发泡剂

Basing on thermo-simulation in laboratory, experimental study was accomplished to analyze the function mechanism of foaming agent and the foaming influence of its decompound production. The results indicated: function of foaming agents was due to their decompound and inter-reaction at high temperature. And some decompound production of foaming agent can reinforce the foaming ability of refining slag.

采用实验室模拟的方法，针对钢包精炼炉常用发泡剂的作用机理以及发泡剂高温分解产物对熔渣泡沫化性能的影响进行了研究，结果表明：发泡剂的作用主要来源于其组成物质的高温分解以及相互反应；发泡剂分解后部分产物作为高熔点粒子存在于熔渣中，提高了精炼渣的泡沫化性能。

The developing principle of MB gypsum fine foamer which takes compound honey-locust abietic acid anionic surfactant as principal composition,is analyzed in theory.

从理论上分析了以复合型皂角松香酸类阴离子表面活性剂为主要成分的MB石膏微发泡剂的研制原理，详细研究了MB微发泡剂在石膏料浆中的起泡条件、起泡性能及其对硬化后的建筑石膏物理力学性能的影响，MB微发泡剂与现有发泡剂的性能比较，MB微发泡剂在纸面石膏板中的应

The influence of high temperature and high pressure on foaming agent's properties in opened and closed system, and influence of the change of foaming agent's properties on foaming capacity and foam stabilizing capacity are also studied. The multiple regression theory is used to establish the quantitative characteristic functions of foaming agent versus temperature and pressure. Based on the Gibbs Principle, the quantitative characterization is carried out on relation of foam system's free energy versus its surface tension, surface area and concentration, and the analysis of energy concluded that the disintegration of the foam is inconvertible. At the same time, the influence of change of foam's shape and structure on distribution of reservoir temperature and pressure is qualitatively described, and the coupling mechanism between temperature field, pressure field and chemical field is systematically expounded.

同时，研究了不封闭体系、封闭体系下高温、高压对发泡剂性质的影响，以及发泡剂性质的改变对其发泡性能、稳泡性能的影响；采用泡沫实验的相关结果，运用多元回归理论，建立温度、压力与发泡剂浓度的定量表征函数；基于Gibbs原理，对高温、高压下泡沫体系的自由能与其表面张力、体系中液体的表面积以及浓度关系进行定量化的表征研究，从能量的角度得出了泡沫衰变过程具有不可逆性；同时定性地描述了泡沫形态、结构的变化对油藏温度和压力分布的影响，系统地阐述了温度场、压力场、化学场间的耦合作用机理。

With azodicarbamide as blowing agent and nano-CaCO3 as nucleator, the cell morphologies of non-crosslinked and corsslinked polypropylene foams were studied. The effects of different contents of crosslinking agent on the flexural strength and non-notched impact strength of PP foamed compound were also studied.

以活性纳米碳酸钙为成核剂，偶氮二甲酰胶为发泡剂，研究了未交联和交联聚丙烯发泡的泡孔结构，同时还研究了不同的交联剂含量对聚丙烯发泡制品弯曲强度和无缺口冲击强度的影响。

Effects of foaming agent、vulcanizer and the match of the two on the compress stress relaxation of the silicone rubber foam were studied.

研究了发泡剂用量以及发泡剂与硫化剂之间的匹配等对硅橡胶泡沫材料压缩应力松弛的影响。

The effect of additive is investgated by measuring solution loss, foam multiple, the quotiety of water retention, and the causation also are discussed.

通过测量发泡剂携液量、发泡倍数、保水系数的变化规律表征外加剂对发泡剂泡沫性能的影响，并对产生影响的原因进行了解释。

The cell structure refining mechanism shows that adding Mg decreases the surface tension of the aluminum alloy melt and hence to increase the bubble stabilization. Adding nuclear forming agent increases the nuclei of heterogeneous nucleation. Adding pre-heating foaming agent postpones its decomposition, hence to increase the uniform of foaming agent dispersion. Stirring within the middle stage of foaming agent rapid decomposition breaks up big bobbles to fine bobbles, hence to reduce mean cell diameter.

孔径细化机理分析表明，Mg的作用在于降低铝熔体的表面张力，提高气泡稳定性；形核剂的作用在于增加气泡非均匀形核的核心；发泡剂氧化预处理可以推迟和延缓发泡剂的分解，提高发泡剂的分散均匀性；搅拌发泡的作用是在发泡剂剧烈分解的中段，通过搅拌搅碎气泡，减小平均孔径。

Bubbling temperature direct affect the diameter and the distribution of bubbles; Bubblier is a main factor which influence the bubble structure of foam glass. To select different bubblier results in different craft. To add stabilizer directs affect the melt viscosity, besides superficial expansion.

在泡沫玻璃烧结过程中，发泡温度(760～950℃)影响泡径及气泡的分布状态；发泡剂是影响泡沫玻璃制品泡孔结构的主要因素，发泡剂不同，发泡时间不同，则气泡的泡径和开闭口的情况就不同；在泡沫玻璃烧结过程中，稳泡剂的加入直接影响粘度，粘度过高气泡不易产生，粘度过低气泡极易逸出，两者都不利于产生所要求数量的气泡；另外，表面张力和配料中的水对发泡也有一定的影响。

In the paper the main topics are:(1) to analyze the chemistry composition, the X-ray diffraction, the DTA, and the functions of all raw materials;(2) to define the best direction for producing glass and foam glass, and the best burning technical process;(3) to characterize the unit weight and thermal conductivity of foam glass;(4) to analyze the reason of bubbling up, including the influence factor of temperature, time and so on;(5) to discuss the reasons of leading to shortcomings.There is high content quartz (SiO2) in the two gangues from gold mine and potassium feldspar mine respectively. They can be used to prepare glass, because the quartz (SiO2) is the main raw material.

