Wyniki wyszukiwania - BazTech

1

Detection of inner defects in industrial pipelines using transient IR thermography

Kopeć M., Chatzipanagiotou P., De Mey G., Więcek B.

Measurement Automation Monitoring

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2017

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Vol. 63, No. 3

115--118

EN

A long time operation of pipelines can lead to the reduction of their wall thickness. This process is accelerated by high temperature and variable pressure of the transported medium and can finally cause mechanical failures along with leaks and danger of explosion. The aim of this paper is to present a new method for the detection of abraded walls in industrial pipelines using the time-frequency analysis. The results of transient temperature measurements are used for the calculation of the thermal time constants corresponding - as demonstrated - to the pipeline wall thickness.

2

Convection and radiation cooling of overhead power lines - laboratory verification using thermography

Chatzipanagiotou P., Felczak M., De Mey G., Chatziathanasiou V., Więcek B.

Measurement Automation Monitoring

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2017

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Vol. 63, No. 3

107--110

EN

The thermal behavior of overhead power lines depends upon physical parameters, such as surface emissivity and line dimensions, as well as weather conditions. In this paper, the results of the convection and radiation cooling of a conductor that simulate a power line are presented. Laboratory experiments were conducted and the results were compared with the data obtained using empirical formulae from the literature. Both the laminar and the turbulent airflow were investigated.

3

A new software tool for transient thermal analysis based on fast IR camera temperature measurement

Chatzipanagiotou P., Strąkowska M., De Mey G., Chatziathanasiou V., Więcek B., Kopeć M.

Measurement Automation Monitoring

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2017

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Vol. 63, No. 2

48--51

EN

A new software tool for transient thermal analysis based on thermographic measurement of temperature is presented. In the proposed approach, temperature change after applying or removing power can be measured by a thermal camera or any contact temperature sensor. The software calculates thermal impedance in frequency domain and represents it in the form of the Nyquist plot. In addition, thermal time constant spectrum and cumulative structure function are evaluated. The software was developed in Matlab environment using in-built procedures for transfer function estimation. For the validation of the proposed tool, the results are compared with ones obtained using commercially available software.

4

Various applications of complex thermal impedance for transient and AC heat transfer analysis

Więcek B., De Mey G., Strąkowska M., Chatziathanasiou V., Gmyrek Z., Strzelecki M., Chatzipanagiotou P.

Measurement Automation Monitoring

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2015

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Vol. 61, No. 6

210--214

EN

This paper presents the concept and three practical examples of using complex thermal impedance for characterisation different thermal objects. The first problem describes estimation time shift between power and temperature in electric distribution systems with non-sinusoidal currents. The second example discussed here, shows the estimation of power losses distribution in the magnetic punched ferromagnetic strips. The third application presents the inverse thermal modelling of 3-layer biomedical objects (tissues) to estimate the thermal parameters. More details of the presented problems are in the appropriate papers of the authors referenced here.

5

Application of thermal impedance to inverse heat transfer modeling of power cables

Więcek B., Strąkowska M., De Mey G., Chatziathanasiou V., Chatzipanagiotou P.

Pomiary Automatyka Kontrola

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2013

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R. 59, nr 9

946--949

EN

This paper presents the inverse heat transfer modeling in applications to the power cables. In order to simplify the calculations, the inverse modeling implements thermal simulations in frequency domain. Due to the cylindrical summery of the power cable, this model has an analytical solution, which simplifies using Bessel functions. The inverse model allows estimating the thermal parameters of the material the cable is made of. It can be used for defect detection and aging of the cable. The model was made in Matlab®, and compared with the results obtained from COMSOL® simulation software.

PL

W pracy przedstawiono zastosowanie modelowania cieplnych zjawisk odwrotnych do wyznaczania wartości parametrów termicznych kabli energetycznych. W procesie modelowania odwrotnego struktury wykorzystano model w dziedzinie częstotliwości, który dla struktury o symetrii cylindrycznej ma rozwiązanie analityczne przy użyciu funkcji Bessela. Model termiczny wraz z optymalizacją opracowano w programie Matlab®. Wyniki modelowania odwrotnego zweryfikowano rezultatami uzyskanymi z symulacji 3D wykonanych za pomocą oprogramowania COMSOL® oraz za pomocą danych pomiarowych, uzyskanych z kamery termowizyjnej. Opracowana metoda może być wykorzystana w praktyce do oceny stanu kabli energetycznych, ich zużycia, do wykrywania defektów związanych np. z korozją oraz do oszacowania warunków odprowadzania ciepła z kabli do otoczenia. W konsekwencji na podstawie wyników termowizyjnych można wyuczyć wartość impedancji termicznej kabla, co pozwoli oszacować maksymalną wartość temperatury w określonych warunkach pracy. Na obecnym etapie badań wykonano model kabla z litego materiału. Kolejnym krokiem będzie opracowanie modelu kabla wielowarstwowego, w tym z izolacją o małej przewodności cieplnej.