how Moldex3D was successfully used to help with part / tool design.
×

Vision and Future Development of Moldex3D

Presenter: Dr. Venny Yang, President, CoreTech System (Moldex3D) Co., Ltd.


moldex3d-logo Abstract:
This presentation will provide company updates, highlight the major enhancements and verifications of Moldex3D’s latest version: Moldex3D R14, and preview the solver enhancements and the user interface developments of the next version, R15. In addition, several significant Moldex3D’s user success stories will be shared and discussed in this presentation.
×

Moldex3D Features for Improved Productivity & A Benchmark Case Study

Presenter: Moses Gnana & Linda Tseng, Molex


Molex Abstract:
In the first half of the presentation, Moses Gnana reviews few of the Moldex3D Features which help to improve the productivity of a CAE Engineer’s tasks from a perspective of a new user of Moldex3D, who has prior experience with other different CAD / CAE packages. The key features discussed are the results visualization and display tools such as Iso surface Display, Slicing Function, Measure Node Wizard, Weld Line & Air trap overlay, Model Manager, View Control panel etc. Few suggestions to enhance the user experience and productivity are also presented.


In the second half, Linda Tseng presents a benchmark case study in which the Moldex3D’s predicted results of a Connector Housing are compared with the results of another software package and also with the actual values.
×

FRP Airbag Housing Strength Prediction CAE Simulations: Integrating Fiber Orientation from Moldex3D FEA

Presenter: Nirmal Narayan, Systems Engineer, Autoliv North America


autoliv Abstract:
Fiber Reinforced Plastics (FRP) are widely used in Airbag Housings currently. Predicting the strength of FRP housings using FEA simulations are very critical during the product design and development process. The current FEA modeling methods assume the material as homogenous and isotropic. In reality the material is non-homogenous and anisotropic. The strength of the material is influenced by the orientation of the fiber.


FEA study was conducted to understand the benefits of incorporating fiber orientation data for characterizing the FRP material used in the Airbag Housing. In this study the fiber orientation data generated after the molding simulation, was exported from the Moldex FEA interface. The fiber orientation data was then used in the LS DYNA-DIGIMAT FEA solver to predict the strength of the material.


Physical test was also performed to compare the FEA results to the test. The results from the study were evaluated in terms of deflection and reaction loads.
×

Predicting the Behavior of Parts Molded with the MuCell® Microcellular Foam Injection Molding Process

Presenter: Levi Kishbaugh (Trexel, Inc)


Trexel Abstract:
The lightweighting targets of automotive companies are driving interest in microcellular foaming options and the design flexibility and weight reductions enabled by these technologies. Simulation of microcellular foaming is a critical part of the implementation process. This paper provides a brief review of the MuCell process and examines a case study using the Moldex3D Microcellular Injection Molding simulation module to predict the results achieved by applying the MuCell® process to an injection molded application.
×

Key Interactions with Simulation and Part Design

Presenter: RJG Inc.


RJG LOGO Abstract:
Are you concerned with how decisions made early on during product development will impact your simulation process? You can optimize the simulation efforts to balance these decisions, saving time and money. With the growing reliability of the simulation tools, manufacturability of the injection molded plastics can be evaluated thoroughly in the early design phase.


RJG Inc., is recognized as the leader in process training and instrumentation in injection molding industry deploys a workforce comprising of processing, material, tooling and simulation experts to develop a comprehensive process for injection molded parts namely from cradle to grave. Furthermore, this method can be tailored and transferred to the industry and evolved with the latest technology applicable.


We will demonstrate the influence of plastic behaviors on part design as well as, a systematic approach for utilizing simulation using an industrial case. The principal objective of this presentation is to demonstrate the major trade-offs made during the part, mold design and mold-machine match process.
×

The Importance of Manufacturing Simulation and Structural FEA in Fatigue Characterisation of Short Fibre Reinforced Thermoplastics

Presenter: Peter Heyes, HBM nCode


nCode_Partnership_Logo Abstract:
Fatigue analyses of engineering components and structures using tools such as nCode DesignLife are typically based on material curves relating applied cyclic stress or strain to fatigue life. For metals these curves are derived from simple tests wherein the stresses and strains are reasonably uniform in the gauge section of the test specimens.


