Research on testing method of resin sand high temperature compressive strength

High temperature compressive strength is one of the most important performances of resin sand; its value directly concerns the quality of castings. In order to seek the best testing method of resin sand high temperature compressive strength, a self-developed instrument was used to carry out experiments, and the sample shape and size were designed and studied. The results show that a hollow cylinder sample can reflect the strength difference of different resin sands better than a solid cylinder sample, and its data is stable. The experiments selected φ20/5×30 mm as the size of the hollow cylinder samples. The high temperature compressive strengths of phenol-formaldehyde resin coated sand, furan resin self-setting sand, and TEA resin sand were each tested. For the resin sand used for cast steel and cast iron, 1,000 ℃ was selected as the test temperature; for the resin sand used for cast non-ferrous alloy, 800 ℃ was selected as the test temperature; and for all the resin sand samples, 1 min was selected as the holding time. This testing method can truthfully reflect the high temperature performance of three kinds of resin sand; it is reproducible, and the variation coefficients of test values are under 10%.

Influence of resin flow on shrinkage of additive manufacturing coated sand molds

Coated sands are used extensively for additive manufacturing sand molds in the metal casting process, and the packing structure changes caused by the resin flow promote the shrinkage and deformation of the part. During the coated sand heating, the resin on the surface flowing to the contact points of the particles forms the resin neck and causes particles to pack close to each other. In this work, the diameters of the coated ceramsite sand before and after heating were measured based on in-situ experimental observations with image measuring apparatus and blue laser, to obtain the relationship between resin coating thickness and the particle diameter. The particle packing model was established to describe the particles＇ achievement of a stable state one by one. A re-packing simulation was then performed after reducing the particle diameter according to the resin coating thickness, to obtain the shrinkage ratios at different particle size distributions. It was found that the resin coating thickness increased from 0.8 to 2.3 IJm as the particle diameter increased from 107 to 500 IJm, for the coated ceramsite sand with the resin content of 2wt.%; the shrinkage ratio decreased first and then increased as the particle diameter increased. The experimental minimum shrinkage ratio was 3.28%, and the corresponding particle diameter was 300-375 IJm, while the minimum shrinkage ratio obtained by simulation was 3.43%, and the corresponding particle diameter was 214-300 IJm. After mixing the five groups proportionally, the shrinkage ratios of the simulation and experiment dropped to 2.81% and 3.04%, respectively, indicating the best results.

Effects of interface adhesive and resin cohesive strength on tensile strength of resin sand based on numerical analysis

A plane-strain unit-cell finite element model was proposed to study the effects of resin/sand interface adhesive and resin cohesive strength on the overall tensile strength of resin sand,as well as the fracture modes.The main micro-scale characteristics of the numerical model were extracted from the micrograph of resin sand specimens by three-dimensional X-ray microscopy(3 D-XRM).The extended finite element method(XFEM)and cohesive behavior method were employed to explicitly describe the resin fracture and sand/resin interface debonding,separately.The corresponding experimental observation of micro-scale failure behavior based on the scanning electron microscopy(SEM)was presented for a comparison.The numerical results show that the initial failure of the model occurs at the sand/resin interface,followed by consequent resin failure.Dependent on the resin cohesive strength,the location of resin failure varies from the central zones to resin neck arc zones.A typical mixed mode fracture is observed,which is consistent with the corresponding micro-scale experimental observation.When the resin cohesive strength ranges between 8 and 12 MPa,the resin cracks occur at the central zone of resin bridges and propagate perpendicularly to the tensile direction until through cracks happen.At a higher range(between 12 and 16 MPa),interface cracks cross with resin cracks,bonding bridges of resin sand are broken.The interface adhesive strength has a more significant effect on the overall tensile strength of resin sand than the resin cohesive strength.The overall tensile strength of resin sand increases first then keeps stable with the increase of the resin cohesive strength.This work attempts to establish a numerical model which accurately describes the complicated mixed mode fracture of resin sand,which is beneficial to understand deeply the fracture mechanism of resin sand.

