Chanpen Thanomboon – รายงานประจำปีศูนย์เทคโนโลยีโลหะและวัสดุแห่งชาติ2020 https://www.mtec.or.th/annual-report2020 MTEC annual report 2020 Tue, 15 Dec 2020 09:13:35 +0000 en-US hourly 1 https://wordpress.org/?v=5.9.3 https://www.mtec.or.th/annual-report2020/wp-content/uploads/2020/08/cropped-arrow_y-32x32.png Chanpen Thanomboon – รายงานประจำปีศูนย์เทคโนโลยีโลหะและวัสดุแห่งชาติ2020 https://www.mtec.or.th/annual-report2020 32 32 Educational Software for the Learning of Computer-Aided Engineering (CAE) https://www.mtec.or.th/annual-report2020/en/educational-software-for-learning-of-computer-aided-engineering_en/ Mon, 19 Oct 2020 07:03:38 +0000 https://www.mtec.or.th/annual-report2020/?p=2841 "Educational Software for the Learning of Computer-Aided Engineering (CAE)"]]> 371 Views

> Prototypes for Public Usage

Computer-Aided Engineering (CAE) is the use of computer software to simulate physical phenomena occurring in engineering works. Noted examples of CAE techniques are Finite Element Analysis (FEA) and Computational Fluid Dynamics (CFD). This technology allows engineers to assess the performance of the design before creating a physical prototype that can be used for the validation and optimization of the products and processes.

The proper and efficient use of CAE is critically important because the computational result will influence the decision in engineering design. However, an improper use of CAE will lead to impractical results or unconverged solutions. Therefore, CAE users should comprehensively study this technology to acquire sufficient knowledge and skills.

The learning of CAE consists of two main parts, namely the theoretical part of the Finite Element and Finite Volume Methods and the use of CAE software. Learners should practice using CAE software by themselves to create computational models, submit computational jobs, and analyze the results to understand the physical phenomena occurring in a given engineering problem. 

At present, there are many CAE software packages, such as proprietary softwares and freewares. CAE proprietary packages usually require for license fees, and freewares packages are free of charge. Both freeware and proprietary software packages available usually contain complicated toolbars and menu bars that make them difficult to use. Therefore, CAE learners tend to pay more attention to the software operation procedures than the physical understanding of the problems problem in question.

The research team has developed an educational software package for learning CAE, called the software ‘CAE 3D’. This software was designed to be user-friendly by communicating with the user via GUI and it runs on Windows. It is a freeware that allows users to install and use the software with no cost on their personal computers. Using ‘CAE 3D’ along with the accompanying book titled ‘Computer-Aided Engineering’ can lead to comprehensive learning of CAE. Learners can study the fundamentals of CAE, differential equations, finite element and finite volume equations, and experience the use of CAE software to analyze engineering problems. 

‘CAE 3D’ software has been used as a learning tool of CAE technology in various channels, such as teaching and learning for bachelor’s degree and postgraduate students in the university, CAE training courses at MTEC, and self-learning of the general public. For those interested, the installation package and user’s manual can be downloaded from the website: www.mtec.or.th/cae3d.

Research team

Dr. Somboon Otarawanna and Computer-Aided Engineering Research Team

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Basket stretchers for transporting patients in emergency medical service systems https://www.mtec.or.th/annual-report2020/en/basket-stretchers_en/ Thu, 08 Oct 2020 04:31:35 +0000 https://www.mtec.or.th/annual-report2020/?p=2823 "Basket stretchers for transporting patients in emergency medical service systems"]]> 238 Views

> Prototypes for Public Usage

Thailand currently lacks emergency rescue equipment that is robust and reliable for transporting patients swiftly and safely in extreme environments and also affordable enough for widespread adoption. Such specialized rescue equipment is essential to the work of rescuers and emergency medical teams, especially those who work in extreme locations.

The National Institute for Emergency Medicine and National Metal and Materials Technology Center thus launched a collaborative research and development project to design and engineer an innovative basket stretcher that can be used in extreme rescue missions in Thailand, ranging from land to water to air rescues. The technical challenge was to develop a basket stretcher that was light, easy to transport, made of a robust material, surpassed the strength requirements of an international standard, and could support very heavy patients. The design and engineering must also take into consideration the manufacturing processes that would be practical and cost-effective for small-scale domestic producers.

The research team used the human-centric design approach to develop a new basket stretcher design, through iterations of observation, ideation, prototyping, and testing.

The observation stage involved discoveries of insights into the users and their use contexts, by interviewing the rescuers, nurses, EMS and EMT personnel, doctors, hospital staff, and governmental administrators, and observing their practices at different sites in remote mountains and sea. The needs, both functional and emotional, were distilled into a coherent problem definition and design brief.

Various ideas for solutions were developed during the ideation stage. Selected designs were modeled and analyzed for its strength using finite element analyses according to the NFPA 1983 standard.

Prototypes of the designs were built and provided to the users for testing. Lab-scale and field-scale prototypes were tested in Mae Hong Son province, in collaboration with representatives from 4 rescue organizations in the nearby areas.
The results both from the computer analyses and field tests indicated that the basket stretcher fulfilled the users’ requirements, with its light weight, high strength, and suitability for extreme environments.

The designed carabiner attachment points were proven to work effectively with the rescuers’ carabiner and rope systems. Additionally, the accessorial wheel systems were found to be helpful for traversing rough terrains. The basket stretcher was designed for domestic manufacturing, taking into account the local materials, production processes, and production costs.
Prototypes for public use and engineering drawings can be made publicly available to small-scale local producers or welders so that they can produce the basket stretchers and perform basic quality assurances by themselves.

This work should lead to widespread domestic production and sustainable adoption of high-quality basket stretchers, reduce the needs for imported stretchers, and ultimately improve the emergency medical systems in Thailand.

Research team

Sarawut Lerspalungsanti and Design and Industry Solutions Research Team

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