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Kuala Selangor, Malaysia

Limkokwing University of Creative Technology is a private international university with a presence across Africa, Europe and Asia. With its main campus in Malaysia, the university has over 30,000 students from more than 150 countries, studying in its 12 other campuses in Botswana, Cambodia, China, Indonesia, Lesotho, Sierra Leone, Swaziland and the United Kingdom accredited by Accreditation Service for International Colleges and Universities . Wikipedia.

Salman B.H.,Limkokwing University of Creative Technology | Mohammed H.A.,University of Technology Malaysia | Kherbeet A.S.,University of Tenaga Nasional
Heat Transfer - Asian Research | Year: 2014

In this paper, Eulerian, mixture and single phase models are used to simulate laminar and turbulent forced convective flow of SiO2-EG nanofluid in a microtube. The comparison between the three approaches and other formula shows that for laminar and turbulent flow the single phase model shows higher heat transfer enhancement and is more precise in comparison to the other Eulerian and mixture models. © 2014 Wiley Periodicals, Inc. Source

Salman B.H.,Limkokwing University of Creative Technology | Mohammed H.A.,University of Technology Malaysia | Kherbeet A.,University of Tenaga Nasional
International Communications in Heat and Mass Transfer | Year: 2014

Forced convective laminar flow of different types of nanofluids such as Al2O3 and SiO2, with a nanoparticle size of 30nm, and different volume fractions ranging from 0.5% to 1% using water as base fluids were investigated numerically and experimentally. This investigation covers the Reynolds number in the range of 90 to 160. The results have shown that SiO2-water nanofluid has the highest Nusselt number, followed by Al2O3-water, and lastly pure water. The maximum heat transfer enhancement was about 22% when using the nanofluids and the numerical and experimental results agree well with the conventional theory. © 2014 Elsevier Ltd. Source

Diwan S.A.,University of Wasit | Diwan S.A.,Limkokwing University of Creative Technology
International Journal of Applied Engineering Research | Year: 2016

This paper is presenting a model to make the dream of semantic web come true, it is just so far for the re-cent technology to completely move the whole internet Architecture to semantic Architecture, the model presented along this paper is to use personalization techniques to customize web servers in a way to make possessed web pages looks like it has been semantically composed. This model is a step toward a possible and meaningful synthesis of search engines and agent technology to participate in personalize customer needs and build semantic relations within the page content. © Research India Publications. Source

Raba R.A.Y.,Limkokwing University of Creative Technology | Awad M.M.I.,Alzahra University
3rd International Conference on Control, Engineering and Information Technology, CEIT 2015 | Year: 2015

The students' portal represents a major part among university information systems. Lack of components distribution is a gap that leads to many problems in students' portals in most of universities worldwide, which is due to tightly-coupled components in the current portal framework. This paper reviews the common features of the general portal structure. A comparison between the traditional students' portal framework and the new students' portal framework is presented. In addition, the paper discusses how to distribute the students' portal components. To achieve the components distribution of the portal, Service Oriented Architecture [1] is adopted to address the missing distribution feature. The research contributes towards the higher education field worldwide by providing a components distributable framework that could be followed as a base for building university portals with distributed components. © 2015 IEEE. Source

Muhieldeen M.W.,UCSI University | Adam N.M.,University Putra Malaysia | Salman B.H.,Limkokwing University of Creative Technology
Energy and Buildings | Year: 2014

In this paper, the cooling load of a lecture hall in a hot, humid climate requiring sustainable energy consumption is investigated experimentally and numerically. The polyethylene aluminium single bubble (PASB) is used as an insulating material placed on the external wall for the lecture hall with dimensions (15 m x 12 m x 6.6 m) at University Putra Malaysia (UPM), Selangor, Malaysia. The measurements of air temperature, air velocity, relative humidity and the number of students using the lecture hall for the whole month of April 2012 were used as input parameters for the three-dimensional computation of fluid dynamics (CFD). The results show that the potential temperature reduction inside the lecture hall was around 3 °C when using the (PASB) as insulating material, leading to a potential saving of 500 USD per month. © 2014 Elsevier B.V. All rights reserved. Source

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