The fatigue characterisation of injection moulded short fibre reinforced thermoplastics presents additional problems because the inhomogeneity and anisotropy of the test specimens leads to non-uniform stress and strain distributions at all scales. The derivation of transferable material properties therefore requires knowledge of the microstructure, detailed stress analysis of the test pieces, and some decisions about the definition of the damage parameter together with the scale over which it should be determined.


This presentation shows how manufacturing simulation with Moldex3D and structural FEA form part of the process of deriving fatigue properties for use in nCode DesignLife. The material used is a short glass fibre-reinforced polyamide. The simulation results are compared with measurements of microstructure, and with stresses and strains from tensile and cyclic (fatigue) tests.
×

Integrating Moldex3D and Digimat for Multi-scale Material Modelling for End-to-end Plastic Solutions

Presenter: Ron Rogers, Business Development Manager, e-Xstream engineering


Digimat Abstract:
Reinforced plastics are increasingly being used in multiple industries (automotive, electronics, consumer goods, …) as a replacement to metal solutions. Reinforced plastics indeed offer an increased flexibility for design, ease of processing as well as lightweighting capabilities. However, they also bring a series of challenges: reinforced plastics behavior is usually highly non-linear, anisotropic, temperature/strain rate dependent and most importantly process dependent.


Early design of reinforced plastic parts has classically faced many difficulties: process information such as fiber orientation might not be available yet, many iterations of design are required in a very short cycle time, material behavior is hardly accessible. These challenges add up to the common difficulty of designing plastic parts with metal based design tools, considering homogeneous isotropic material behaviour.


This presentation will demonstrate how Digimat can help to overcome those challenges to accelerate the design of plastic parts, from early design to final validation.
×
Terms and Conditions

1. Definition
a. Portal means Moldex3D Channel Partner Portal is a portal hold by Moldex3D exclusively to its Resellers.
b. Reseller means the company who has signed the Reseller Agreement, VAR Agreement or Distributor Agreement with Moldex3D.
c. Member means a Reseller who signs up for Moldex3D Channel Partner Portal, and was accepted by Moldex3D.
 
2. This Portal authorizes only the staffs of an approved Reseller to use the documents and media provided in this Portal. The Member should use the document or media shared in this Portal only to promote Moldex3D. Other usage conditions should follow the Moldex3D Reseller Agreement.
 
3. Each Member can have a maximum of 2 accounts in this Portal.

 

4. A Member shall never share the account and password to a third party or any individuals.

 

5. A Member is responsible for keeping the account and password from leaking to the others by former employees.

 

6. If any terms or conditions conflict with the signed Moldex3D Reseller Agreement, the Member should still follow the ones in the Moldex3D Reseller Agreement.

 

7. Moldex3D reserves the following rights:
a. To terminate this Portal.
b. To modify the terms and conditions of this Portal.
c. To suspend or terminate a Member’s registration.

×

Special Prize

Beijing University of Chemical Technology

Improvement on the 2.5 Inch NPSM Screw Thread Requirement of a Plastic Bottle Cap


2015GITA_s09 Problem:
The goal of this project was to minimize the volumetric shrinkage of a plastic bottle cap in order to meet the 2.5 inch NPSM screw thread requirement without compromising the final product quality. With this goal in mind, an in-depth study on the mold cavity dimensional design was conducted in hopes of successfully controlling the precision of the screw thread within the acceptable tolerance.

Solution:
Two important processing parameters that influence the part shrinkage are packing pressure and packing time. In this study, Moldex3D was utilized to optimize the part/mold design and further identify the appropriate packing conditions to successfully adhere to the NPSM screw thread requirement.