Development of a new instrument for measurement of high temperature mechanical properties of resin-bonded sand

The mechanical properties of resin-bonded sand mixtures at high temperatures significantly affect the quality of casting. However, the existing instruments for high-temperature performances testing mainly focus on inorganic binder-bonded sands no matter the test items or the atmospheric protection, while the instrumentss specially designed for resin-bonded sand are not yet available. A new instrument for testing the hightemperature performance of resin sand was designed including the confirmation of the testing parameters, loading, measurement and control systems, and the design of the frame shape and heating furnace. This instrument can test the compressive strength, heat tolerance time and restraining load of phenol-formaldehyde resin coated sand, self-hardened furan resin sand, and trimethylamine(TEA)-based resin bonded sand at high temperatures. The developed instrument has a high accuracy offering smaller than 0.3% deviation at a full scale in the measurement of the high temperature compressive strength and the restraining load over the range of 0-6.8 MPa and 0-2,000 N, respectively. The high temperature heat tolerance time range is 0-300 s and its measurement accuracy is ±1 s.

耐高温泡沫树脂低伤害均匀固砂技术

针对常规泡沫树脂体系耐温性较差和辽河油田疏松砂岩稠油油藏化学固砂储层伤害大与有效期短的问题,以环氧树脂、酚醛树脂、疏水纳米SiO_(2)、硅烷偶联剂等为原料制得纳米改性树脂基液,然后加入固化剂、乳化剂、起泡剂、稳泡剂等添加剂制得泡沫树脂固砂体系。评价了该体系的固化温度、固砂强度、渗透性能、耐温性能和非均质多层注入性能;研发了配套的泡沫发生器,形成了耐高温泡沫树脂低伤害均匀固砂技术,并在辽河油田进行了现场应用。结果表明,泡沫树脂固砂体系的最优配方为:20%~30%树脂基液+8%~12%酚醛胺类固化剂+0.3%乳化剂OP-10+0.5%起泡剂有机硅表面活性剂+0.1%固体稳泡剂纳米SiO_(2)+0.1%聚合物稳泡剂聚乙二醇+57%~71%清水。该体系的起泡体积约为发泡前的7倍、半衰期大于20 min,可在35℃以上固化,固化后耐温可达280℃,既具有低温固化的特点,又具有耐高温的特点。在不同温度下固化的泡沫树脂固结岩心的抗压强度达到5 MPa以上,固砂强度高,满足疏松砂岩固砂强度的要求。对用0.25~0.42 mm石英砂制得的固结岩心的固砂渗透率达到4.8μm2,优于常规树脂固砂剂(1.9μm~2)。在非均质多油层中可明显防止高渗透层突进,改善固砂剂注入剖面,实现均匀固砂。现场试验取得良好的防砂效果,验证了该技术可实现均匀固砂和低伤害特性。利用泡沫树脂流体特性实现非均质多油层均匀固砂,达到了提高化学固砂效果和防砂有效期的目的。

铸造混合型旧砂的复合再生工艺研究

对含不同类型树脂芯砂的粘土混合旧砂进行再生试验研究,对比了湿法再生、化学再生和复合再生等对再生砂表面形貌和性能的影响。结果表明:单一再生方法无法同时满足对含泥量、灼减量、酸耗值等要求。“水洗+碱/酸处理+高温焙烧”工艺能充分发挥不同工艺优势,获得理想结果,适宜的工艺参数为在400 r/min的转速下水洗6次,每次5 min,砂水比约为1.7∶1,并在水洗初期和水洗后每100 g旧砂依次加入0.1 mol/L的氢氧化钠溶液4 mL和草酸溶液6 mL,最后将水洗后的砂子在700℃焙烧15 min。再生砂含泥量、酸耗值、灼减量分别达到0.18%,2.61 mL和0.08%,均超过行业标准和企业生产要求。

