1) low-E
低辐射
1.
Preparation and Properties of F-Sb Doped Tin Dioxide for Low-Emissivity Glass;
氟锑掺杂氧化锡低辐射涂层玻璃的制备与性能研究
2.
The developing course of low-e coated glasses is reviewed, the energy-saving merit and the prospect of low-e coated glass equipment are introduced and the direction of improving the domestic available off-line coating equipment is described.
回顾了低辐射镀膜玻璃的发展历程,重点介绍了low-e镀膜玻璃的节能特性及发展前景,并指出了国内现有镀膜设备的改进方向。
3.
A model of heat transfer through low-E windows is developed.
建立了低辐射能玻璃窗的物理传热模型 ,计算并分析反映窗户性能的两个参数 :传热系数U和太阳得热系数SHGC ,着重讨论了低辐射能玻璃窗的这两个参数的特点和影响因素 ,找出了其节能的机理。
2) low-E
Low-E
3) low-E
低反射率
4) Low-E glass
Low-E玻璃
1.
Influence of Low-e glass on air conditioning load and building energy consumption;
Low-e玻璃对空调负荷及建筑能耗的影响
2.
The related concept and kinds of Low-E glass were introduced and some proposals for installation of the glass were put forward.
介绍了Low-E玻璃相关的概念和常见品种,对Low—E玻璃的安装使用提出一些建议。
3.
This paper studied on the aerodynamic characteristics and velocity profile of air current in tempering furnace when Low-E glass is tempered and convective heat transfer is put into effect by air-stream introduction .
着重研究了Low-E玻璃在钢化加热炉内加入空气进行对流传热时,气流的气动特性及速度场分布情况,从而讨论了它对炉内传热所做的贡献。
5) low-e glass
低辐射玻璃
1.
The analysis of optical performance showed that the low-e glass was prepared with good thermal insulation performance.
将纳米ATO与水性聚氨酯通过一定的工艺制备出纳米隔热涂料,在常温下将之涂在玻璃表面制成低辐射玻璃。
2.
The SnO2 low-E glass prepared by spray pyrolysis have the advantages of low cost, fine bonding strength, high wearability and so on, and it holds great promise with the popularization of Low-E glass.
喷雾热解法制备的SnO2低辐射玻璃具有成本低、薄膜与基板结合度及耐磨性高等优点,随着低辐射玻璃的普及将具有非常广阔的应用前景。
6) Low-E glass
LowE玻璃
参考词条
new Low-E coating
Low-E windshield
Low-E glass
Low-E glass window
LOW-E glass
online Low-E glass
on-line Low-E glass
low-e laminated glass
Low-E glass
Low-E insulating glazing unit
heat treatable Low-E glass
本国化
欠费问题
补充资料:低能辐射
分子式:
CAS号:
性质:一般指非致电离辐射,如紫外线。这种低能辐射随环境不同可以是非致电离辐射,也可以是致电离辐射。电离不是辐射能被物质吸收的惟一形式,激发同样可以在随后产生的物理、化学、生物效应中发挥重要作用。
CAS号:
性质:一般指非致电离辐射,如紫外线。这种低能辐射随环境不同可以是非致电离辐射,也可以是致电离辐射。电离不是辐射能被物质吸收的惟一形式,激发同样可以在随后产生的物理、化学、生物效应中发挥重要作用。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。