參考書目

1.

譚亮，熊永強，李文娟 (2009)，外牆隔熱塗料的製備與節能應用，新型建築材 料，vol. 9, pp74-77.。

2.

林憲德，1995。建築及空調節能設計規範的解說與實例。詹氏書局。

3.

劉靜而，「軍用建築物外牆隔熱塗料開發研究」，國防大學化學及材料工程學系，

碩士論文，2014。

4.

徐峰，邵侯招，儲建，環保型無機塗料，化學工業出版社，北京，2004。

5.

林基裕，“隔熱建材珍珠岩表面特性及其應用潛能之研究，碩士論文，2007。

6.

3M 公司，3M 玻璃微球、陶瓷微球應用指南，3M 公司，2010。

7.

葉宏，徐文武，葉暖強，莊雙勇，“陶瓷微球填充型隔熱塗料的有效導熱係數”，

中國科學技術大學學報，第 36 卷，第 4 期，第 360-363 頁，2006。

8.

費凡，倪邦慶，佟麗華，“新型太陽熱反射塗料的組成與性能研究”，當代化工，

第 38 卷，第 3 期，第 296-302 頁，2009。

9.

孫明杰，夏楚秋，文倩倩，“太陽熱反射隔熱塗料的研製”，塗料工業，第 40 卷，第 9 期，第 37-40 頁，2010。

10.

林宣益，“建築反射隔熱塗料的標準及應用探討”，上海申得歐有限公司，2011。

11.

石玉梅，楊文願，喬亞玲，“建築反射隔熱塗料的應用現狀及存在問題分析”。

12.

張雪芹，曲生華，蘇蓉芳，徐超“建築反射隔熱塗料隔熱性能影響因素及應用技 術要點”。

13.

方 煒 ， 建 築 設 施 空 調 節 能 設 計 新 思 維 - 市 售 隔 熱 漆 產 品 遮 熱 性 能 之 再 思 考

http://www.ecaa.ntu.edu.tw/weifang/sysEng/%E9%81%AE%E7%86%B1%E6%BC%

86.htm。

14.

張育誠、吳國光、林琨程，「薄薄一層，大有學問—隔熱塗料原理及其節能評估」， 經濟部能源局--能源報導，2010 年 1 月。

15.

http://energymonthly.tier.org.tw/outdatecontent.asp?ReportIssue=201001&Page=14

16.

鍾寶堂、黃元昌、徐雅怡，「透明防污隔熱節能塗料」，工研院材料與化工研究所，

工研院電子報第 10308 期，2014。

http://edm.itri.org.tw/enews/epaper/10308/e01.htm

18.

CNS 15666 建築用長期耐候性面漆。

32.

Gregory R.Fedor 和 Patrick J. Brennan1，自然老化和螢光紫外曝曬的對比:UVA-340 燈管曝曬試驗結果。

33.

袁宏輝，孫杏蕾，張恒，氙弧燈老化與自然曝曬測試所得顏料耐候性的相關性。

34.

Akbari, H. (1998) ‘Cool roofs save energy’, ASHRAE Transactions, vol 104, no 1B, pp783–788.

35.

Akbari, H. and A. Desjarlais (2005) ‘Cooling down the house’, Professional Roofing, March,www.professionalroofing.net/article.aspx?A_ID=609.

36.

Akbari, H., S. Bretz, H. Taha, D. Kurn and J. Hanford (1997) ‘Peak power and cooling energy savings of high-albedo roofs’,Energy and Buildings, vol 25, no 2, pp117–126.

37.

Akbari, H., S. Konopacki, D. Parker, B. Wilcox, C. Eley and M. Van Geem (1998)

‘Calculations in support of SSP90.1 forreflective roofs’, ASHRAE Transactions, vol 104, no 1B, pp984–995.

38.

Akbari, H., S. Konopacki and M. Pomerantz (1999) ‘Cooling energy savings potential of reflective roofs for residential andcommercial buildings in the United States’, Energy, vol 24, pp391–407.

39.

Akbari, H., S. Konopacki and D. Parker (2000) ‘Updates on revision to ASHRAE Standard 90.2: Including roof reflectivity forresidential buildings’, in ACEEE 2000 Summer Study on Energy Efficiency in Buildings, vol 1, Pacific Grove, CA, August,American Council for an Energy Efficient Economy, Washington, DC, pp1–11.

40.

Akbari, H., M. Pomerantz and H. Taha (2001) ‘Cool surfaces and shade trees to reduce energy use and improve air quality inurban areas’, Solar Energy, vol 70, no 3, pp295–310.

41.

Akbari, H., R. Levinson and P. Berdahl (2005a) ‘Review of residential roofing materials, Part I: A review of methods forthe manufacture of residential roofing materials’, Western Roofing Insulation and Siding, January/February, pp54–57.