Benefit:
BUCT was able to successfully control the precision of the screw within the acceptable tolerance. The part reject rate was significantly lowered from 90% to 5% which ultimately helped generate a greater business value for manufacturing companies, as well as, reducing material wastage.

Software used:
Moldex3D Advanced
Fiber
Flow
Pack
Warp

×

Special Prize

National Yunlin University of Science and Technology

The Study of Product Warpage in Co-injection Molding


2015GITA_s08 Problem:
In co-injection molding, warpage is strongly associated with its core/skin material ratio. In order to improve product warpage, the team turned to the help of Moldex3D’s MCM solution to gain an in-depth understanding of co-injection molding. The effects of skin/core material ratio, processing parameters, and warpage behavior are investigated further in this study in order to improve product warpage.

Solution:
Moldex3D’s solution for multi-component molding (MCM) was utilized in this study. Simulation results helped identify the potential problematic areas and pinpoint the crucial factors influencing the product warpage in the early product development stage. The accurate simulation results were further validated by an actual mold-trial. Through Moldex3D simulation analyses and the actual mold-trial results, the team was able to clearly understand the phenomenon of the skin/ core ratio and further concluded that the product warpage could be improved by adjusting the amount of the injected core material, lowering the melt temperature, and reducing the flow rate of the first shot.

Benefit:
– Reduced warpage
– Optimized process parameters

Software used:
Moldex3D Advanced
Flow
Warp
Co-injection
MCM

×

Special Prize

National Chiayi University

Applying Static Mixers in a Multi-cavity Design to Reduce Runner’s Corner Effect


2015GITA_s07 Problem:
In order to facilitate mass production and reduce overall costs, a multi-cavity system has been a prevalent mold design to improve production efficiency. However, a flow imbalance issue has been a commonly-found trouble experienced by many mold designers. Generally speaking, adding one more cavity, the product precision would decrease approximately by 4%.

Solution:
Moldex3D analysis was utilized to precisely simulate the injection molding process of a multi-cavity system. NCU was able to observe the cutting, rotating, and mixing effects of the plastic meltafter applying static mixers in the runner design, evaluate the static mixer’s performance, and test different static mixer designs. Thus, at the end, NCU could identify the best static mixer design to further solve the flow imbalance issue of a multi-cavity system.

Benefit:
– According to Moldex3D analysis results, the temperature distribution and flow balance could be improved effectively after the plastic melt passed through a static mixer.
– Moldex3D particle tracer was applied to better analyze the polymer particle filling behavior inside the cavity, making it easier to compare the pros and cons of using different static mixer designs and identify the best static mixer placement arrangement in order to achieve the most optimal design.

Software used:
Moldex3D Advanced
Moldex3D eDesign

×

Special Prize

National Taiwan University of Science and Technology

The Study of the Effect of Glass Fibers on Poly Lactic Acid (PLA) and Structural Integrity


2015GITA_s06 Problem:
Environmentally degradable polymers and plastics (EDPs) are a group of polymeric materials experiencing a rapid growth in number as well as in their applications and quantities used. Polylactic Acid (PLA) is a biodegradable thermoplastic derived from renewable resources, such as corn starch, tapioca roots, chips or starch, or sugarcane. PLA can be used in manufacturing products like food containers as well as medical bone screws and plates. This goal of this study is to get a more comprehensive understanding of how glass fibers including both long and short fibers influence the mechanical properties of PLA products and pinpoint the important injection molding processing parameters in order to serve a valuable reference for future PLA product development.

Solution:
Moldex3D simulation technology was utilized to study the two different molding scenario of using PLA material with and without adding any fibers. Next, a detailed simulation analysis was done to further differentiate the effects of using short and long fibers in injection molding process with PLA material. Then, Moldex3D FEA interface was used to transfer essential injection molding simulation data to ANSYS software for a further analysis on product structural integrity.

