Study on Adsorption Removal of Polycyclic Aromatic Hydrocarbons by Modified Mussel Shells

Polycyclic aromatic hydrocarbons(PAHs)are typical persistent organic pollutants(POPs)that are commonly found in the environment.They are carcinogenic,teratogenic,mutagenic and biodegradable obviously.In this paper,the modified mussel shells were used to adsorb and remove anthracene.The results show that the adsorption removal rate of the mussel shells was higher after calcination at 600℃.5%H_(3)PO_(4) solution was more suitable for shell treatment than 3 mol/L ZnCl_(2) solution.As the dosage of the modified shells was 0.5 g/L,the adsorption reached a stable state,and the removal rate of PAHs was about 69.44%;the adsorption efficiency rose with the increase of time.It can be seen that as a new and cheap biological adsorbent,the modified shells can be used to remove PAHs from wastewater.

Effects of Phosphorus Concentration on the Treatment of Domestic Wastewater by a Combination of Hydrolytic Acidification and Biological Aerated Filter Filled with Mussel Shells

The combination of hydrolytic acidification and biological aerated filter （BAF） filled with mussel shells was used to treat domestic wastewater, and the removal rates of chemical oxygen demand （COD）, ammonia nitrogen （NH3-N） and total phosphorus （TP） by the system were analyzed under different TP concentrations. When TP concentration ranged from 12.39 to 14.69 mg/L, the removal rate of COD was the best, over 90.92% ; as TP concentration varied from 2.26 to 2.61 mg/L, the removal rates of NH3-N and TP were the best, up to 100.00% and 76.38% respectively. The results show that it is feasible to use mussel shells as the media of BAF, and TP concentration has certain influence on the performance of the system dealing with domestic wastewater.

Preparation of Porous Materials Derived from Waste Mussel Shell with High Removal Performance for Tableware Oil

In this work,carbonized mussel shell powder(CMSP)was modified by alkyl polyglucosides(APG)and rhamnolipid(RL)to render porous biomass a lipophilic surface,which was innovatively utilized as an environmentally friendly tableware cleaning material.The modified method was two-step hydrotherm-assisted synthesis.A contact angle meter was used to determine the surface hydrophobic property of modified samples(MTAR).The pore and the surface structure of CMSP and MTAR were characterized by BET,SEM,XRD,FTIR and XPS.The effect of removing oil was tested by gravimetric method.The results showed that the surface of MTAR was more porous and fluffier than CMSP,and the specific surface area is increased by 16.76 times.The results showed that when calcining CMSP at 1000℃,the oil removal rate of the synthesized MTAR is the best,and the decontamination rate can reach 87.05%.This research aims to develop a green and environmentally-friendly tableware cleaning material,solve environmental problems,and make full use of waste,which is very conducive to environmental protection.

Beneficial use of mussel shell as a bioadditive for TPU green composites by the valorization of an aqueous waste

Scientific studies have focused on environmentally friendly solutions as effective as the reuse of crop products owing to plastic-waste problems in recent years.This issue is the main driving force for upcoming academic research attempts in waste valorization-related studies.Herein,we integrated an aqua-waste,mussel shell(MS),as a bioadditive form into green thermoplastic polyurethane(TPU)green composites.Tuning of the MS surface was performed to achieve strong adhesion between composite phases.The surface functionalities of MS powders were evaluated via infrared spectroscopy and scanning electron microscopy(SEM)images.Composite samples were prepared by melt-compounding followed by injection molding techniques.It was confirmed by morphological analysis that relatively better adhesion between the phases was achieved for composites involving surface-modified MS compared to unmodified MS.Tensile strength and Young’s modulus of surface-modified MS-filled composites were found to be higher than those of unmodified MS,whereas the elongation at break shifted to lower values with MS inclusions.The shore hardness of TPU was remarkably improved after being incorporated with silane-treated MS(AS-MS).Stearic acid-treated MS(ST-MS)additions resulted in an enhancement in the thermal stability of the composites.Thermo-mechanical analysis showed that the storage moduli of composites were higher than those of unfilled TPU.ST-MS additions led to an increase in the characteristic glass transition temperature of TPU.Melt flow index(MFI)of neat TPU was highly improved after MS loading regardless of modification type.According to the wear test,surface modification of MS displayed a positive effect on the wear resistance of TPU.As the water absorption data of the composites were evaluated,the TPU/AS-MS composite yielded the lowest water absorption.The silane layer on MS inclusion promoted water repellency of composites due to the hydrophobicity of silane.The results of the biodegradation investigation demonstrated that adding unmodified and/or modified MS to the TPU matrix increased the biodegradation rate.The test results at the end of a 7-week period of biodegradation with a soft-rot fungus implied that the composite materials were more biodegradable than pure TPU.Silane modification of MS exhibited better performance in terms of the characterized properties of TPU-based composites.

