Programme
THURSDAY, 14 SEPTEMBER 2023
8.30 AM - 10.30 PM
Everly Hotel, Putrajaya
08:30 – 09:15 : Registration
09:15 – 09:45 : Keynote 1
at Mesmera 1 (Level 1)
09:45 – 10:15 : Keynote 2
at Mesmera 1 (Level 1)
10:15 – 10:45 : Opening Ceremony
at Mesmera 1 (Level 1)
10:45 – 11:00 : Coffee Break / Group Photos
11:00 – 13:00 : Parallel Sessions I
(8 presentations x 6 rooms)
13:00 – 14:30 : Lunch
14:30 – 15:30 : Parallel Sessions II
(4 presentations x 6 rooms)
15:30 – 15:45 : Afternoon Break
15:45 – 17:45 : Parallel Sessions III
(8 presentations x 6 rooms)
20:30 – 22:30 : Dinner/Best Presentation Award ceremony at Mesmera 2 (Level 1)
Keynote Speakers
Assoc. Prof. Dr. Muhd Ridzuan Mansor
Universiti Teknikal Malaysia Melaka (UTeM)
Dr. Ridzuan Mansor is currently an Associate Professor at Faculty of Mechanical Engineering, UTeM. He obtained his Phd in Mechanical Engineering from Universiti Putra Malaysia (UPM) in 2015, and has been in academic career since 2005. His research field of interest includes Concurrent Design, Design for Sustainability, Theory of Inventive Problem Solving (TRIZ), Multicriteria Decision Making, and Biocomposite materials. He is ranked among the World’s Top 2% Scientists List 2021 by Stanford University, USA.
Innovative Solution Generation using TRIZ Method in Concurrent Design of Products
abstract
This research article provides an overview of the TRIZ method and its application in the concurrent design of products. TRIZ is a problem-solving methodology that was developed in Russia in the mid-20th century and has gained popularity worldwide due to its effectiveness in generating innovative solutions. The article explains the history and evolution of TRIZ, and highlights its key advantages such as the ability to systematically identify and overcome contradictions and the use of a comprehensive set of inventive principles. The article also discusses the integration of TRIZ into concurrent design, which involves multiple design activities taking place simultaneously. The application of TRIZ in concurrent design can lead to faster and more efficient product development, as well as improved product quality and innovation. Overall, this article provides a valuable resource for researchers, designers, and practitioners interested in the use of TRIZ in concurrent design of products.
Dr. Eng. Indri Yaningsih
Universitas Sebelas Maret (UNS)
Dr Indri is an Assistant Professor at the Department of Mechanical Engineering, Universitas Sebelas Maret, Indonesia. She received the B.Eng. and M.Eng. in Mechanical Engineering from Universitas Sebelas Maret, Indonesia, during 2010 and 2012. She completed her Ph.D. in Engineering from the Department of Energy and Environmental Engineering, Kyushu University, Japan, in 2019. Her research is focused on thermal energy conversion systems, particularly on studying the science of fluid flows, including energy content and its transport with a low environmental impact. She currently works for the adsorption air conditioning system through experimental and numerical study.
Towards the Development of Adsorption Technology for Cooling and Dehumidification Applications
abstract
Considering the increase in the demand for air conditioning systems (ACS) for cooling and dehumidifying, which leads to high peak energy consumption, the development of an ACS with low energy consumption will be mandatory. Adsorption refrigeration system (ARS) technology is proposed as a potential ACS that could give almost an ideal condition to handle heat and moisture loads. But even if the ARS provides great advantages, the performance of this system is still not satisfying. The performance of the ARS depends on the sorption bed where the adsorption and desorption processes occur. In the ARS, the sorption bed acts as the compressor in the traditional vapor compression system, which controls the refrigerant's circulation. The sorption bed with a fin-tube heat exchanger construction should provide a large thermal conductivity to maximize the equilibrium uptake and refrigerant amount change. However, the commonly used sorption bed has poor thermal conductivity with high contact thermal resistance between the adsorbent and the heat exchanger. The current study will provide insight into how the ARS could be one of the alternatives for cooling and dehumidification by providing some attempts to improve ARS's performance and the analysis energy cost required to drive the system.