地采暖用木质地板导热性能影响因素及提升方法
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摘要
地采暖用木质地板由木质基材和发热源组成,影响其导热性能的因素主要为木质基材、胶黏剂与地板结构等。为了提升地采暖地板导热性能,有研究对木质基材、胶黏剂添加导热填料,或在木材单板上化学镀铜。笔者以石墨烯为导热填料,配制浸渍改性剂,对速生杨木单板进行真空浸渍,结果表明石墨烯能够有效提高木材导热系数。以此石墨烯复合导热木材作为地板基材,不仅可以缩短传热时间,还能够节约能耗,是促进产业升级、提升产品附加价值,避免同质化竞争的重要手段。
The wooden heating floor is composed of wooden substrate and heating source, and the factors affecting its thermal conductivity are mainly wood substrate, adhesive and floor structure. In order to improve the thermal conductivity of wooden heating floor, it is studied to add conductive filler to the wood substrate or the adhesive, or to electrolessly plate copper on the wood veneer. This paper uses graphene as a conductive filler to compound impregnation agents, and vacuum impregnates the fast-growing poplar veneer. The result shows that graphene can effectively improve the thermal conductivity of wood. The use of wood graphene composite as a floor substrate not only shortens the heat transfer time but also saves energy, and is an important means for promoting floor industrial upgrading, enhancing product added value,and avoiding homogenization competition.
The wooden heating floor is composed of wooden substrate and heating source, and the factors affecting its thermal conductivity are mainly wood substrate, adhesive and floor structure. In order to improve the thermal conductivity of wooden heating floor, it is studied to add conductive filler to the wood substrate or the adhesive, or to electrolessly plate copper on the wood veneer. This paper uses graphene as a conductive filler to compound impregnation agents, and vacuum impregnates the fast-growing poplar veneer. The result shows that graphene can effectively improve the thermal conductivity of wood. The use of wood graphene composite as a floor substrate not only shortens the heat transfer time but also saves energy, and is an important means for promoting floor industrial upgrading, enhancing product added value,and avoiding homogenization competition.
引文
[1]徐伟,陶鑫,吴智慧,等.木质地板用地采暖方式[J].木材工业,2017,31(3):35-39.
[2]胡亚才,范利武,俞自涛,等.木材微结构对其传热特性影响的实验研究[J].工程热物理学报,2005,26(S1):210-212.
[3]郭洪武,李黎.木地板的加工、铺装与环境设计[M].北京:中国水利水电出版社,2013:112-113.
[4]黄成建,包永洁,李能,等.不同胶黏剂竹木复合电热地板的基本特性[J].浙江农林大学学报,2017,34(2):369-373.
[5]叶红,代平国,任彦回.地暖环境条件下木地板甲醛释放量测定及收集装置[J].福建分析测试,2012,18(6):25-26.
[6]叶春香,崔启鹏,吴玉琪,等.地采暖用实木复合地板甲醛释放变化规律[J].林业与环境科学,2016,32(2):31-33.
[7]杨奠基.无甲醛胶粘剂发展现状及其在地热地板上的应用[J].国际木业,2016,20(9):6-10.
[8]SEO J,JEON J,LEE J H,et al.Thermal performance analysis according to wood flooring structure for energy conservation in radiant floor heating systems[J].Energy&Buildings,2011,43(8):2039-2042.
[9]何毅,熊国兵,叶小青,等.多层复合实木地板的热传导性能和尺寸稳定性[J].南京林业大学学报(自然科学版),2006,30(4):43-46.
[10]CHEN Q,GUO X,Ji F,et al.Effects of Decorative Veneer and Structure on the Thermal Conductivity of Engineered Wood Flooring[J].Bioresources,2015,10(2):2213-2222.
[11]张桂兰,张振涛,仇洪波,等.木质导热材料的导热性能及强化导热机理研究[J].林产工业,2017,44(10):12-15.
[12]仇洪波.导热木质复合材料制备工艺及性能研究[D].呼和浩特:内蒙古农业大学,2015.
[13]刘明利,李春风,刘彦龙,等.氧化铝添加量对地采暖强化木地板基材性能的影响[J].木材工业,2014,28(6):42-44.
[14]商俊博.木质电磁屏蔽材料的化学镀制备工艺研究[D].北京:北京林业大学,2009.