Benefit:
Through Moldex3D simulation analyses, NTUST was able to understand that the fiber orientation result is highly associated with the filling behavior and they could further identify the different fiber orientation results in the freeze layer, the shear layer and the core layer. Then, with a close integration of Moldex3D and structural analysis software-ANSYS, a more precise analysis on product structural integrity could be achieved. Thus, with the accurate simulation results, NTUST was able to conclude that long fibers possess better functionality over short fibers due to its superior performances in fiber orientation, tensile strength, impact strength, and warpage.

Software used:
Moldex3D Advanced
Stress
Fiber
FEA Interface

×

Special Prize

National Kaohsiung University of Applied Sciences

The Cause of Sink Marks and the Dynamic Measurement of Thick Lens for Automotive


2015GITA_s05 Problem:
Thick lens molding has become a future trend for automotive lighting applications. However, undesirable product defect- sink mark is one of the biggest technological challenges in the production of thick-wall parts. It is due to the residual heat within the center of the thick lens parts after the parts are ejected from the mold cavity; thus, it gives rise to a possible re-softening of the already solidified part surface which ultimately leads to unwanted sink marks.

Solution:
Moldex3D was utilized in this study to validate the residual heat phenomenon and the occurrence of sink marks. Thus, the purpose of this study is to find out the most appropriate processing parameters for a sufficient cooling to avoid sink marks which ultimately leads to better production efficiency.

Benefit:
By utilizing Moldex3D analysis, NKUAS was able to successfully predict and avoid potential problems that might lead to poor product quality; thus the production efficiency could be greatly enhanced.

Software used:
Moldex3D eDesign
Optics

×

Special Prize

National Kaohsiung University of Applied Sciences

Applying MCM Process in Thick Lens Design


2015GITA_s04 Problem:
Thick wall processing issues which can include sink marks, voids/bubbles, jetting marks and longer cooling times. The visual defects are caused by a bigger mold cavity space and part shrinkage induced by the solidified plastic melt; longer cooling times are generally a result of the poor thermal conductivity caused by the uneasy heat dissipation within the thick wall sections of the part.

Solution:
This study features an optical lens with a heavier thickness design of 12mm. The concept of MCM sandwich molding was implemented in the form of B-A-B molding sequence layer design. Moldex3D’s MCM analyses were utilized to study the appropriate thickness design for A and B layers in order to achieve the shortest cooling time.

Benefit:
– Cooling time were drastically shortened by 50-60% after changing the thickness of A layer to twice as thick of B layer.

Software used:
Moldex3D Advanced
Optics
MCM

×

Third Prize

The Ohio State University

Microinjection Molded Miniature Freeform Alvarez Lenses


2015GITA_s03 Problem:
Microinjection molding is a mass production method to fabricate affordable optical components. However, the intense nature of this process often results in part deformation and uneven refractive index distribution. These two factors limit the precision of replicated optics.

Solution:
In order to understand the influences of injection molding to freeform optical devices, in this study, Moldex3D’s finite element method (FEM) was employed to investigate the miniature microinjection molded Alvarez lenses. In addition, Moldex3D was also used to explain the differences between the nominal and experimentally measured wavefront patterns of the microinjection molded Alvarez lenses.

Benefit:
– Utilized the information of part deformation and uneven refractive index to calculate the optical aberrations of the injection molded Alvarez lens
– Significantly increase production yields by 99%
– Compensated optical aberration by modifying the original surface to obtain ideal MTF results

Software used:
Moldex3D Advanced
Optics

×

Second Prize

National Kaohsiung University of Applied Sciences

The Study of Volumetric Shrinkage using Zirconia Ceramic for Artificial Dental Roots with Two-shot Sequential Molding Application


2015GITA_s02 Problem:
As opposed to using conventional molding, one of the concerns of applying MCM process in manufacturing is the interchangeable mechanism between the different materials. When two or more materials are injected in the mold to form a part, the intricate interface between the different materials and the complexity of the geometric design are strongly related to the final product quality. Molding problems like an imbalanced flow behavior might lead to undesirable defects such as stress concentration or residual stress which ultimately influences the interface bonding strength and the overall product life span. Therefore, potential molding problems for example, product shrinkage and deformation might occur due to the different material properties and geometric part designs, and the quality of the finished products might be compromised.

