壁材

不同的壁材对辅酶Q（10）纳米脂质体包埋效果的影响

Effects of Different Wall Materials on Microencapsulation Quality of Coenzyme Q_ ( 10 ) Nanoliposomes

并初步研究了在一定条件下，利用同轴喷嘴将萃取出的花椒油直接喷雾干燥制备微胶囊过程中，壁材浓度、壁材流量、CO2流量、进风温度等对包埋率的影响。

In microcapsulation with spray drying by using coaxial nozzle , the factors affecting the degree of encapsulation , such as wall material concentration , wall material flow rate , CO2 flow rate , inlet-air temperature were also investigated .

我们用阿拉伯胶作壁材，包埋SOD。

We used Arabic gum as Wall material to imbed SOD .

用原位聚合法制备以脲醛树脂为壁材的酞菁绿G颜料微胶囊，采用了酸催化下的缩聚反应工艺。

Microcapsules of Phthalocyanine Green G with urea-formaldehyde resin wall were prepared by in-situ condensation polymerization reaction with acid catalyzer .

文中以蛋黄磷脂为主要壁材，采用乙醇注入-超声法制得稳定性较好的辅酶Q（10）纳米脂质体。

In this study , ethanol injection-sonication method was selected to prepare stable CoQ_ ( 10 ) nano - liposomes .

EPA、DHA的微胶囊化：壁材的筛选

Microencapsulations of EPA and DHA : Wall material Selection

基于此，本文采用海藻酸钠-壳聚糖为壁材，乳化-内部凝胶化法对GOD进行微胶囊化包埋，从三方面改善GOD的改良品质。

Based on this , we embedded GOD using emulsion-internal gelation method with alginate - chitosan as wall material , improving the quality of GOD from three respects .

通过DSC热分析、红外光谱分析、囊芯物磷的定性检测等测试方法表征了甲基磷酸二甲酯微胶囊的壁材与囊芯物。

The core and shell materials of DMMP microcapsules were identified by DSC , IR spectrum , phosphorous qualitative analysis .

壁材乙基纤维素微胶囊饲料在不同体系（pH、温度）的缓释性能优于壁材明胶微胶囊饲料。

The diet microencapsulated with ethyl cellulose had better performance with slow release characteristic in different solution ( pH , temperature ) compared with the diet microencapsulated with gelatin . 3 .

复合纤维素酶的加酶量2%（g酶/g纤维素），水解温度50℃，水解时间12h，pH4.5.并以全绿豆酶解产物为壁材，通过制备微胶囊技术制得全绿豆速溶饮品。

The Preparation of Instant Whole Mung Bean Beverage Using Enzyme Hydrolysis Method And using the microencapsulation technology , the instant whole mung bean beverage was made .

用甲苯2,4二异氰酸酯（TDI）为壁材原料，利用界面聚合法在不同条件下制备了一系列TiO2聚脲微胶囊。

A series of TiO 2 polyurea microcapsules were prepared at different conditions by interfacial polymerization with 2,4 toluene diisocyanate ( TDI ) as wall material precursor .

水性聚氨酯乳液可作为包覆壁材应用于NEPE推进剂中。

So latex of waterborne polyurethane can be used as cliff material to coat stuffing in NEPE propellant .

以尿素和甲醛为壁材，油性蓝和TiO2纳米粒子分散在四氯乙烯中作为囊芯，通过原位聚合法制备了蓝色电泳显示微胶囊。

Electrophoretic microcapsules were prepared via in-situ interfacial polymerization using ureaformaldehyde ( UF ) resin as the outer membrane and oil blue and TiO2 nanoparticles dispersed in tetrachloroethylene as core materials .

选择合适的材料作为壁材和稳定的微胶囊（Microcapsule，MC）制备工艺等一直是微胶囊化研究者探索的重点之一。

Choosing the suitable wall-materials and effective methods to prepare stable microcapsules ( MCs ) have been the key target to researchers in the pharmaceutical and food industries .

以尿素和甲醛为壁材，分散染料酸性红GP（C.I.266）为囊芯制备了分散染料微胶囊。

Microcapsules were prepared by the method of in situ interfacial polymerization with urea formaldehyde as the outer membrane and disperse dye C. I. 266 as core material .

采用尿素和甲醛为壁材，分散染料为囊心，采用SEM以及Zeta电位仪，观察了分析微胶囊的结构以及分散性，确定了生产微胶囊的最佳工艺条件。

The structure and the dispersibility of microcapsule are observed and analysed by SEM and the Zeta potential analyzer . The factors which affected the properties of microcapsules are also dis-cussed .