[15]秦静,陈丽杰,沈德君.电热式化学镀铜地热地板的表面化学结构与导热性[J].北华大学学报(自然科学版),2017,18(2):277-280.
[16]秦静.化学镀铜杨木单板多层复合材料的物性与力学松弛[D].北京:北京林业大学,2015.
[17]符远翔,姚汉伟,吕树申.填料导热胶粘剂的性能研究[J].工程热物理学报,2012,33(12):2137-2139.
[18]NOVAK I,KRUPAI.Electro-conductive resins filled with graphite for casting applications[J].European Polymer Journal,2004,40(7):1417-1422.
[19]SEO J,CHA J,KIM S.Enhancement of the thermal conductivity of adhesives for wood flooring using x Gn P[J].Energy&Buildings,2012,51(1-2):153-156.
[20]SEO J,CHA J,KIM S,et al.Development of the thermal performance of wood-flooring by improving the thermal conductivity of plywood[J].Journal of Biobased Materials&Bioenergy,2014,8(2):170-174.
[21]徐伟,陶鑫,吴智慧,等.家具用速生杨木改性材研究进展及方向[J].家具,2017(4):8-11.
[2]胡亚才,范利武,俞自涛,等.木材微结构对其传热特性影响的实验研究[J].工程热物理学报,2005,26(S1):210-212.
[3]郭洪武,李黎.木地板的加工、铺装与环境设计[M].北京:中国水利水电出版社,2013:112-113.
[4]黄成建,包永洁,李能,等.不同胶黏剂竹木复合电热地板的基本特性[J].浙江农林大学学报,2017,34(2):369-373.
[5]叶红,代平国,任彦回.地暖环境条件下木地板甲醛释放量测定及收集装置[J].福建分析测试,2012,18(6):25-26.
[6]叶春香,崔启鹏,吴玉琪,等.地采暖用实木复合地板甲醛释放变化规律[J].林业与环境科学,2016,32(2):31-33.
[7]杨奠基.无甲醛胶粘剂发展现状及其在地热地板上的应用[J].国际木业,2016,20(9):6-10.
[8]SEO J,JEON J,LEE J H,et al.Thermal performance analysis according to wood flooring structure for energy conservation in radiant floor heating systems[J].Energy&Buildings,2011,43(8):2039-2042.
[9]何毅,熊国兵,叶小青,等.多层复合实木地板的热传导性能和尺寸稳定性[J].南京林业大学学报(自然科学版),2006,30(4):43-46.
[10]CHEN Q,GUO X,Ji F,et al.Effects of Decorative Veneer and Structure on the Thermal Conductivity of Engineered Wood Flooring[J].Bioresources,2015,10(2):2213-2222.
[11]张桂兰,张振涛,仇洪波,等.木质导热材料的导热性能及强化导热机理研究[J].林产工业,2017,44(10):12-15.
[12]仇洪波.导热木质复合材料制备工艺及性能研究[D].呼和浩特:内蒙古农业大学,2015.
[13]刘明利,李春风,刘彦龙,等.氧化铝添加量对地采暖强化木地板基材性能的影响[J].木材工业,2014,28(6):42-44.
[14]商俊博.木质电磁屏蔽材料的化学镀制备工艺研究[D].北京:北京林业大学,2009.
[15]秦静,陈丽杰,沈德君.电热式化学镀铜地热地板的表面化学结构与导热性[J].北华大学学报(自然科学版),2017,18(2):277-280.
[16]秦静.化学镀铜杨木单板多层复合材料的物性与力学松弛[D].北京:北京林业大学,2015.
[17]符远翔,姚汉伟,吕树申.填料导热胶粘剂的性能研究[J].工程热物理学报,2012,33(12):2137-2139.
[18]NOVAK I,KRUPAI.Electro-conductive resins filled with graphite for casting applications[J].European Polymer Journal,2004,40(7):1417-1422.
[19]SEO J,CHA J,KIM S.Enhancement of the thermal conductivity of adhesives for wood flooring using x Gn P[J].Energy&Buildings,2012,51(1-2):153-156.
[20]SEO J,CHA J,KIM S,et al.Development of the thermal performance of wood-flooring by improving the thermal conductivity of plywood[J].Journal of Biobased Materials&Bioenergy,2014,8(2):170-174.
[21]徐伟,陶鑫,吴智慧,等.家具用速生杨木改性材研究进展及方向[J].家具,2017(4):8-11.
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