Synthesis of polymeric ionic liquids material and application in CO2 adsorption

We synthesized one quaternary ammonium polymeric ionic liquids（PILs）P[VBTHEA]Cl and three imidazolium PILs of P[VEIm]Br, P[VEIm]BF, P[VEIm]PFby free-radical polymerization in solution. These PILs were characterized by FT-IR,H-NMR,C-NMR, TGA, XRD and SEM. Their COadsorption capacities were measured under different pressures and temperatures by constant-volume technique. It was observed that quaternary ammonium PILs of P[VBTHEA]Cl have higher adsorption capacity for COthan those imidazolium PILs, following P[VBTHEA]Cl > P[VEIm]PF> P[VEIm]BF> P[VEIm]Br, which may be ascribed to higher positive charge density on ammonium cation than that on imidazolium cation and thus stronger interaction with CO, consistent with the results from dual-mode adsorption model that ammonium PILs have much higher CObulk absorption than imidazolium PILs. COadsorption capacity of P[VBTHEA]Cl is 9.02 mg/g under 295 K and 1 bar, which is comparable to that of some other PILs, and is much higher than that of the corresponding ILs monomer. These PILs have good adsorption selectivity for COover Nand regeneration efficiency.

Coassembled ionic liquid/laponite hybrids as effective CO2 adsorbents

Hybrid adsorbents for COcapture were prepared by coassembling laponite（LP） nanosheets and 1-nbutyl-3-methylimidazolium chloride（BMIMCl）. The prepared BMIMCl/LP layered hybrids were systematically characterized. The interlayer distance of the BMIMCl/LP layered hybrids expanded with an increasing concentration of BMIMCl, indicating that cumulative BMIMCl was intercalated into the LP layers. The efficiency of BMIMCl toward COcapture was significantly enhanced after it was immobilized within LP layers.

Orthogonal array design for the optimization of stripping Sr(Ⅱ) from ionic liquids using supercritical CO2

The strontium ions extracted from the aqueous phase into 1-ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide(C_2mimNTf2) with dicyclohexyl-18-crown-6(DCH18C6) was stripped effectively by supercritical CO_2(sc-CO_2).Hexafluoroacetylacetone(HFAA)-acetonitrile was found to be an excellent modifier of sc-CO_2 to enhance the stripping efficiency.In the orthogonal array design(OAD),OA_(25)(5~5)matrix was employed to optimize the stripping of Sr(Ⅱ) from the DCH 18C6-C_2mimNTf_2 system.Effects of five experimental factors:temperature,pressure,concentration of HFAA,static and dynamic extraction times as well as each factor at five-levels on the stripping of Sr(Ⅱ) were optimized.The effects of these parameters were treated by the analysis of variance(ANOVA).The results showed that Sr(II) could be nearly 100%extracted from the IL phase at 308 K,30 MPa,40 min of dynamic extraction and 60 mmol·L^(-1) HFAA in acetonitrile,respectively.Finally,the stripping mechanism was studied by ESI-MS.

Simulation and Experiment for Oxygen-enriched Combustion Engine Using Liquid Oxygen to Solidify CO2

For capturing and recycling of CO2 in the internal combustion engine, Rankle cycle engine can reduce the exhaust pollutants effectively under the condition of ensuring the engine thermal efficiency by using the techniques of spraying water in the cylinder and optimizing the ignition advance angle. However, due to the water spray nozzle need to be installed on the cylinder, which increases the cylinder head design difficulty and makes the combustion conditions become more complicated. In this paper, a new method is presented to carry out the closing inlet and exhaust system for internal combustion engines. The proposed new method uses liquid oxygen to solidify part of cooled CO2 from exhaust system into dry ice and the liquid oxygen turns into gas oxygen which is sent to inlet system. The other part of CO2 is sent to inlet system and mixed with oxygen, which can reduce the oxygen-enriched combustion detonation tendency and make combustion stable. Computing grid of the IP52FMI single-cylinder four-stroke gasoline-engine is established according to the actual shape of the combustion chamber using KIVA-3V program. The effects of exhaust gas recirculation （EGR） rate are analyzed on the temperatures, the pressures and the instantaneous heat release rates when the EGR rate is more than 8%. The possibility of enclosing intake and exhaust system for engine is verified. The carbon dioxide trapping device is designed and the IP52FMI engine is transformed and the CO2 capture experiment is carried out. The experimental results show that when the EGR rate is 36% for the optimum EGR rate. When the liquid oxygen of 35.80-437.40 g is imported into the device and last 1-20 min, respectively, 21.50-701.30 g dry ice is obtained. This research proposes a new design method which can capture CO2 for vehicular internal combustion engine.