Solution:
Utilize Moldex3D simulation to analyze PIM and MCM processes in order to further determine the proper product structure design and examine potential molding problems, such as short shots, air traps, excessive pressure, uneven cooling, or warpage. In order to improve the product quality, NKUAS resorted to Moldex3D’s solutions to simulate PIM and MCM processes to further observe the phase separation phenomenon of the powder and the adhesive, and visualize insert molding in hopes of determining the most optimized design. The accurate prediction on the powder density and distribution prevented the occurrence of stress concentration and residual stress and the ultimate goal of reducing volumetric shrinkage and product warpage could be achieved.

Benefit:
– Improved powder concentration distribution
– Solved warpage problem
– Enhanced the part quality by 71.15%

Software used:
Moldex3D eDesign
Powder Injection Molding
MCM

×

First Prize

Chung Yuan Christian University

A Study of the Influences of Processing Parameters and Glass Fiber Material on Part Roundness using Moldex3D


2015GITA_s01 Problem:
One of the biggest challenges encountered in the camera lens hood production is “warpage.” Warpage is generally caused by the uneven shrinkage of the part. It is believed that if the volumetric shrinkage is consistent throughout the whole part, the roundness value of the part will only become smaller in size instead of resulting in product deformation or warpage. However, controlling a consistent shrinkage volume throughout the whole part is a complex task and not easy to achieve; many factors such as fiber orientation, mold cooling, processing parameters, etc. affect the success of the shrinkage control.

Solution:
With Moldex3D analyses, Chun Yuan University was able to attain the most optimal processing parameters, as well as, gain a comprehensive understanding of how glass fiber material influences the precision roundness of the part. The accurate simulation results were validated by an actual mold trial and the ultimate goal of improving the precision roundness of the part within the tolerable range could be further achieved.

Benefit:
– Achieved a balanced fill pattern
– Optimized the part roundness by 35%

Software used:
Moldex3D eDesign
Fiber

×

Special Prize

Linear Mold & Engineering

Improvement of Injection Molding Cycle Process


2015GITA_b09 Problem:
With injection molding many tools have longer than acceptable run times due to the limitations of conventional cooling methods. In addition to the longer run times, warpage is a serious factor when producing parts and often times result in excessive scrap in any attempts to reduce cycle time. The aim of this project was to help a customer to improve unacceptable lengthy run times on a tool.

Solution:
Linear Mold & Engineering utilized Moldex3D software to analyze a conventional cooling approach to a tool in question, showing where the areas of concern were that would demand long run times and produce extensive warpage of the part. Taking the results Moldex3D produced, Linear Mold then developed a solution in the form of conformally cooled components to replace or modify existing components in the tool to streamline the injection process. With a small amount of cycle process modification over the course of a day, the customer achieved the time savings Linear Mold predicted within a 3% margin of error.

Benefit:
– Reduced cycle times by 50 %
– Solved warpage problem
– Developed a competitive advantage in the market

Software used:
Moldex3D Advanced
Flow
Pack
Cool
Warp
Fiber
Stress
CADdoctor

×

Special Prize

Calin Technology Co., Ltd.

Moldex3D Injection Molding Simulation Applications in Projector Lens


2015GITA_b08 Problem:
The weld line occurred on the surface of the project lens when the melt entered the thin section in the middle of the part. The finished part needed to achieve uniform residual stress in order to maintain excellent optical properties.