42.

Akbari, H., R. Levinson and P. Berdahl (2005b) ‘Review of residential roofing materials, Part II: A review of methods for themanufacture of residential roofing materials’, Western Roofing Insulation and Siding, March/April, pp52–58.

43.

Akbari, H., C. Wray, T. T. Xu and R. Levinson (2006) ‘Inclusion of solar reflectance and thermal emittance prescriptiverequirements for steep-sloped nonresidential roofs in Title 24’, http://energy.ca.gov/title24/2008standards/prerulemaking.

44.

documents/2006-05-18_workshop/2006-05-19_NONRESDNTL_STEEP-SLOPED_

COOL_ROOFS.PDF.

45.

ASHRAE (American Society of Heating, Refrigerating and Air-Conditioning Engineers) (1999) ASHRAE Standard 90.1-1999:Energy Standard for Buildings Except Low-Rise Residential Buildings, SI Edition, American Society of Heating,Refrigerating and Air-Conditioning Engineers, Atlanta, GA.

46.

ASHRAE (2001) ASHRAE Standard 90.1-2001: Energy Standard for Buildings Except Low-Rise Residential Buildings, SI Edition,American Society of Heating, Refrigerating and Air-Conditioning Engineers, Atlanta, GA.

47.

ASHRAE (2004a) ASHRAE Standard 90.1-2004: Energy Standard for Buildings Except Low-Rise Residential Buildings, SIEdition, American Society of Heating,

Air-Conditioning Engineers, Atlanta, GA.

49.

ASHRAE (2007) ASHRAE Standard 90.2-2007: Energy-Efficient Design of Low-Rise Residential Buildings, American Society ofHeating, Refrigerating and Air-Conditioning Engineers, Atlanta, GA.

50.

ASTM (American Society for Testing and Materials) (1998) ‘ASTM E 1980-98:

Standard Practice for Calculating SolarReflectance Index of Horizontal and Low-Sloped Opaque Surfaces’, in Annual Book of ASTM Standards, vol 04.12,American Society for Testing and Materials, Philadelphia, PA.

51.

BCAP (Building Codes Assistance Project) (2007) ‘Status of residential and commercial building state energy codes’,www.bcap-energy.org.

52.

Berdahl, P., H. Akbari, R. Levinson and W. A. Miller (2008) ‘Weathering of roofing materials – an overview’, Construction andBuilding Materials, vol 22, no 4, April, pp423–433.

53.

CEC (California Energy Commission) (2001) 2001 Energy Efficiency Standards for Residential and Nonresidential Buildings,P400-01-024, California Energy Commission, Sacramento, CA.

54.

CEC (2006) 2005 Building Energy Efficiency Standards for Residential and Nonresidential Buildings, CEC-400-2006-015,California Energy Commission, Sacramento, CA.

55.

Census (2007) US Census Bureau State and County Quickfacts, http://quickfacts.census.gov.

56.

Chicago (2001) ‘Amendment of Title 18 of Municipal Code of Chicago Concerning Energy Efficiency Requirements’, Journal ofthe City Council of Chicago, 6 June, p60939.

57.

Chicago (2007) City of Chicago Energy Conservation Code, Index Publishing Corporation, Chicago, IL.

58.

DOE-2 (2007) Lawrence Berkeley National Lab DOE-2 website, http://simulationresearch.lbl.gov/dirsoft/d2whatis.html

59.

Eley (2007) Pers comm with Charles Eley, Architectural Energy Corporation, 17 August.

60.

Eley Associates (2003a) Assessment of Public Policies Affecting Cool Metal Roofs, Final report prepared for the Cool MetalRoofing Coalition,

www.coolmetalroofing.org/elements/uploads/casestudies/TMI_CaseStudy_28.pdf.

61.

Eley Associates (2003b) Hawaii Commercial Building Guidelines for Energy Efficiency,www.archenergy.com/library/general/hawaiigl.

62.

Eley Associates (2007) Guam Building Energy Code, http://eley.com/guam

63.

Eilert, P. (2000) High Albedo (Cool) Roofs: Codes and Standards Enhancement (CASE) Study, Pacific Gas & Electric report,www.energy.ca.gov/title24/2001standards/associated_documents/2000-11-17_P GE_CASE.PDF.

64.

EnergyGauge (2007) EnergyGauge USA FlaRes2007 Energy and Economic Analysis Software, www.energygauge.com.

65.

EPA (US Environmental Protection Agency) (2007) Roof Products Criteria for US EPAEnergy

Starrogram,ww.energystar.gov/index.cfm?c=roof_prods.pr_crit_roof_products.

66.

FBC (Florida Building Commission) (2001) 2001 Florida Building Code, Florida Building Commission, Tallahassee, FL,www.floridabuilding.org.

67.