离子液体固定CO2及其转化利用的研究进展

综述了新型绿色溶剂离子液体在CO2固定和转化利用领域的应用研究进展.根据离子液体的结构特征和CO2的固定机理,离子液体固定CO2可以分为常规离子液体固定、功能化离子液体固定和离子液体固定转化.常规离子液体固定CO2为物理作用过程,功能化离子液体固定CO2为化学作用过程,而离子液体固定转化CO2的过程在固定CO2的同时又实现了CO2从工业废气直接到有用化学品的转变.因此,设计合成高效的功能化离子液体来实现CO2的固定转化一体化将具有重要的意义。

多孔液体在CO_(2)捕集与利用领域的研究进展

为助力中国早日实现“双碳”目标,深入落实化工领域绿色低碳可持续发展的重要举措,吸附/吸收耦合有望成为气体分离的绿色变革性分离技术,其关键是高性能吸附(收)材料的开发。多孔液体作为一类具有永久孔隙的液体材料,兼具了液体吸收剂的易于管道输送、传质传热效果好等优点和固体吸附剂的高比表面积、高孔隙率等优点,有望成为新一代CO_(2)捕集的绿色变革性介质。该文首先简单介绍了多孔液体发展历程;然后,重点对多孔液体在CO_(2)的吸附/吸收、膜分离、催化转化等领域的应用进行了论述,并对多孔液体性能和优缺点进行了分析归纳。最后,对多孔液体目前面临的挑战和未来发展趋势进行了展望。

液态CO2溶浸煤体孔裂隙演化特征的实验研究

为研究煤层在液态CO2溶浸作用下煤体孔裂隙的演化特征,设计液态CO2溶浸实验系统,选取3种不同煤质的煤样,干燥后对其进行液态CO2溶浸实验,在一定压力温度下溶浸30 min,通过扫描电镜和核磁共振测试方法对溶浸前后的煤样进行观测,基于分形理论和T2谱分布方法定量地对煤体孔裂隙进行分析,分形理论分析得出:3种煤样分形维数均为增大趋势,且直线拟合系数均大于0.967;T2谱分布分析得出经液态CO2溶浸后,吸附孔T2谱面积增长率分别为15.9%,38.1%,29.1%;渗流孔增长率分别为11.9%,55.7%,61.1%;全孔T2谱面积分别增加24.7%,54.6%,56.1%.结合渗透率理论模型计算1/3焦煤、气煤和褐煤渗透率分别提高了5.56%,13.79%和14.80%.液态CO2溶浸可有效促进煤体裂隙发育,有利于提高煤体的渗透性。

嫁接型离子液体的制备及其对CO2与环氧丙烷环加成反应的催化性能

采用后嫁接法在温和条件下制得了4种嫁接在硅胶上的离子液体，用傅里叶变换红外光谱、元素分析、N2吸附-脱附、热重等手段对其进行了表征，并考察了其对于c02与环氧丙烷（P0）环加成反应的催化性能。结果表明，离子液体以共价键嫁接到硅胶上，具有较好的热稳定性；在无溶剂条件下，在CO2与PO环加成反应中表现出较好的催化活性；其中嫁接在硅胶上的1-丁基-3-甲基咪唑的氢氧化物（[Bmim-10H／SiO2）的催化效果最好，PO的转化率大于99％，碳酸丙烯酯（PC）的选择性达到100％。

考虑煤体层理方向效应的液态CO2致裂增透规律

为研究循环注入液态CO2过程中煤体层理方位对致裂效果的影响,利用非金属超声波检测分析仪与低场核磁共振仪研究了不同循环注入液态CO2煤样的损伤程度及孔隙发育程度。结果表明:煤层层理对煤体的冻融损伤破坏模式及内部孔隙发育均有一定程度的影响;层理方位首先影响煤体裂纹的起裂位置,进而影响其破坏模式及孔隙扩展、延伸、连通;随着循环注入液态CO2次数的增加,煤体表面因冻胀融缩作用引起的裂纹逐渐增多、变宽,煤体内部原有孔隙增大并产生新孔隙,不同层理方位效果不同。

双功能乙醇胺基离子液体催化CO2转化研究

在无溶剂无助催化剂条件下,研究了一系列双功能乙醇胺基离子液体催化剂(IL1~IL7)催化CO 2和环氧烷的偶联反应.该系列环境友好型催化剂具备高催化活性和高选择性的优点.进一步研究表明,卤素离子对催化活性有着重要影响,催化活性顺序为I^->Br^->Cl^-,即含有I^-的催化剂具有最好的催化活性.选取IL2和IL7作为代表性催化剂,系统探讨了催化剂用量、温度、CO 2压力、时间等因素对反应的影响,筛选出最佳的反应条件为催化剂IL2∶PO=1∶100,120℃,2 MPa,4 h,Br-和催化剂IL7∶PO=1∶200,100℃,1 MPa,3 h,I^-.在最佳条件下,环状碳酸酯的产率可高达99%,且产物选择性>99%.最后,根据反应结果和文献报道提出了双功能基团协同催化机理.