低伤害固砂用乳液树脂的制备与评价

采用固化剂乳化法,以缩水甘油醚环氧树脂和香兰素/六亚甲基-1,6-二胺/丙烯酰胺三元聚合物固化剂为主体,加入一定量的偶联剂KH-550和控制剂氢氧化钠,制备了一种低伤害固砂用树脂体系。考察了树脂、固化剂、偶联剂、控制剂用量对该体系固砂效果的影响。结果表明,优选配方组成为m(树脂)∶m(固化剂)∶m(偶联剂)∶m(控制剂)∶m(水)=10∶12.5∶1∶2.5∶74。该体系在室温25℃条件下,静置24 h未固化且黏度保持在6 mPa·s;在80℃恒温水浴下固化72 h,固结体的抗压强度可达到5.8 MPa,渗透率保留率可达85%以上。

S16R机体裂纹的分析及预防

针对S16R机体铸件裂纹问题进行铸造应力、金相和电镜分析。应力场数值模拟结果表明,铸件结构合理,不会产生裂纹缺陷。金相和电镜分析后发现裂纹处存在E型石墨和严重的氧化物。通过控制砂芯强度为1.0~1.2 MPa,熔炼时增加1%碳化硅预处理剂,提高铸件碳含量0.05%和增加0.1%硅锆随流孕育等措施,消除了铸件裂纹缺陷。

选区激光烧结技术在复杂流道砂芯中的应用

介绍了选区激光烧结技术生产复杂流道砂芯的整套工艺流程,通过合适的选区激光烧结砂芯结构设计、成形制造工艺及覆膜砂原材料的选择,制造出了结构复杂的整体流道砂芯。原材料采用抗拉强度更高的覆膜宝珠砂、合理的砂芯定位支撑面和砂芯排气通道等措施,更能满足复杂薄壁流道砂芯的实际铸造需求,通过实际生产验证,利用选区激光烧结技术整体制造了复杂流道砂芯,生产的铸件尺寸精度达到CT8级,采用100/200目的覆膜砂原材料,流道表面粗糙度可达Ra 6.9~10μm。

不同添加剂配比对镁合金砂型铸造用树脂砂性能的影响研究

针对镁合金砂型铸造中使用的树脂砂,探讨了混砂时加入树脂、固化剂、阻燃剂、硅烷等添加剂的配方及作用。通过测定树脂砂的可使用时间、起模时间、抗压强度等参数,分析了不同添加剂配比对树脂砂性能的影响。研究结果表明,在确保树脂砂强度的基础上,尽量减少树脂和固化剂的配比量,可减少铸件气孔缺陷,改善高温性能,提高铸件质量,降低生产成本。该研究结果可为镁合金铸件的高质量生产提供技术支持。

新型改性酚醛树脂的特点和使用性能

本文旨在探讨新型改性酚醛树脂(简称“B树脂”)在铸钢生产领域的特点和使用性能。首先概述了改性酚醛树脂的技术指标和特点,包括其绿色化、高旧砂再生率和低旧砂再生成本等优势。然后研究了如何提高酚醛树脂的耐热性,包括化学和物理改性方法。在此基础上,通过与其他常用砂种的成本比较,展示了改性酚醛树脂砂在清理和模具成本方面的优越性。通过进一步分析改性酚醛树脂砂的使用性能,包括型砂强度和溃散性,发现该树脂不仅能保护金属表面,降低氧化程度,还能提高铸钢件表面质量,有效地减少刺激性气体的产生。综合以上研究结果,得出结论:改性酚醛树脂“B树脂”不含游离甲醛与苯酚,具有无毒性、环保性,在铸钢生产中实现了高度可再生率,降低了废砂排放量。