FBC (2004) 2004 Florida Building Code, Florida Building Commission, Tallahassee, FL, www.floridabuilding.org.

68.

FBC (2007) Proposed Modification to the Florida Building Code: Chapter 11, Energy Efficiency,www.dca.state.fl.us/FBC/thecode/Res_Chapter_11.rtf.

69.

GBC (US Green Building Council) (2001) Leadership in Energy and Environmental Design Green Building RatingSystem for New Construction and Major Renovations (LEED-NC), Version 2.0, US Green Building Council,www.usgbc.org.

70.

GBC (2002) Leadership in Energy and Environmental Design Green Building Rating System for New Construction and MajorRenovations (LEED-NC), Version 2.1, US Green Building Council, www.usgbc.org.

71.

GBC (2005) Leadership in Energy and Environmental Design Green Building Rating System for New Construction and MajorRenovations (LEED-NC), Version 2.2, US Green Building Council, www.usgbc.org.

72.

Hildebrandt, E., W. Bos and R. Moore (1998) ‘Assessing the impacts of white roofs on building energy loads’, ASHRAETechnical Data Bulletin, American Society of Heating, Refrigerating and Air-Conditioning Engineers, Atlanta, GA, vol 14,no 2,

74.

ICC (2006) 2006 International Energy Conservation Code, www.iccsafe.org.

75.

Jump, D. and M. Modera (1994) Energy Impacts of Attic Duct Retrofits in Sacramento Houses, LBL-35375, Lawrence BerkeleyNational Laboratory, Berkeley, CA.

76.

Konopacki, S. and H. Akbari (1998) Simulated Impact of Roof Surface Solar Absorptance, Attic, and Duct Insulation on Coolingand Heating Energy Use in Single-Family New Residential Buildings, LBNL-41834, Lawrence Berkeley National Laboratory,Berkeley, CA.

77.

Konopacki, S. and H. Akbari (2001) Measured Energy Savings and Demand Reduction from a Reflective Roof Membrane on aLarge Retail Store in Austin, LBNL-47149, Lawrence Berkeley National Laboratory, Berkeley, CA.

78.

Konopacki, S., L. Gartland, H. Akbari and L. Rainer (1998) Demonstration of Energy Savings of Cool Roofs, LBNL-40673,Lawrence Berkeley National Laboratory, Berkeley, CA.

79.

Levinson, R., H. Akbari, S. Konopacki and S. Bretz (2005a) ‘Inclusion of cool roofs in nonresidential Title 24 prescriptiverequirements’, Energy Policy, vol 33, no 2, pp151–170.

80.

Levinson, R., P. Berdahl and H. Akbari (2005b) ‘Solar spectral optical properties of pigments, part I: Model for derivingscattering and absorption coefficients from transmittance and reflectance measurements’, Solar Energy Materials & SolarCells, vol 89, pp319–349.

81.

Levinson, R., P. Berdahl and H. Akbari (2005c) ‘Solar spectral optical properties of pigments, part II: Survey of commoncolorants’, Solar Energy Materials & Solar Cells, vol 89, pp351–389.

82.

Levinson, R., P. Berdahl, A. A. Berhe and H. Akbari (2005d) ‘Effects of soiling and cleaning on the reflectance and solar heatgain of a light-colored roofing membrane’, Atmospheric Environment, vol 39, pp7807–7824.

83.

Levinson, R., P. Berdahl, H. Abkari, W. Miller, I. Joedicke, J. Reilly, Y. Suzuki and M.

Vondran (2007) ‘Methods of creating solarreflectivenonwhite surfaces and their application to residential roofing materials’, Solar Energy Materials & Solar Cells,vol 91, pp304–314.

84.

MCC (Maui County Code) (2004) A Bill for an Ordinance Amending Title 16, Maui

County Code, Pertaining to Energy EfficiencyStandards for Buildings, www.co.maui.hi.us/files/ordinance/LF-Ord3240_etkoujogl.pdf

85.

MICROPAS (2007) MICROPAS product website, http://micropas.com.

86.

Parker, D. (2005) Technical Support for Development of an Attic Simulation Model for the California Energy Commission, FloridaSolar Energy Center report FSEC-CR-1526-05, www.fsec.ucf.edu/en/publications/pdf/FSEC-CR-1526-05.pdf

87.

Parker, D. (2007) Pers comm from Danny Parker, Florida Solar Energy Center, 13 August.

88.

Parker, D., J. Huang, S. Konopacki, L. Gartland, J. Sherwin, and L. Gu (1998a)

‘Measured and simulated performance ofreflective roofing systems in residential buildings’, ASHRAE Transactions, vol 104, no 1, Atlanta, GA.

89.