以跨临界CO2-离子液体[bmim]PF6为工质对的吸收式制冷循环性能分析

选择跨临界CO2-[bmim]PF6作为新型的吸收式制冷工质对,考察了CO2在离子液体[bmim]PF6中的溶解度和CO2-[bmim]PF6工质体系的热物性。计算了在给定工况下循环的制冷特性并对结果进行了分析与讨论。

复方黄柏液涂剂联合CO2激光治疗面部痤疮的效果

目的分析复方黄柏液涂剂联合CO2激光治疗面部痤疮的临床效果。方法随机选取120例面部痤疮患者为研究对象,根据不同治疗方案将其分为观察组、对照A组和对照B组,各40例,观察组用复方黄柏液涂剂联合CO2激光治疗,对照A组单纯使用CO2激光治疗,对照B组用复方黄柏液涂剂治疗。比较三组的临床疗效、复发情况及患者满意度。结果观察组的治疗总有效率显著高于对照A组和对照B组,差异具有统计学意义(P<0.05);对照A组与对照B组的治疗总有效率比较,差异不具有统计学意义(P>0.05)。观察组的复发率显著低于对照A组和对照B组,差异具有统计学意义(P<0.05);对照A组与对照B组的复发率比较,差异不具有统计学意义(P>0.05)。观察组的满意度显著高于对照A组和对照B组,差异具有统计学意义(P<0.05);对照A组与对照B组的满意度比较,差异不具有统计学意义(P>0.05)。结论复方黄柏液涂剂联合CO2激光治疗面部痤疮效果显著,值得在临床中推广应用。

Phase transition and chemical decomposition of liquid carbon dioxide and nitrogen mixture under extreme conditions

Thermodynamic and chemical properties of liquid carbon dioxide and nitrogen（CO_（2~–）N_2） mixture under the conditions of extremely high densities and temperatures are studied by using quantum molecular dynamic（QMD） simulations based on density functional theory including dispersion corrections（DFT-D）. We present equilibrium properties of liquid mixture for 112 separate density and temperature points, by selecting densities ranging from ρ = 1.80 g/cm^3 to 3.40 g/cm^3 and temperatures from T = 500 K to 8000 K. In the range of our study, the liquid CO_（2~–）N_2 mixture undergoes a continuous transition from molecular to atomic fluid state and liquid polymerization inferred from pair correlation functions（PCFs）and the distribution of various molecular components. The insulator–metal transition is demonstrated by means of the electronic density of states（DOS）.

甲醇合成技术现状及其发展趋势

甲醇生产装置正向生产规模大型化、低能耗以及环境友好方向发展。主要围绕气相法和液相法甲醇合成技术阐述了其工艺和催化剂的发展、反应器的更新迭代以及反应机理的争论,认为在甲醇合成工艺方面,合成反应逐渐沿着最佳动力学和最佳热力学曲线进行,目标为提高碳单程转化率、碳综合利用率和热效率;在甲醇合成反应器方面,正向降低催化床层温差和塔内压降,操作稳定可靠、结构简单、方便催化剂装卸等方向拓展;在甲醇催化剂方面,高转化率、高选择性、优异的稳定性是一直受关注的研究课题。此外,在上述2种甲醇合成工艺的基础上,利用气相法工艺以CO_(2)和H_(2)为原料制绿色甲醇的模式符合“双碳”目标,也是国内外关注的研究热点。

CO2-[emim][Tf2N]二元体系汽液相平衡及超额焓研究

针对CO2-离子液体二元体系的相平衡问题,搭建了一套汽液相平衡数据测定系统,获得了CO2-[emim][Tf2N]二元体系在273.15~328.15 K的汽液相平衡数据,利用PR (Peng-Robinson)状态方程、NRTL (non-random two liquid)活度系数模型结合WS (Wong-Sandler)混合规则对实验数据进行关联,并应用此模型计算得到CO2-[emim][Tf2N]二元体系的超额焓。结果表明:关联得到的压力计算值与实验值相比,两者的平均相对偏差为3.87%,与其他模型对比所选模型偏差最小,能够成功地关联CO2-[emim][Tf2N]二元体系汽液相平衡数据。进一步完善了CO2-离子液体二元体系的关联模型。