论文的主要内容包括：1、对矿山尾矿的湿化学分析，粒度、X射线衍射和热稳定性的分析，以及硼砂、碳酸钙及制备泡沫玻璃的玻璃粉、磷酸钠实验原料在实验中的作用进行分析；2、确定尾矿烧结成玻璃体和利用玻璃体烧结泡沫玻璃的最佳配方以及两次烧结的最佳烧成工艺条件；3、泡沫玻璃制品的体积密度和导热系数等物理性能的测定；4、泡沫玻璃的发泡机理分析，包括发泡温度、发泡时间、发泡剂的用量、稳定剂的用量及其它因素对发泡作用的影响；5、讨论造成泡沫玻璃成品各种缺陷的原因及其解决方法。

In this study, Cryptomeria japonica was liquefied in phenol with H2SO4 and HCl as a catalyst. The epoxy resin was synthesized from epichlorohydrin and bisphenol A with the molar ratio of 5/1. Blending resins were prepared by mixing the liquefied Japanese cedar and epoxy resin with weight ratios of 30/100, 50/100 and 70/100, and the triethylene tetramine was added as a cross-linking hardener. The effect of mixing ratios of liquefied Japanese cedar to epoxy resin and amount of hardener added on the reactivity of blending resins and the properties of cured resins were investigated. Furthermore, polysiloxane and rice husk were added as foaming agent and filler, respectively, to the epoxy resin and blending resins. The foaming process, the bubbles shape, the mechanical properties, and the thermal stability of the epoxy foams were investigated.

中文摘要本研究将柳杉(Cryptomeria japonica； Japanese cedar)木材以酚为溶剂，H2SO4及HCl为催化剂进行液化处理，另以莫耳比5/1之环氧氯丙烷与双酚A反应合成环氧树脂，并将液化柳杉与环氧树脂以重量比30/100、50/100及70/100混合制备掺合树脂，并以三乙基四胺(Triethylene tetramine； TETA)为架桥硬化剂，探讨液化柳杉与环氧树脂混合比及硬化剂添加量对其掺合树脂之反应性，及其硬化树脂性质之影响；进一步於环氧树脂与掺合树脂中添加聚矽氧烷为发泡剂，稻壳粉为填料制备发泡体，探讨其发泡体之发泡过程、泡体形态、发泡体机械性质与热稳定性。

foaming agent：发泡剂

目前在国内使用于地暖工程的轻量气泡混凝土是通过把发泡剂(Foaming Agent)和高压空气,水等注入到发泡机里形成气泡,然后再把气泡与水泥泥浆混合的方法而形成的,还可添加沙子、笨板粒子,发泡合成树脂块...与角质层的脂质作用,

Lauryl Betaine：烷基甜菜硷 界面活性剂,强力发泡剂

Lanolin Alcohol 含水羊毛脂 乳化剂. | Lauryl Betaine 烷基甜菜硷 界面活性剂,强力发泡剂. | Lauryl Diethanolamide 烷醇眉胺 界面活性剂,发泡及增稠剂.

blowing agent：发泡剂

吸热剂(Endothermic)(发泡剂)(blowing agent) (发泡剂) 吸热剂 发泡剂的化学作用导致它生成气体的同时会吸收热量, 通常使用的吸热发泡剂是碳酸氢钠和 柠檬酸的混合物.

blowing agent：发泡剂;生气剂;起泡剂

blowing activator 发泡活性剂 | blowing agent 发泡剂;生气剂;起泡剂 | blowing down 吹除

CBA：化学发泡剂

、化学发泡剂(CBA)行业下游介绍二、化学发泡剂(CBA)行业下游发展状况分析三、化学发泡剂(CBA)行业下游对化学发泡剂(CBA)行业影响力分析第十二章 化学发泡剂(CBA)重点企业发展分析第十三章 化学发泡剂(CBA)行业投资策略分析第

effervescence mixture：发泡剂

发泡 effervescence | 发泡剂 effervescence mixture | 必v,效率 efficiency

foamer：起泡剂;发泡剂

foamedplastics泡沫塑料 | foamer起泡剂;发泡剂 | foamingagent起泡剂;发泡剂

frothing agent：发泡剂,起沫,起泡剂

frothing | 发泡,起沫 | frothing agent | 发泡剂,起沫,起泡剂 | frothing machine | 发泡机,起沫机

AZDNazo-isobutyric dinitrile：偶氮异丁二腈[发泡剂]

AZBNazo-isobutyronitrile 偶氮异丁腈[发泡剂] | AZDNazo-isobutyric dinitrile 偶氮异丁二腈[发泡剂] | boils at...;boiling at... 在......温度下沸腾

frother：发泡剂

froth, 泡,泡沫,废物 | frother, 发泡剂 | frothy,发泡的,起泡沫的,多泡沫的