Solution:
Moldex3D was utilized to optimize process parameters and run virtual molding simulations. It helped Calin Technology to determine the best combination of process settings for molding the projector lens. Using the optimum process conditions along with compensation method technology, Calin Technology was able to compared the simulation results to experimental results and verified that the requirements had been met with the help of Moldex3D.

Benefit:
– Improved weld lines to meet surface quality
– Achieved uniform distribution of shear stress

Software used:
Moldex3D Advanced
Moldex3D eDesign
Flow
Pack
Cool
Warp

×

Special Prize

KOPLA

Solving Warpage Problem through Injection Analysis and Structural Analysis


2015GITA_b07 Problem:
In this project, KOPLA was tasked with reducing the risk of assembly problems on a door module part. The door module part consisted of many mounting holes for assembly purpose. Therefore, the location of the mounting holes was very crucial and required thorough investigation.

Solution:
KOPLA utilized Moldex3D simulation solution to identify the optimum gate location that could lead to good flow pattern and low warpage displacement. After the best gate location was identified, KOPLA output the warpage simulation result to ANSYS using Moldex3D FEA interface to increase the accuracy of the structural analysis.

Benefit:
– Obtained more realistic structural analysis
– Reduced cycle time and improved product quality

Software used:
Moldex3D eDesign
FEA Interface
Flow
Pack
Cool
Warp

×

Special Prize

Metal Industries Research Development Centre

Analyzing the Optical Properties of a Double-sided Micro Lens Array in Laser Projectors


2015GITA_b06 Problem:
Micro lens arrays (MLA) are one of the key components of laser-illuminated projector systems. After injection, the lens usually will warp as it cools because of the large difference in temperature. In this study, the Metal Industries Research Development Centre (MIRDC) aimed to use Moldex3D Optics for molding condition optimization to reduce optical quality issues, e.g., shrinkage, cracks, and residual stresses etc., to ensure uniform brightness.

Solution:
To effectively reduce residual stresses and warpage, Moldex3D enabled MIRDC to determine the optimal processing conditions through the Design of Experiments analysis, varying mold temperature, injection velocity and packing pressure factors. The simulation results then were compared to experimental results to further investigate the fringe orders and optical paths. The results showed that higher velocity can help improve the fringe orders and optical paths, and increased packing pressure and time can help improve warpage.

Benefit:
– Improved warpage by 30%
– Reduced optical path difference from 3.483X10-4 mm to 1.460X10-4mm
– Cut down mold trials and save costs

Software used:
Moldex3D Advanced
DOE
Optics
Flow
Pack
Cool
Warp

×

Special Prize

Synventive Molding Solutions

Using Moldex3D to Simulate Synventive’s activeGate™ Technologies


2015GITA_b05 Problem:
With large injection molded parts, it is common to use a multiple drop hot runner system. Also common with this type of part is to use sequential filling as to eliminate weld lines. However, when molders use sequentially valve gates, there is a possibility that some common defects will occur. These defects are pressure transition marks on unpainted parts, reflection marks after a paint drying process and hot spot marks opposite of a direct gated nozzle. These defects are a result of a change in pressures and the fact that polymer melt is compressible.

Solution:
In this project, two analyses were conducted. The first analysis was done with standard sequential valve gating and was designed to see if the simulation can help identify the problem areas. The second simulation was also sequenced, but opening strokes of the delayed pins were controlled. The purpose of the second analysis was to find out if the simulation can help validate the activeGate controls. With Moldex3D simulations, Synventive were able to identify molded parts that could potentially have defects, which would cost time and money, before the tool is ever machined. Additionally, the ability to simulate the advanced pin control allowed Synventive to alter the characteristics of the fill and possibly eliminated any defects found in the injection molded part.

Benefit:
– Enabled pin movement simulation to identify defects that can be eliminated by activeGate controls
– Early detection of common defects in injection molded parts
– Saves molders time and money by scrapping less parts

Software used:
Moldex3D Advanced
Advanced Hot Runner

×

Special Prize

Acer Inc.