CO2气体在地震孕育与发生过程中的作用及其机理研究

通过甘东南地震危险区地震宏观异常观测实例分析,系统研究CO2气体在地震构造活动过程中的地球化学演化过程,以及发生的一系列酸碱平衡和氧化还原化学反应。结果表明地下深部CO2气体不仅是其他微量气体Rn等向地表方向运移的载体,而且参与酸碱平衡和氧化还原反应,是地下深部生物化学反应的重要影响条件,地震前兆及宏观异常现象的发生常伴随着CO2的异常变化。因此CO2气体可以作为良好的示踪气体,在地震前兆观测及重大异常落实中尤其要重视对其进行监测。

井下高压液态CO2压裂增透煤岩成套装备研制与应用

我国煤层渗透率低、瓦斯压力高、含量大,原始煤层瓦斯抽采困难。为提高煤层瓦斯抽采率、缩短预抽时间,必须实施人工增透。而众多压裂增透技术中,液态CO2压裂兼具压裂增透和驱替置换的双重瓦斯强化抽采作用,是当前低渗透煤层压裂改造方法的一个研究热点。为探索液态CO2(L-CO2)压裂增透技术在高瓦斯低透气性煤层中的应用及效果,类比水力压裂施工工艺,提出了井下高压(30 MPa)液态CO2压裂增透煤岩成套装备系统架构,确定了决定装备性能的5个关键参数。基于弹性力学理论、相似模拟实验和装备自身结构特点,综合考虑L-CO2低黏强渗透性和其相变特征,建立了L-CO2压裂煤岩起裂压力计算模型,推导了水和L-CO2压裂注液量的量化表征关系,得到了关键参数的科学确定方法。采用该方法,针对淮南潘三矿C13-1煤层地质赋存条件,研发了国内首套井下高压(30 MPa)L-CO2压裂增透煤岩成套装备,进行了井下上向穿层钻孔的L-CO2压裂增透煤层现场试验。结果表明:L-CO2压裂增透影响半径约25 m,此范围内单孔瓦斯抽采体积分数提高约1.47倍,抽采纯量提高1.75~3.30倍;抽采钻孔出现明显的压裂增流效应,且随抽采孔与压注孔间距离的增加,增流效应逐渐减弱。

液态CO2辅助喷涂发泡聚氨酯硬泡的研究

采用三组分聚氨酯硬泡喷涂高压发泡机,以HCFO-1233zd(E)或HFO-1336mzz(Z)为主体发泡剂,将液态CO2作为第三组分添加,制备了喷涂聚氨酯硬泡。对比了不同含量CO2喷涂发泡制得的聚氨酯泡沫制品的性能。结果表明,添加液态CO2会使泡沫的乳白时间缩短,凝胶时间和固化时间延迟;添加适量液态CO2可以提高泡沫制品的压缩强度,能降低泡沫的闭孔率;添加少量液态CO2会使泡沫的泡孔分布更加均匀,泡沫更加细腻,可以提高HFO类发泡体系泡沫的综合性能,尤其能提高泡沫超低温环境下的绝热性能。

超临界CO2和液态CO2及气态N2注入采空区防灭火性能实验

为对比研究超临界态CO2、液态CO2和气态N2注入采空区的防灭火性能,自主研制了模拟采空区残煤自燃过程实验系统,开展了超临界态CO2、液态CO2和气态N2注入采空区防灭火实验。实验结果表明:12 MPa、39℃超临界态CO2对采空区自燃残煤的降氧降温能力优于6 MPa、30℃液态CO2优于6 MPa、39℃气态N2;12 MPa、39℃超临界态CO2对残煤的降温能力是6 MPa、30℃液态CO2的1.7倍,是6 MPa、39℃气态N2的10倍,对采空区的降温能力是液态CO2的2倍,为气态N2的8倍;12 MPa、39℃超临界CO2对采空区的降氧速率比6 MPa、30℃液态CO2和6 MPa、39℃气态N2高12.5%;12 MPa、39℃超临界CO2的降温能力是8 MPa、39℃超临界CO2的1.7倍,因此适当提高超临界态CO2的注入压力,防灭火性能更佳。

液态CO2处理对微粉煤性质的影响研究

为了考查液态二氧化碳(CO_2)对微粉煤性质的影响,利用间歇作业的搅拌混合柱开展了微粉煤表面改性试验研究,结合FTIR、XPS及微量热仪等分析仪器重点研究了经液态CO_2处理改性前后微粉煤官能团和润湿热的变化情况。结果表明:采用液态CO_2处理可以降低微粉煤含氧官能团含量,从而改变微粉煤的亲/疏水性官能团的比例;而由于液态CO_2良好的扩散吸附特性导致无机矿物微粒夹带进入煤颗粒的内部空隙,最终使得无机矿物微粒覆盖在其内表面上而导致润湿热的增加。