以酯型儿茶素为芯材，大豆色拉油为初级壁材，蛋白NP和碳水化合物CA、CB为壁材，经乳化剪切，喷雾干燥制得酯型儿茶素微胶囊。

Esters-catechin was used as core materials , soybean oil as primary wall materials and albumen NP and carbohydrate CA , CB as wall materials . After shearing and spray-drying the esters-catechin microcapsule was prepared .

以5wt%阿拉伯胶（GA）和麦芽糊精（MD）为壁材和稳定剂，采用超声细胞粉碎技术制备了牛初乳乳清W/O型乳状液。

W / O bovine colostrums whey emulsion was prepared with 5 wt % arabic gum ( GA ) and maltodextrin ( MD ) as wall materials and stabilizers , by the method of ultrasonic emulsification .

采用酵母浸膏-海藻酸钠-壳聚糖为壁材，以自制南海低值鱼鱼油为芯材，采用层-层（LBL）组装技术制备鱼油微胶囊产品。

The microcapsule was prepared using yeast extract-sodium alginate-chitosan as wall and self-made fish oil as core by layer-by-layer ( LBL ) assembling technique .

本论文为了解决以上存在的问题，选择微胶囊的囊芯物质为乙二胺固化剂，壁材物质为环氧树脂E51。

This paper use ethylene diamine as the core material of the microcapsule to solve this problem .

采取三步调酸法控制壁材固化反应速率，考察了乳化条件、乳化剂用量、固化反应pH值和壁材/芯材的质量比等对微胶囊性能的影响。

The three-step method is used to control the reaction rate . The effect of the conditions of emulsification , amount of emulsifier , the pH of curing reaction and mass ratio of cyst wall to core materials on the performance of the pressure-sensitive color-developing microcapsules are studied .

组份在推进剂/衬层中迁移特性的新方法探索水性聚氨酯乳液可作为包覆壁材应用于NEPE推进剂中。

A Novel Study on the Migration Property of Components in Propellant / Liner ; So latex of waterborne polyurethane can be used as cliff material to coat stuffing in NEPE propellant .

用明胶+蔗糖、明胶+桃胶+蔗糖、桃胶+蔗糖作为壁材，VA作模型心材，用喷雾干燥法制备微胶囊；

In this research , microcapsules were spray-dried , gelatin + sucrose , gelatin + peach gum + sucrose , and peach gum + sucrose were used as wall material and vitamin A was used as the model core respectively .

研究结果表明一定葡萄糖值的低粘度SSOS作为微胶囊壁材具有很好的包埋效果。

The results indicated that low viscosity of SSOS with certain dextrose equivalent would be potential wall materials for microencapsulation of lemon oil .

本论文以三聚氰胺-甲醛为壁材，正十八烷为芯材，采用原位聚合法制备相变材料微胶囊（microPCMs）。

Phase-Change Materials Microencapsule ( microPCMcs ) was prepared by in-situ polymerization using melamine-formaldehyde resin as the shell and n-Octadecane as the core .

结果表明：心材与壁材的最佳比例为12：88，最佳研磨时间30min，最适超声波时间为30min。

The results showed that the optimum ratio of heartwood to wall material was 12:88 , the optimum abrasive time was 30 min , and the best supersonic wave time was 30 min.

心材与壁材的适宜比例为12∶1；高压均质可有效地提高天然维生素E的微胶囊化效率和微胶囊化产率，其最佳均质压力为30MPa～40MPa；

The suitable proportion of core material and wall material was 1.2 ∶ 1 And high pressure homogenization can effectively increase the MEE and MEY , its suitable homogenizing pressure was 30 MPa ~ 40 MPa .

对于单一芯材（番茄红素）以较优壁材组合对微胶囊生产过程中乳化剂种类，乳化剂HLB值，均质压力，喷雾进风温度等因素进行试验，制得微胶囊包埋率72%。

For single core material ( lycopene ), based on best wall materials , the kind of emulsion , the HLB value of , homogeneity pressure and inlet temperature was studied . The microencapsulation efficiency of final products was 72 % .

以所合成的M-DDM粉体为囊芯、以2,4-甲苯二异氰酸酯（TDI）为壁材单体，采用界面聚合技术，首次成功制备了一种新型聚脲M-DDM微胶囊固化剂。

The achieved M-DDM was encapsulated to be a novel microcapsule-type latent curing agent by an interfacial polymerization process from the synthesized M-DDM as core material and tolylene diisocyanate ( TDI ) as wall monomer .

修补、填缝、不垂流壁材涂覆保护膜。

Repair , seam filling and coating film materials for wall .