Using Design of Experiment (DOE) Analysis to Solve Ink Washout and Stress Issues in Thin-wall Injection Molded Ultrabook Base Cases


2015GITA_b04 Problem:
In-mold Roller (IMR) technology is widely used in manufacturing ultrabook cases, which can provide scratch-resistance and design flexibility advantages. However, in this case, the thin-wall injection molded base case of the ultrabook had ink wash-out and stress issues. Moreover, the base case needed to meet the product specification for a wall thickness of 0.8mm.

Solution:
Moldex3D Design of Experiment (DOE) analysis was implemented to determine the optimum gate type and processing conditions. Acer used the optimum processing conditions obtained from the DOE analysis to adjust gate and wall thickness designs to avoid ink washout and stress issues.

Benefit:
– Minimized ink washout and residual stresses
– Optimized wall thickness by 48%
– Reduced product weight by 40%

Software used:
Moldex3D eDesign
DOE

×

Third Prize

TYC Brother Industrial Co., Ltd.

Solving Air Traps in BMC (Bulk Molding Compound) Automotive Headlight Reflectors


2015GITA_b03 Problem:
BMC (Bulk Molding Compound) reflectors are one of the most important components of headlights. Molding BMC reflectors is quite challenging due to the high surface quality requirements; surface defects will cause problems in the aluminizing process. In this case, TYC needed to overcome the quality issue of air traps in the mold to meet the demands from the customer.

Solution:
TYC used Moldex3D Advanced for filling simulation analysis of the BMC reflector part. The analysis result accurately identified where the air traps would be in the original design. Moreover, Moldex3D helped TYC validate how changes to gate locations and wall thickness can affect air trapping before making physical changes in tools.

Benefit:
– Eliminated air traps
– Reduced costly physical prototypes

Software used:
Moldex3D Advanced
Flow

×

Second Prize

TomTom

Using Moldex3D to Reduce Warpage in a Cradle of Truck GPS Navigation Device


2015GITA_b02 Problem:
The front cover of the truck GPS navigation cradle is made with nylon with 50% fiberglass. During the injection molding process, the warpage occurred and led to a gap between the front and back covers, exceeding the given tolerance.

Solution:
TomTom used Moldex3D eDesign with Fiber simulation capability to investigate the root cause of warpage and the contribution of each variate to the total warpage of the product. Through the contributing factor study, TomTom was able to identify the major factors affecting the warpage. By combining all these key factors, TomTom was able to make the critical design decision quickly and accurately, and successfully reduces the risk of assembly problems.

Benefit:
– Minimized the assembly gap from 2.3mm to 0.3mm to meet dimensional specifications
– Increased yields by 92%
– Saved money and development time

Software used:
Moldex3D eDesign
Fiber
Flow
Pack
Cool
Warp

×

First Prize

Lite-On Technology Corporation

Improving the Warpage in a Scanner CIS Holder Part using Moldex3D and LS-DYNA


2015GITA_b01 Problem:
The holders, which are used to fix contact image sensors (CIS) in scanners, got warped during shipment due to the relief of internal stresses, causing the CIS holder detached from the scanner glass. This could have a critical impact on the depth of field and even cause some noise (speckles) on the image.

Solution:
To understand factors contributing to warpage, Lite-On utilized Moldex3D to simulate the effects of different design approaches, such as changes to gate locations, mold temperature and reducing materials. Comparing the analysis results, Lite-On determined which design had the minimum amount of warpage displacement. Next, Lite-On exported the simulation result of the optimal design to LS-DYNA using Moldex3D FEA interface and further investigated the internal strength of the part. This simulation, combined with structural analysis capabilities, helped Lite-On make informed decisions before making costly changes to existing part designs.

Benefit:
– Shorten product development cycle by 13%
– Significantly increase production yields by 99%
– Cut manufacturing costs

Software used:
Moldex3D Advanced
FEA Interface (integrated with LS-DYNA)
Flow
Pack
Cool
Warp

×