Conditions for the use of infrared camera diagnostics in energy auditing of the objects exposed to open air space at isothermal sky

Convective and radiation heat transfer take place between various objects placed in open air space and their surroundings. These phenomena bring about heat losses from pipelines, building walls, roofs and other objects. One of the main tasks in energy auditing is the reduction of excessive heat losses. In the case of a low sky temperature, the radiation heat exchange is very intensive and the temperature of the top part of the horizontal pipelines or walls is lower than the temperature of their bottom parts. Quite often this temperature is also lower than the temperature of the surrounding atmospheric air. In the case of overhead heat pipelines placed in open air space, it is the ground and sky that constitute the surroundings. The aforementioned elements of surroundings usually have different values of temperature. Thus, these circumstances bring about difficulties during infrared inspections because only one ambient temperature which represents radiation of all surrounding elements must be known during the thermovision measurements. This work is aimed at the development of a method for determination of an equivalent ambient temperature representing the thermal radiation of the surrounding elements of the object under consideration placed in open air space, which could be applied at a fairly uniform temperature of the sky during the thermovision measurements as well as for the calculation of radiative heat losses.

[1]  H. Polakowski,et al.  A method for modelling IR images of sky and clouds , 2011 .

[2]  Jonathan Tennyson,et al.  HITEMP, the high-temperature molecular spectroscopic database , 2010 .

[3]  Ryszard A. Białecki,et al.  Frictional, diathermal flow of steam in a pipeline , 1996 .

[4]  Aleksander Lisiecki,et al.  Experimental analysis of heat conditions of the laser braze welding process of copper foil absorber tube for solar collector elements , 2013 .

[5]  Tadeusz Orzechowski,et al.  Determining local values of the heat transfer coefficient on a fin surface , 2007 .

[6]  J. Bathiébo,et al.  Clear sky radiation as a function of altitude , 1992 .

[7]  Andrzej Klimpel,et al.  Numerical and experimental determination of weld pool shape during high-power diode laser welding , 2003, Laser Technology Poland.

[8]  Ziemowit Ostrowski,et al.  Absorption line black body distribution function evaluated with proper orthogonal decomposition for mixture of CO2 and H2O , 2014 .

[9]  M. Pinar Mengüç,et al.  Thermal Radiation Heat Transfer , 2020 .

[10]  Patrik Nemec,et al.  Visualization of heat transport in heat pipes using thermocamera , 2010 .

[11]  T. Kruczek,et al.  Determination of annual heat losses from heat and steam pipeline networks and economic analysis of their thermomodernisation , 2013 .

[12]  Svend Svendsen,et al.  Energy and exergy analysis of low temperature district heating network , 2012 .

[13]  Bryan A. Baum,et al.  An efficient method for computing atmospheric radiances in clear-sky and cloudy conditions , 2011 .

[14]  Cossi Norbert Awanou,et al.  Clear sky emissivity as a function of the zenith direction , 1998 .

[15]  Svend Svendsen,et al.  Method for optimal design of pipes for low-energy district heating, with focus on heat losses , 2011 .