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200 10$aHeat transfer virtual lab for students and engineers $etheory and guide for setting up /$fElla Fridman and Harshad S. Mahajan
210  1$aNew York :$cMomentum Press,$d[2014]
210  4$dİ2014
215   $a1 online resource (128 p.)
225 1 $aThermal science and energy engineering collection
300   $aDescription based upon print version of record.
311   $a1-60650-548-3 
311   $a1-322-08766-0 
320   $aIncludes bibliographical references (page [105]) and index.
327   $a1. Introduction -- 1.1 History of distance learning and concept of virtual lab -- 1.2 What is virtual lab? -- 1.3 Analysis of the project requirements -- 1.4 Learning theory and its influence on role design -- 1.5 System architecture -- 1.6 Model hierarchy -- 1.7 Web user interface -- 1.8 Questions -- 
327   $a2. LabVIEW basics -- 2.1 LabVIEW introduction -- 2.2 G-language -- 2.3 Front panel -- 2.4 Block diagram -- 2.5 LabVIEW palettes -- 2.6 Programming with LabVIEW -- 2.7 Programming structures -- 2.8 Data acquisition with LabVIEW -- 2.9 Questions -- 
327   $a3. Hardware: Armfield Heat Exchanger and Service Unit -- 3.1 Operating HT30XC using customer-generated software -- 3.2 USB interface driver function calls -- 3.3 LabVIEW data logger -- 
327   $a4. Design of LabVIEW VI program -- 4.1 Software: algorithm of the program -- 4.2 Introduction of LabVIEW controls used in the project -- 4.3 Design of front panel -- 4.4 Design of block diagram -- 4.5 How were the PID parameters' values derived for temperature control? -- 4.6 Questions -- 
327   $a5. Experiments -- 5.1 How to perform an experiment using the LabVIEW interface? -- 5.2 How would a student access the experiment over the internet? -- 5.3 Experiment results -- 
327   $a6. Factors influencing the virtual lab -- 6.1 Drivers for programmable devices -- 6.2 Concurrent requirements for same experiment -- 6.3 User authentication -- 6.4 Issues surrounding live training -- 6.5 System management and development -- 6.6 Future developments -- 
327   $a7. Experiment instructions -- 7.1 Instructions for the shell and tube heat exchanger experiment -- 7.2 Instructions for the PID control for heater experiment -- 
327   $a8. Related work -- Bibliography -- Index.
330 3 $aLaboratory experiments are a vital part of engineering education, which historically were considered impractical for distance learning. In view of this, the proposed book presents a guide for the practical employment of a heat transfer virtual lab for students and engineers. The main objective of our virtual lab is to design and implement a real-time, robust, and scalable software system that provides easy access to lab equipment anytime and anywhere over the Internet. We have combined Internet capabilities with traditional laboratory exercises to create an efficient environment to carry out interactive, online lab experiments. Thus, the virtual lab can be used from a remote location as a part of a distance learning strategy. Our system is based on client-server architecture. The client is a general purpose java-enabled web-browser (e.g. Internet Explorer, Firefox, Chrome, Opera, etc.) which communicates with the server and the experimental setup. The client can communicate with the server and the experimental setup in two ways: either by means of a web browser, which runs a dedicated CGI (Common Gateway Interface) script in the server, or using the LabVIEW Player, which can be downloaded and installed for free. In both cases, the client will be capable of executing VIs (Virtual Instruments) specifically developed for the experiment in question, providing the user with great ability to control the remote instrument and to receive and present the desired experimental data. Examples of this system for several particular experiments are described in detail in the book.
410  0$aThermal science and energy engineering collection.
606   $aHeat$xTransmission$xComputer simulation
615  0$aHeat$xTransmission$xComputer simulation.
676   $a621.40220113
700   $aFridman$b Ella$01494984
702   $aMahajan$b Harshad S.
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200 10$aRubber Based Bionanocomposites $eApplications /$fedited by P. M. Visakh
205   $a1st ed. 2025.
210  1$aCham :$cSpringer Nature Switzerland :$cImprint: Springer,$d2025.
215   $a1 online resource (346 pages)
225 1 $aAdvanced Structured Materials,$x1869-8441 ;$v227
311 08$aPrint version: Visakh, P. M. Rubber Based Bionanocomposites Cham : Springer,c2025 9783031785566 
327   $aRubber based Bionanocomposites -- Cellulose based rubber nanocomposites -- Cellulose in rubber based blends and micro composites -- Chitin based rubber nanocomposites -- Chitin in rubber based blends and micro composites -- Starch based rubber nanocomposites -- Starch in rubber based blends and micro composites -- Soy Protein based Rubber composites and nanocomposites -- PLA based rubber composites and nanocomposites -- Bacterial Cellulose (BC)/ rubber composites and rubber nanocomposites -- Casein based rubber composites and nanocomposites -- Hemi Cellulose rubber composites and rubber nanocomposites -- PHA based rubber composites and nanocomposites.
330   $aThis book emphasizes on the various aspects of applications of rubber-based bionanocomposites. It summarizes in a comprehensive manner many of the recent research advances in the rubber-based bionanocomposites and their applications, such as biomedical packaging, structural applications, military applications, tire industry, and coating industry of different bionanocomposites of cellulose rubber, chitin rubber, starch rubber, soy protein rubber, PLA rubber, hemi cellulose rubber-based bionanocomposites. This book also discusses PHA-based rubber composites which covers an up to date record on the major findings and observations in the field of applications of rubber based bionanocomposites. This book serves as a ?one stop? reference resource for important research accomplishments in the above area. Academics, researchers, scientists, rubber technologist, biotechnologist, and students in research and development will benefit from an application-oriented book that helps them to find solutions to both fundamental and applied problems.
410  0$aAdvanced Structured Materials,$x1869-8441 ;$v227
606   $aContinuum mechanics
606   $aComposite materials
606   $aContinuum Mechanics
606   $aComposites
615  0$aContinuum mechanics.
615  0$aComposite materials.
615 14$aContinuum Mechanics.
615 24$aComposites.
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