MARC Record from marc_columbia

LEADER: 03996cam a2200457 i 4500
001 13555256
005 20220703224332.0
006 m o d
007 cr cnu---unuuu
008 140916s2006 enk ob 000 0 eng d
035 $a(OCoLC)ocn890656396
035 $a(NNC)13555256
040 $aKNOVL$beng$erda$epn$cKNOVL$dOCLCF$dOCLCQ$dSTF$dOCLCQ$dCEF$dRRP$dOCLCQ$dDKU$dOCLCQ$dOCLCO
020 $a9781680150193$q(electronic bk.)
020 $a1680150197$q(electronic bk.)
035 $a(OCoLC)890656396
050 4 $aTH7225
082 04 $a697$223
049 $aZCUA
245 00 $aDegree-days :$btheory and application.
264 1 $aLondon :$bChartered Institution of Building Services Engineers,$c[2006]
264 4 $c©2006
300 $a1 online resource
336 $atext$btxt$2rdacontent
337 $acomputer$bc$2rdamedia
338 $aonline resource$bcr$2rdacarrier
490 1 $aCIBSE ;$vTM41: 2006
504 $aIncludes bibliographical references.
505 00 $g1.$tAn introduction to degree-days and their uses:$tAn introduction to calculating degree-days ; Degree-days for energy estimation ; Degree-days for energy management --$g2.$tCalculating degree-days:$tMean degree-hours ; The Meteorological Office equations ; Mean daily temperature ; Hitchin's formula ; Other methods ; Errors associated with calculation methods ; Base temperature correction ; Summary --$g3.$tEnergy estimation techniques:$tHeating applications ; Intermittent heating ; Accuracy and uncertainty ; Carbon dioxide emissions ; Determination of gains ; Cooling applications ; Summary --$g4.$tWorked examples:$tHeating ; All-air cooling --$g5.$tUsing degree-days in energy management:$tNormalisation of energy performance indicators for weather ; Energy signatures ; Performance lines and degree-days ; Further diagnostics using performance lines ; Regression analysis: caveats and interpretations ; Summary. --$gAppendices:$g1.$tDegree-day errors ;$g2.$tRatios and corrections ;$g3.$tBase temperature conversion using Hitchin's formula ;$g4.$tDerivation of mean internal temperature for intermittent heating ;$g5.$tAreas of on-going work.
520 $aDegree-days are a tool that can be used in the assessment and analysis of weather related energy consumption in buildings. They have their origins in agricultural research where knowledge of variation in outdoor air temperature is important, and the concept is readily transferable to building energy. Essentially degree-days are a summation of the differences between the outdoor temperature and some reference (or base) temperature over a specified time period. A key issue in the application of degree-days is the definition of the base temperature, which, in buildings, relates to the energy balance of the building and system. This can apply to both heating and cooling systems, which leads to the dual concepts of heating and cooling degree-days. This TM replaces previous guidance given in section 18 of the 1986 edition of CIBSE Guide B [CIBSE 1986] and Fuel Efficiency Booklet 7 [Energy Efficiency Office 1993]. It provides a detailed explanation of the concepts described above, and sets out the fundamental theory upon which building related degree-days are based. It demonstrates the ways in which degree-days can be applied, and provides some of the historical backdrop to these uses. --$cProvided by publisher.
650 0 $aDegree days.
650 0 $aCommercial buildings$xEnergy consumption.
650 6 $aDegrés-jours.
650 6 $aImmeubles commerciaux$xConsommation d'énergie.
650 7 $aCommercial buildings$xEnergy consumption.$2fast$0(OCoLC)fst00869395
650 7 $aDegree days.$2fast$0(OCoLC)fst00889811
655 4 $aElectronic books.
710 2 $aChartered Institution of Building Services Engineers.
830 0 $aCIBSE ;$vTM41: 2006.
856 40 $uhttp://www.columbia.edu/cgi-bin/cul/resolve?clio13555256$zACADEMIC - Civil Engineering & Construction Materials
852 8 $blweb$hEBOOKS