贻贝壳负载纳米零价铁去除钒(Ⅴ)的性能与机制

针对采矿、冶金、石油炼制等行业产生的含钒废水导致的环境污染难题,以热解后的贻贝壳粉(CMS)为载体,通过液相还原法制备了贻贝壳负载纳米零价铁复合材料(nZVI@CMS),采用SEM、TEM、XRD、BET、FT-IR和XPS等对其进行了表征,通过批量吸附实验考察了nZVI@CMS对V(Ⅴ)的吸附性能,利用吸附动力学、吸附等温线和吸附热力学分析了nZVI@CMS对V(Ⅴ)的吸附机制。结果表明:nZVI@CMS具有疏松多孔的链球状结构,含有多种含氧官能团;在nZVI@CMS投加量0.05 g/L、初始pH=7、V(Ⅴ)初始质量浓度20 mg/L、溶液体积100 mL、温度25℃的条件下,nZVI@CMS在600 min内对V(Ⅴ)的最大吸附量为149.33 mg/g。nZVI@CMS对V(Ⅴ)的吸附过程可通过Langmuir吸附等温模型与准二级反应动力学方程拟合,且该过程是自发的吸热过程。nZVI@CMS对V(Ⅴ)的去除机制主要包括吸附、还原和共沉淀作用。本研究将贻贝壳变废为宝,同时为废水中V(Ⅴ)的高效治理提供了新思路。

生物填料的制备及其对聚丙烯复合材料性能影响的研究

以废弃贻贝壳为原料,经去除角质层、粉碎、研磨、剪切乳化得到生物填料,然后对聚丙烯(PP)进行充填.研究分析了生物填料的物相组成、微观形貌、热稳定性和对其PP充填力学性能的影响.实验结果表明,制备的生物填料主要成分为文石碳酸钙,成片状,粒径大小约为40～500 nm,有机物含量约为2.04wt%,热稳定性良好.生物填料(YBCC)对PP具有增强效果.当填充比例为3wt%时,PP/(YBCC)复合材料屈服强度比PP提高了约11.1%;对PP亦具有异相成核的作用,可诱导形成β晶.利用废弃物贻贝壳为原料生产的生物填料填充PP可降低材料成本,提高力学性能和结晶性能,具有广阔的应用前景.

河蚌壳生物填料的制备及其表面特性

为资源化利用废弃河蚌壳,以其为原料,经去除角质层、分离珍珠层,得到棱柱层。然后机械研磨得到生物填料(HBLZC),并对其物相组成、表面元素组成、微观形貌、热稳定性及其亲水、亲油性等表面特性进行分析表征。研究结果表明:制备的生物填料成分为文石型碳酸钙,成柱状、长条状,有机物质量分数约为2.20%,热稳定性良好。表面元素Ca,C,O和N平均摩尔分数分别为12.10%,33.63%,51.35%和2.93%,其中有机物中C,O和N元素实际摩尔分数分别为54.49%,38.09%和7.42%。HBLZC粉体具有亲水、亲油的双亲性,对正庚烷浸润,对水的接触角约为32°。利用河蚌壳棱柱层为原料生产的生物填料在水性涂料和树脂中具有良好的应用前景。

