桃胶多糖的化学研究及其应用

毛桃(Prunus persica (L.) Batsch)是我国普遍裁培的一种果树。在桃树致病或受伤处会有桃胶(Peach gum)分泌。在一般情况下，天然桃胶是很难溶于水的，因此限制了它的使用。本文首次通过碱溶后，以快速沉淀的方法来降低桃胶的局部结晶度，使得桃胶能较顺利地溶解于冷水中。并提出了由于桃胶对金属镁的强络合作用而影响了桃树的正常生长这一推测。 桃胶经碱溶纯化制得钠型胶，再用阳离子交换树脂处理得氢型胶。用不同的方法处理桃胶后，桃胶红外光谱的结构特征吸收方才显示出来。钠型胶具840Cm-1的红外吸收;氢型胶具890Cm-1、1730cm-1的红外吸收;甲基化后的桃胶具810Cm-1、870Cm-1、890Cm-1的红外吸收。桃胶的比旋光度为负值。核磁共振证明桃胶多糖中，α-和β-甙键共存。碱溶纯化的桃胶多糖经凝胶色谱和超速离心证明为单一物质。 桃胶多糖不具还原性。经气相层析和比色法分析，桃胶中D-葡萄糖醛酸(包括4-甲氧基-D-葡萄糖醛酸）、D-半乳糖、D-木糖、D-甘露糖、L-阿拉伯糖、L-鼠李糖含量分别为10%、30%、11%、1.3%、45%、2%。18C-NMR和甲基化分析，证明桃胶大分子链是高度支链化的。且阿拉伯糖和半乳糖在大分子结构中有呋喃环和吡喃环两种形式共存。桃胶按物理性状，可分为两种。它们仅仅是在分子量和水溶液中的粘度不同，分子量( Mw)为342.9万和416.9万，特性粘度(η)为0.425dl/g和0.866dl/g。但在化学成分及结构特征上是相似的。以甘油为增塑剂，能增加桃胶成膜后的柔韧性。

Controlled release of urea encapsulated by starch-g-poly(L-lactide)

This paper presented a new approach for preparing a new type of slow-release membrane-encapsulated urea fertilizer with starch-g-PLLA as biodegradable carrier materials. By solution-casting and washing rapidly with water the urea was individually encapsulated within the starch matrix modified by L-lactide through in situ graft-copolymerization.

松辽盆地南部腰英台区块低渗透储层整体压裂改造技术研究

The Yaoyingtai Block is located within the northeastern Changling Depression of southern Songliao Basin, where the reservoir sandstones are petrophysically characterized by very low permeability, which results in the low success probability of artificial fracturing, and the low oil yield by water injection in the course of oil production. In order to improve the situations as stated above, this research aims to work out an integral fracturing technology and strategy applicable to the low permeable reservoirs in Yaoyingtai Block. Under the guidance of geological theory, reservoir engineering and technology, the subsurface occurrences of natural and hydraulic fractures in the reservoirs are expected to be delineated, and appropriate fracturing fluids and proppants are to be optimized, based on the data of drilling, well logging, laboratory and field experiments, and geological data. These approaches lay the basis of the integral fracturing technology suitable for the low permeable reservoir in the study area. Based on core sample test, in-situ stress analysis of well logging, and forward and inversion stress field modeling, as well as fluid dynamic analysis, the maximum in-situ stress field is unraveled to be extended nearly along the E-W direction (clustering along N85-135°E) as is demonstrated by the E-W trending tensional fractures. Hydraulic fractures are distributed approximately along the E-W direction as well. Faulting activities could have exerted obvious influences on the distribution of fractures, which were preferentially developed along fault zones. Based on reservoir sensitivity analysis, integrated with studies on rock mechanics, in-situ stress, natural fracture distribution and production in injection-production pilot area, the influences of primary fractures on fracturing operation are analyzed, and a diagnostic technology for primary fractures during depressurization is accordingly developed. An appropriate fracturing fluid (hydroxypropyl guar gum) and a proppant (Yixing ceramsite, with a moderate-density, 0.45-0.9mm in size) applicable to Qingshankou Formation reservoir are worked out through extensive optimization analysis. The fracturing fluid can decrease the damage to the oil reservoir, and the friction in fracturing operation, improving the effect of fracturing operation. Some problems, such as sand-out at early stage and low success rate of fracturing operations, have been effectively solved, through pre-fracturing formation evaluation, “suspension plug” fracturing, real-time monitoring and limited-flow fracturing. Through analysis of fracture-bearing tight reservoir with variable densities and dynamic analysis of influences of well patterns on fracturing by using numerical simulation, a fracturing operation scheme for the Qingshankou Formation reservoir is proposed here as being better to compress the short factures, rather than to compress the long fractures during hydraulic fracturing. It is suggested to adopt the 450m×150m inverted 9-spot well pattern in a diamond shape with wells placed parallel to fractures and a half fracture length of 60-75m.