Parker, D., J. Sherwin and J. Sonne (1998b) ‘Measured performance of a reflective roofing system in a Florida commercialbuilding’, ASHRAE Technical Data Bulletin, American Society of Heating, Refrigerating and Air-Conditioning Engineers,Atlanta, GA, vol 14, no 2, pp7–12.

90.

PG&E (Pacific Gas & Electric) (2007) Pacific Gas & Electric Cool-Roof Rebate Program, www.pge.com/myhome/saveenergymoney/rebates/remodeling/coolroof

91.

ROH (Revised Ordinances of Honolulu) (2001) Revised Ordinances of Honolulu, City and County of Honolulu.

92.

ROH (2004) Revised Ordinances of Honolulu, City and County of Honolulu.

93.

ROH (2007) Revised Ordinances of Honolulu, www.honolulu.gov/refs/roh.

94.

SCE (Southern California Edison) (2007) Southern California Edison Cool-Roof RebateProgram,www.sce.com/RebatesandSavings/Residential/_Heating+and+

Cooling/CoolRoof.

95.

SMUD (Sacramento Municipal Utility District) (2007) Sacramento Municipal Utility District Residential Cool-Roof Program,www.smud.org/rebates/cool%20roofs.

96.

Swami, M. (2007) Pers comm from Muthusamy Swami, Florida Solar Energy Commission, Developer of FLA/COMperformance compliance software, 14 June.

97.

Taha, H. (2001) Potential Impacts of Climate Change on Tropospheric Ozone in California: A Preliminary Episodic ModelingAssessment of the Los Angeles Basin and the Sacramento Valley, LBNL-46695, Lawrence Berkeley National

99.

Wray, C., H. Akbari, T. T. Xu and R. Levinson (2006) Inclusion of Solar Reflectance and Thermal Emittance PrescriptiveRequirements for Residential Roofs in Title 24, www.energy.ca.gov/title24/2008standards/prerulemaking/documents/2006-05-18_wor kshop/2006-05-17_RESIDENTIAL_ROOFS.PDF.

100.

Zhongyi, Z., James, M., Hom, N. D., Jovana, R., Constandinos, H., Miltiadis, T.and Nick, B., “Enhanced Water Rellence and Thermal Insulation of Masonry byZinc Oxide Treatment,” Energy and Buildings,Vol.54, pp.40-46,2012.

101.

Paul Berdahl,n, Hashem Akbari, Ronnen Levinson, Jeffry Jacobs, Frank Klink, Rebecca Everman Three-year weathering tests on asphalt shingles: Solar reflectance.

102.

Mohamad Sleiman, Thomas W. Kirchstetter, Paul Berdahl , Haley E. Gilbert Sarah Quelen, Lea Marlot, Chelsea V. Preble, Sharon Chen, Amandine Montalbano,Olivier Rosseler, Hashem Akbari, Ronnen Levinson, Hugo Destaillats,nSoiling of building envelope surfaces and its effect on solar reflectance – Part II: Development of an accelerated aging method for roofing materials.

103.

ASTM G155 Standard Practice for Operating Xenon Arc Light Apparatus for Exposure of Non-Metallic Materials.

104.

ASTM D6695 Standard Practice for Xenon-Arc Exposures of Paint and Related Coatings.

105.

ASTM G154 Standard Practice for Operating Fluorescent Ultraviolet (UV) Lamp Apparatus for Exposure of Nonmetallic Materials.

106.

ASTM G7 Standard Practice for Atmospheric Environmental Exposure Testing of Nonmetallic Materials.

107.

ASTM E1980 Standard Practice for Calculating Solar Reflectance Index of Horizontal and Low-Sloped Opaque Surfaces.

108.

ASTM G151 Standard Practice for Exposing Nonmetallic Materials in Accelerated Test Devices that Use Laboratory Light Sources.

109.

ASTM C1371 Standard Test Method for Determination of Emittance of Materials Near Room Temperature Using Portable Emissometers.

110.

ASTM E408 – 13 Standard Test Methods for Total Normal Emittance of Surfaces Using Inspection-Meter Techniques.

111.

ASTM C1549 Standard Test Method for Determination of Solar Reflectance Near Ambient Temperature Using a Portable Solar Reflectometer.

112.

ASTM E903 Standard Test Method for Solar Absorptance, Reflectance, and Transmittance of Materials Using Integrating Spheres.

113.

ISO 11341:2004 Paints and varnishes -- Artificial weathering and exposure to artificial radiation -- Exposure to filtered xenon-arc radiation.

114.

ISO 4892-2:1994 Plastics -- Methods of exposure to laboratory light sources -- Part 2:

Xenon-arc sources.

115.

ISO 10292:1994 Glass in building -- Calculation of steady-state U values (thermal transmittance) of multiple glazing.

116.

ISO 9050:2003 Glass in building -- Determination of light transmittance, solar direct transmittance, total solar energy transmittance, ultraviolet transmittance and related glazing factors.

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