酯硬化水玻璃砂+酯硬化碱酚醛树脂砂“双砂”造型技术创新与实践

针对公司新上马的酯硬化水玻璃砂铸钢造型生产线初始的酯硬化水玻璃砂造型工艺生产部分厚大合金钢、低碳合金钢及高锰钢铸件表面存在的气孔、皱皮、气痕、冷隔和粘砂铸造缺陷,在原湿型水玻璃砂面、背砂工艺生产铸钢件的启发下,在新上马的酯硬化水玻璃砂铸钢造型生产线通过实施“酯硬化碱酚醛树脂砂面砂+酯硬化水玻璃砂背砂”“双砂”造型的工艺创新,较好地解决了初始酯硬化水玻璃“单一砂”造型工艺生产厚大铸钢件存在的问题,发挥了酯硬化水玻璃砂与酯硬化碱酚醛树脂砂两种型砂各自的工艺优势,为公司新上马的酯硬化水玻璃砂铸钢造型生产线提升铸件质量奠定了坚实的基础。

浅谈3D打印结合传统自硬砂在铸造生产中的应用

主要论述了砂型3D打印结合邦尼树脂自硬砂在铸造生产中的应用,介绍了锦州捷通将砂型3D打印和传统自硬砂造型进行有机结合生产铸件的过程。生产实践证明:砂型3D打印工艺与传统自硬砂造型生产的有机结合,可以充分发挥新旧生产技术的优点,缩短铸件产品交货周期,在保证铸件质量的前提下可以降低铸件造型生产的整体综合成本,提高了生产效率,实现柔性研制+生产。为砂型3D打印生产大型铸件提供了新的思路。

高韧性砂纹粉末涂料用聚酯树脂的合成研究

为提高砂纹粉末涂料的机械性能,探索了醇酸比、三羟甲基丙烷(TMP)用量、柔性单体种类、合成工艺及增韧助剂等对聚酯树脂的影响,通过漆膜冲击仪、T型弯曲仪、氙灯老化、中性盐雾测试等表征了涂层性能。结果表明,以醇酸比1.13、三羟甲基丙烷用量1.2%、己二酸(ADA)作为柔性单体、先IPA酸解后ADA酸解并二次抽真空的工艺条件,采用增韧剂C可赋予聚酯树脂优异的机械性能,该聚酯树脂还具有较高的玻璃化转变温度、良好耐候性和优异的耐盐雾性能。

金属效应粉末涂料表面效果及缺陷处理

通过探索不同铝银粉及用量对金属效应粉末涂料表面流平、光泽和金属效应的影响,以及不同聚酯树脂、助剂(如流平剂、光亮剂、铝银粉排列分散剂等)、挤出工艺、邦定工艺等对涂层表面金属效应的影响作用和表面缺陷的改善作用,为生产金属效应粉末涂料提供理论基础及处理表面缺陷的解决方案,从而保证产品质量,以供同行借鉴。

Extraction of cerium(Ⅳ) using tributyl phosphate impregnated resin from nitric acid medium

Tributyl phosphate （TBP） solvent was used for impregnation into Amberlite XAD-16 nonionic polymeric resin beads using the wet method to prepare solvent impregnated resin （SIR）. Undiluted TBP in a ratio to the resin support （volume to mass） of 6.0 at room temperature （RT） in 24 h was impregnated the resin with a mass ratio of 1.944, while the prepared gross sample of SIR at the ratio of solvent to resin of 3.0 was impregnated with a mass ratio of 1.88. Cerium（Ⅳ） oxide concentrate, prepared from crude Egyptian monazite sand, containing 37% cerium, 1.6% thorium and about 40% the other trivalent rare earth oxides, was used to prepare cerium（Ⅳ） nitrate solution for extraction using the prepared SIR. The impregnated resin was satisfactory for Ce（Ⅳ） extraction from nitric acid medium at room temperature. Cerium loading capacity of the impregnated resin reached 95.6% of the calculated theoretical capacity （173 g/kg （Ce/SIR）） under the conditions of 51.57 g/L cerium and 2.48 g/L thorium, 5.0 mol/L free nitric acid, solution to resin ratio of 10.0 and contacting the phases for 5.0 min. The loading capacity reached 98.75% when cerium concentration was increased to 91.43 g/L under the same conditions.

