multi N/C ?3100总有机碳/总氮分析仪,用于检测液体/固体样品TNb的含量,适用于制药用水、超纯水、自来水、地表水、污水、废水、海水、发酵液体等所有水质以及经过前处理的植物、土壤样品分析。可广泛应用于以下领域:高校科研、市政供排水、电力、石油石化及化工、地质矿业、煤炭、水利、农业、环保、疾控、海洋等。
针对垃圾/污泥焚烧厂对烟气排放参数的测量,聚光科技(杭州)股份有限公司所推出的CEMS-2000 B FT型傅立叶烟气排放连续监测系统(以下简称CEMS-2000 B FT系统)可以连续监测SO2、NOX(NO、NO2)、NH3、HCL、HF、CO、CO2、O2、H2O、烟尘(颗粒物)浓度、烟气温度、压力、流速多项相关参数,并统计排放率、排放总量等,从而对测量到的数据进行有效管理。
multi N/C ?3100总有机碳/总氮分析仪,用于检测液体/固体样品中总有机碳TOC/TNb的含量,适用于制药用水、超纯水、自来水、地表水、污水、废水、海水、发酵液体等所有水质以及经过前处理的植物、土壤样品分析。可广泛应用于以下领域:高校科研、市政供排水、电力、石油石化及化工、地质矿业、煤炭、水利、农业、环保、疾控、海洋等。
multi N/C ?3100总有机碳/总氮分析仪,用于检测液体/固体样品中总有机碳TOC/TNb的含量,适用于制药用水、超纯水、自来水、地表水、污水、废水、海水、发酵液体等所有水质以及经过前处理的植物、土壤样品分析。可广泛应用于以下领域:高校科研、市政供排水、电力、石油石化及化工、地质矿业、煤炭、水利、农业、环保、疾控、海洋等。
multi N/C ?3100总有机碳/总氮分析仪,用于检测液体/固体样品中总有机碳TOC/TNb的含量,适用于制药用水、超纯水、自来水、地表水、污水、废水、海水、发酵液体等所有水质以及经过前处理的植物、土壤样品分析。可广泛应用于以下领域:高校科研、市政供排水、电力、石油石化及化工、地质矿业、煤炭、水利、农业、环保、疾控、海洋等。
multi N/C ?3100总有机碳/总氮分析仪,用于检测液体/固体样品中总有机碳TOC的含量,适用于制药用水、超纯水、自来水、地表水、污水、废水、海水、发酵液体等所有水质以及经过前处理的植物、土壤样品分析。可广泛应用于以下领域:高校科研、市政供排水、电力、石油石化及化工、地质矿业、煤炭、水利、农业、环保、疾控、海洋等。
An experimental study of the interaction of a planar diffusion flame with a line vortex is presented. A planardiffusion flame is established between two coflowing, equal velocity streams of acetylene diluted with nitrogenand air. A line vortex is generated on demand by momentarily pulsing one of the flow streams by way of electromagneticactuation of a piston in the flow apparatus. The flame–vortex interactions are diagnosed by planarlaser-induced incandescence for soot yield and by particle image velocimetry for vortex flow characterization. Theresults show that soot formation and distribution are influenced by the reactant streams from which vortices areinitiated. The vortices interacting with the flame from the air side produce more soot and soot is distributed in andaround the vortex core in diffuse layers. In contrast, topography of soot in vortices interacting from the fuel sideis such that soot is confined to thinner layers around the vortex core which does not contain any soot. The flamecurvature is found to influence the local soot production with the flame regions convex to the fuel side containingmore soot locally. It is also found that the overall soot yield is less sensitive to the vortex strength and is of lowermagnitude when vortex is spun from the fuel side. The knowledge of this type of asymmetry in soot yield inflame–vortex interactions is useful for combustion engineering and design of practical devices.