机械力化学法制备河蚌珍珠层生物填料及其表面特性研究

以废弃河蚌壳为原料,经去除角质层、分离棱柱层,得到珍珠层。采用机械力化学法研磨得到生物填料(HBZZC),对其物相组成、微观形貌、热稳定性及其亲水、亲油性等表面特性进行了分析表征。实验结果表明制备的生物填料主要成分为文石碳酸钙,成片状,粒径大小约为40～1000nm,有机物含量约为4.34%,热稳定性良好。表面元素平均原子分数为Ca(8.71%),C(45.17%),O(43.79%),N(2.33%),其中有机物中各元素实际原子分数为C(64.59%),O(31.28%),N(4.13%)。HBZZC粉体具有亲水、亲油双亲性,对正庚烷浸润,对水的接触角约为24.5°。利用河蚌壳为原料生产的生物填料在水性涂料和树脂中具有良好的应用前景。

天然材料贻贝壳的应用研究

我国贻贝养殖业迅速发展的同时产生了大量的废弃贻贝壳,如何对其资源化利用成为了研究者关注的热点。综述了贻贝壳的研究利用现状,介绍了其作为钙补充剂、土壤改良剂方面的研究现状,探讨了其在重金属、磷及染料去除方面的应用研究进展,讨论了其作为建筑材料、功能材料以及催化剂等方面的利用进展,并对贻贝壳的再利用的发展方向进行了展望。

池塘养殖三角帆蚌的耗氧率

采用流水法现场研究在池塘养殖条件下不同规格(一龄蚌,蚌壳长分别为52和77mm;二龄蚌,蚌壳长分别为69、87和102mm)三角帆蚌的耗氧率.结果表明:在水温为(22.7±0.7)℃,pH为8.07±0.02,溶解氧(dissolved oxygen,DO)为(6.05±0.52)mg/L的条件下,蚌壳长为52、77、69、87和102mm的三角帆蚌的单位质量耗氧率分别为(27.85±7.15)、(17.94±4.89)、(18.76±6.55)、(14.26±3.24)和(14.25±2.51)mg/(kg.h);三角帆蚌个体耗氧率与蚌质量和蚌壳长均显著相关;在实验期间,三角帆蚌单位质量耗氧率存在昼夜差异,夜间(0:00)耗氧率高于白天(12:00);经过3d饥饿后三角帆蚌耗氧率未出现大幅度下降.本结果揭示池塘养殖的三角帆蚌代谢强度远远低于混养的淡水鱼类,说明三角帆蚌养殖不是鱼蚌综合养殖池塘中DO消耗的主要原因.

水力停留时间对水解酸化-改性贻贝壳填料曝气生物滤池处理模拟生活污水的影响

研究了水力停留时间(HRT)对以贻贝壳和3种不同质量分数柠檬酸改性的贻贝壳为填料的曝气生物滤池(BAF)与水解酸化池组合对模拟生活污水中COD、氨氮(NH3-N)和总磷(TP)去除效果的影响,并对4个系统的处理效果进行比较,以考察贻贝壳改性程度对系统处理效果的影响。结果表明,贻贝壳及改性贻贝壳均可以作为BAF的填料,其中0.5%柠檬酸改性的贻贝壳填料处理系统对模拟生活污水的处理效率最高。HRT对COD和TP去除效果的影响较大;HRT为4 h或8 h时,4个系统对NH3-N的平均去除率均在92.30%以上。

育珠期三角帆蚌的生长及其与珍珠增长的关系

通过对三角帆蚌壳长、壳宽、蚌总重(整体湿重)、内脏团湿重、壳重和珍珠重等指标在5-11月间的逐月连续测定,研究了常规养殖模式下育珠期2龄三角帆蚌在主要生长季节的生长规律及其与珍珠生长的相关性。结果表明:珍珠重(PW)与壳长(SL)、壳宽(SW)的关系分别为PW=0.0008SL3.3946(R2=0.6948)和PW=0.7809SW1.0227(R2=0.6888);而珍珠重(PW)与蚌重(TW)、内脏团重(BW)和壳重(W)的关系分别为PW=0.0021TW1.5434(R2=0.7337),PW=0.107BW0.9125(R2=0.7158)和PW=0.0324W1.125 9(R2=0.7101);三角帆蚌总重(TW)与壳长(SL)、壳宽(SW)的关系最适合用指数函数进行拟合,其关系式分别为TW=16.003e0.1681SL,(R2=0.7961),和TW=64.311e0.1372SW(R2=0.6822);而内脏团重(BW)和壳重(W)与壳长(SL)、壳宽(SW)的关系则适合为幂函数曲线拟合,关系式分别为BW=0.018 8SL3.1427,(R2=0.6927);W=0.0656SL2.7721,(R2=0.8271)和BW=12.446SW0.8974(R2=0.617);W=19.876SW0.802(R2=0.7563)。本研究结果发现,珍珠生长与蚌总重、壳长和壳宽等外部测量指标之间的相关性显著,从而无须通过杀蚌取珠而直接通过这些外部生长指标的测定就能较好地了解珍珠的生长,更好地为珍珠养殖生产和管理提供指导。