Biodegradable materials as binders for IVth generation moulding sands

This paper focuses on the possibility of using the biodegradable materials as binders(or parts of binders' compositions) for foundry moulding and core sands. Results showed that there is a great possibility of using available biodegradable materials as foundry moulding sand binders. Using biodegradable materials as partial content of new binders, or additives to moulding sands may not only decrease the toxicity and increase reclamation ability of tested moulding sands, but also accelerate the biodegradation rate of used binders, and the new biodegradable additive(PCL) did not decrease the strength and thermal properties. In addition, using polycaprolactone(PCL) as a biodegradable material may improve the flexibility of moulding sands with polymeric binder and reduce toxicity.

水基树脂型化学固砂体系在海上出砂井研究及应用

海上油田具有高孔高渗的储集物性特征,单井日产液量大且因地层埋深浅、欠压实,岩石胶结程度弱,地层中砂粒易被高速流体拖拽进入井筒,造成冲蚀油嘴、停泵,甚至砂埋,严重影响海上油田高效开发。本研究评价一种水基树脂型固砂体系,结果表明:水基树脂化学固砂体系在25℃时、48 h内黏度保持在2~7 mPa·s,充分保证了注入安全性;固结后岩心渗透率保留率为84.6%~91.4%,岩心抗压强度为3.44~6.95 MPa,化学固砂固结后岩心酸化后强度基本不变,满足生产井后期多轮次酸化要求。化学固砂后岩心耐冲刷临界流速为160 mL·min^(-1),满足海上单井大产液量生产特点。该体系应用于海上M1井,作业前日产液量为196.9 m^(3)·d^(-1),日产油23.6 m^(3)·d^(-1)。化学固砂后日产液量为167 m^(3)·d^(-1),日产油量为18.4 m^(3)·d^(-1),井口化验无砂产出,持续稳产。水基树脂型化学固砂体系海上成功应用,对海上出砂井治理具有重要意义。

纳米SiO_(2)/酚醛树脂复合材料裂纹扩展行为分析及力学性能研究

油气井出砂是疏松砂岩油气藏开采面临的主要矛盾。树脂固结人工井壁防治细粉砂效果优良,可实现复杂井况下的无筛管防砂,是目前油田应用最广泛的化学防砂方法,决定其防砂成败的关键是树脂的固结性能。借助扩展有限元(XFEM)对裂纹经过单个粒子、一对粒子、均匀分布的多个粒子进行数值模拟,研究纳米粒子对裂纹扩展路径和损伤耗散能量的影响,发现纳米SiO_(2)对裂纹影响区间为5个纳米粒子直径,纳米SiO_(2)的最佳质量分数为树脂基体的3%。树脂样条的抗冲击强度和树脂防砂体的抗压强度的测定结果表明,纳米SiO_(2)质量分数为3%时,树脂样条抗冲击强度提高39%左右,树脂防砂体抗压强度提高36%左右,显著改善了酚醛树脂的力学性能。

环氧树脂改性多异氰酸酯微胶囊的制备及其防砂性能

为提高疏松油田的采油率,研发高性能防砂是必须要采取的工艺措施,本论文通过二苯基甲烷二异氰酸酯多聚体(MDIP)与环氧树脂(E-51)反应,制备环氧树脂改性多异氰酸酯(EMP).通过物理化学法中复相乳液法对EMP进行微胶囊化.进行红外、核磁、扫描电镜等结构表征,证明EMP的成功制备.同时EMP微胶囊固砂液平均粒径为0.1359μm和动力学稳定指数(TSI)为0.468,表明该微胶囊的粒径分布均一,且体系稳定.在达到油井粉细砂固结要求的同时最环保和节约成本条件下,得到最佳固砂配方和条件下固结砂柱的抗压强度为6.563 MPa,渗透率为1476 mD,出砂量为6 mg,出砂率为0.006%,同时还具备良好的耐酸、耐盐、耐氧化性,显著提高油井采油率.