1) soybean hull peroxidase
豆壳过氧化物酶
1.The effects of affinity ligand (polyethylene glycol (PEG)- iminodiacetic acid (IDA)-Cu(II)) on the affinitypartition of soybean hull peroxidase (SHP) were investigated in different types of aqueous two-phase systems.
采用双水相金属螯合亲和萃取法从豆壳中分离过氧化物酶,考察了豆壳过氧化物酶在不同类型双水相系统中金属螯合亲和配基聚乙二醇(PEG)-亚氨基二乙酸(IDA)-Cu(Ⅱ)对亲和分配的影响,发现PEG/羟丙基淀粉(PES)系统适合于金属螯合亲和分配豆壳过氧化物酶。2) soybean coat
豆壳3) modified soybean hull
改性豆壳
1.The sorption behaviors of Cu (II) and malachite green (MG) from aqueous solution onto modified soybean hull (MSH) were investigated in a batch system.
报道了一种功能基为磷酸羟基的酯化豆壳阳离子吸附剂的固相制备技术,研究了铜离子和孔雀绿在改性豆壳上的吸附行为.采用静态批次试验研究了不同实验参数(pH值、吸附剂用量、吸附质浓度和吸附时间)对铜和染料吸附的影响.铜离子和孔雀绿分别在pH≥3.0和6.0时达到最大吸附值.对于浓度为100mg·L-1的铜溶液,5.0g·L-1及以上的改性豆壳能去除91%以上的铜;改性豆壳用量≥2.0g·L-1时,能去除浓度为250mg·L-1的溶液中95%以上的孔雀绿.改性豆壳对铜离子和孔雀绿的吸附符合Langmuir吸附等温线模型,最大吸附能力分别为31.55mg·g-1和178.57mg·g-1.对铜离子和孔雀绿的吸附分别在75min和7h达到吸附平衡,准一级反应动力学方程和准二级反应动力学方程能分别描述铜离子和孔雀绿在改性豆壳上的吸附过程4) mungbean hull
绿豆壳
1.The optimal extracting technological conditions of flavonoids from mungbean hull were studied.
采用低浓度AlCl3为显色剂紫外吸收光谱法测定黄酮的含量,研究了以乙醇作为提取剂提取绿豆壳中黄酮类物质的最优提取工艺。5) activated carbon
蚕豆壳
1.The mew processing of manufacturing of activated carbon from broad bean shell leached with zinc chloride by microwave radiation has been reported.
研究了微波辐照蚕豆壳制造活性炭新工艺.实验结果表明,微波工艺所需时间仅为传统工艺的1/45 ,而所得活性炭产品的亚甲蓝脱色力为国家标准一级品(LY216 - 79) 的1-5 倍