用扫描电镜研究淡水蚌壳的热分解行为

用扫描电镜(SEM)和傅立叶变换红外光谱(FT IR)法,研究了淡水蚌壳在不同温度时的结构变化。SEM观察蚌壳纵断面结构发现,在280℃煅烧10 m in的蚌壳出现了两条明显的裂缝,同时棱柱层和珍珠层微结构发生变化。FT IR测量蚌壳粉发现,随着温度的升高,蚌壳中的有机物逐渐分解,600℃时完全消失;同时无机物也逐渐分解,在600℃恒定2 h,碳酸钙完全分解为氧化钙。

微冻及真空包装对原汁整壳贻贝贮存期品质的影响

为研究微冻及真空包装对原汁整壳贻贝贮存期品质的影响,将原汁整壳贻贝进行真空包装及普通包装,于4和-3℃下进行贮存,对样品的感官评分、汁液流失率、pH、电导率、挥发性盐基氮(total volatile basic nitrogen,TVB-N)、2-硫代巴比妥酸(2-thiobarbituric acid,TBA)、菌落总数等指标的变化规律进行分析。结果表明:原汁整壳贻贝在贮藏过程中,随着时间的延长,感官评分下降;pH先降低后升高;汁液流失率、TVB-N、TBA、电导率和菌落总数均随贮存时间的延长而增长。-3℃微冻的保鲜效果明显优于4℃冷藏(P<0.05),真空包装的保鲜效果明显优于普通包装(P<0.05),-3℃微冻结合真空包装保鲜效果最佳,能显著延缓原汁整壳贻贝感官性状的下降(P<0.05),抑制汁液流失率、电导率、TVB-N值、TBA值的上升(P<0.05),延缓pH最低点出现的时间(P<0.05),抑制菌落总数的增长(P<0.05)。综合比较分析,4℃普通包装、4℃真空包装、-3℃普通包装、-3℃真空包装的货架期分别为6、15、15和60 d。因此,微冻结合真空包装能较好维持原汁整壳贻贝的感官性状及品质稳定性,有效延长货架期。

贻贝壳在不同方法下合成羟基磷灰石多孔微球的性能研究

选用舟山市贻贝壳为原料制备羟基磷灰石(HA)多孔微球,球形HA较其他形状的HA有更多的药物和金属负载量,可以合成特殊的功能性材料.实验过程为:采用贻贝壳提取CaCO_(3),以贻贝壳的CaCO_(3)为原料,用水热法、沉淀法、十六烷基三甲基溴化铵模板剂法及反相微乳液法制备HA,经比较确定可行方案,并对制备出的样品进行银离子吸附实验.研究结果表明:通过扫描电子显微镜表征观察得出水热法制备的产物为球形;X射线粉末衍射仪和傅里叶红外光谱仪测得水热法制得的产物为HA,其他产物为方解石型CaCO_(3)/HA复合材料;比表面积及微孔孔隙分析表征得出水热法制备的产物介孔结构和比表面积最优;电感耦合等离子体发射光谱仪检测产物的钙磷比及载银量,确定水热法制备的样品为缺磷型HA,该HA的银离子吸附率达75.10%.表明贝壳制备HA多孔微球是可行的,采用水热法可将贝壳CaCO_(3)合成球形多孔HA,且在转化程度和载银效果方面较其他方法更有优势.

生态因子对厚壳贻贝眼点幼虫生长和存活的影响

为了实现厚壳贻贝人工育苗技术突破和推广,研究了海水盐度、温度、p H等生态因子对厚壳贻贝眼点幼虫的生长和存活的影响,筛选出最佳的繁育条件。结果表明：厚壳贻贝眼点幼虫对盐度的适应范围为23.5~39.1,最适为27.4~35.3;对温度的适应范围为18~27℃,最适为21~24℃;对pH值的适宜范围为7.5~9.0,最适为7.8~8.5。掌握了厚壳贻贝眼点幼虫对主要生态因子的适应范围,对厚壳贻贝人工育苗技术的突破具有重要的指导意义。

原汁整壳真空包装贻贝的加工工艺研究

为延长贻贝货架期并保持其鲜品的风味,以枸杞岛厚壳贻贝为原料,开发原汁整壳真空包装贻贝产品。在单因素试验的基础上,通过正交试验优化原汁整壳真空包装贻贝加工工艺,制定包装与杀菌参数,并对产品品质进行分析。结果表明,最佳脱腥调味工艺为预煮75 s,白砂糖添加量2%,食盐添加量6%,味精添加量0.5%;真空包装条件为抽真空时间9 s,热封温度160℃,热封时间3 s,袋内真空度为-0.1 MPa;杀菌参数为110℃、30 s蒸汽式杀菌。在此工艺条件下制得的产品在-18℃经6个月的保存后,与鲜贻贝比较,在感官及理化指标上无显著差异,微生物指标达到国家食品安全标准。

低温烧结蚌壳改性粉煤灰水泥基材料水化机理分析

鉴于粉煤灰和废弃蚌壳对环境的污染,研究了将二者复合用作水泥砂浆掺合料的可行性。通过对蚌壳进行研磨过筛处理,粒度控制在124μm左右,对比分析了不同温度烧结后蚌壳粉与室温蚌壳粉对水泥砂浆性能的影响,确定了蚌壳的适宜烧结温度和掺量。采用X射线衍射(XRD)、扫描电镜(SEM)和热重-差热分析(TG-DTA)等手段对烧结后蚌壳粉改性砂浆水化机理进行了深入分析。研究表明:磨细蚌壳粉经850～900℃烧结后,掺量为3%时对粉煤灰水泥基材料的激发作用最显著,能促进水泥复合胶凝体系的水化,生成大量水化硅酸钙凝胶(C-S-H)和钙矾石(AFt)等水化产物,蚌壳粉改性水泥砂浆的3 d、28 d抗压强度较空白砂浆均有所提高,改性后水泥砂浆具有良好的力学性能。

煅烧废弃河蚌壳制取化剂的分解特性研究

为了研究河蚌壳在煅烧过程中的分解特性及影响产物比表面积的因素，采用差热天平，分析蚌壳的分解特性，在河蚌壳分解过程中，有机物成分在287—458℃区间分解，CaCO3在600℃开始分解，800℃几乎分解完全．利用电镜分析观察不同煅烧温度时产物的形貌特征，发现随着温度的升高，产物不断被细化，1100℃时产物出现熔融烧结．选择三因素四水平的正交试验，优化了分解产物比表面积的主要影响因素，选择以1000℃煅烧、120μm初始粉碎粒径和1．5h的保温时间为最佳比表面积制备条件．

水解酸化—改性贻贝壳填料曝气生物滤池处理生活污水研究

[目的]研究水解酸化—改性贻贝壳填料曝气生物滤池（BAF）处理生活污水的效果。[方法]在不同磷含量条件下,分别以未改性贻贝壳及3种不同浓度柠檬酸改性贻贝壳为填料的曝气生物滤池与水解酸化池组合对生活污水中COD、氨氮（NH3-N）和总磷（TP）进行去除,并对4种贻贝壳BAF的去除效果进行比较。[结果]当磷含量为14.03~14.73 mg/L时,1.0%柠檬酸改性贻贝壳为填料BAF对COD的去除效果最好,去除率最高可达90.11%;在2种不同磷浓度的条件下,4种贻贝壳BAF对NH3-N均有很好的去除效果;当磷含量为2.26~2.61 mg/L时,1.0%柠檬酸改性贻贝壳为填料BAF对TP的去除效果最好,去除率最高可达91.89%。磷含量的提高可以在一定程度上促进COD和NH3-N的去除,但TP的去除效率降低。[结论]4种贻贝壳填料BAF中,1.0%柠檬酸改性贻贝壳填料BAF对生活污水中COD、NH3-N和TP去除效果最好。