产品介绍
德国HYDRO-BIOS公司 多通道水样采集器MWS
类别: 分层采水器
型号: 436 912/436 924
关键字: 多通道水样采集器,CTD采水器,多瓶采水器,分层采水器
供应商: 青岛水德科技有限公司
产品简介:
多通道水样采集器用于海洋水体分层采样,同时可采集各种水质参数,包括温度、盐度、深度、溶解氧等参数。
MWS多通道水样采集器用于在水体中进行水样分层采集工作。它由一组坚固的、装有12/24个支架的不锈钢阵列组成,支架上可以安装容量为5L或10L的采样瓶,用来在一次操作中完成12/24个不同深度水样的采集工作。
多通道水样采集器装有一个马达驱动的自动释放装置,上面集成一个压力传感器,传感器的测量范围可根据用户的工作要求进行选择。耐压水深:3000米,6000米,11000米。整套系统工作时电量消耗低,并且可以在温度为-40℃~+85℃的环境中正常工作。
MWS多通道水样采集器可以由甲板控制单元上的控制按钮控制,进行在线实时采样;也可按照预先设定的采样深度间隔进行离线自容式采样。
多通道水样采集器控制单元:
选配件:
CT-组件,完全整合在多通道水样采集器的驱动单元上,由一个电导率传感器、一个温度传感器和一个电路板组成。
各种参数的传感器,如温度、盐度、叶绿素、浊度等
容量16M为数据存储器
技术参数:
尺寸 | MWS12:直径140cm,高度160cm;MWS24:直径180cm,高度160cm |
空重 | MWS12:约100kg(不带采样瓶);MWS24:约200kg(不带采样瓶) |
操作水深 | 标准配置:3000米;可选配置:6000米,11000米 |
阵列 | 不锈钢材质 |
马达单元 | 由钛制成,电池供电(3×DL123A/3V) |
甲板控制单元 | 金属舱室;带一个控制采样器开关的按钮;显示采样瓶序号、压力和电池状态带发光二极管背景灯的液晶显示屏;与PC机的接口为RS232;由85-260V交流电或电池 |
压力传感器 | 0-3000dbar±0.1%f.s.(标准);0-6000dbar±0.1%f.s.(可选);0-11000dbar±0.1%f.s.(可选); |
独特之处:
√ 操作简单
√ 双向通信
√ 耐压水深:3000米,6000米,11000米(可选)
√ 长距离(>10000米)遥感数据传输
√ 电量消耗低
√ 水下单元有电池操作
√ 电子单元可在温度为-40℃~+85℃的环境中正常工作
√ 获CE国际质量管理标准体系认证,品质保证
MWS多通道水样采集器订购信息:
436 912 MWS 12多通道水样采集器
带微处理器和外置电池组的马达驱动单元;
集成压力传感器;
通过PC机控制的可编程式深度依赖性采样间隔;
16兆数据存储器;
带甲板控制单元,85-260V交流电或电池供电;
可安装采样瓶:12只,5~10L(注意:采样瓶需单独订购)
436 924 MWS 24多通道水样采集器
带微处理器和外置电池组的马达驱动单元;
集成压力传感器;
通过PC机控制的可编程式深度依赖性采样间隔;
16兆数据存储器;
带甲板控制单元,85-260V交流电或电池供电;
可安装采样瓶:24只,1.7~10L(注意:采样瓶需单独订购)
代表文献:
1.Gradinger, Jiirgen Lenz,1989.Picocyanobacteria in the high Arctic.Marine Ecology. Progress series.52:99-101.
2.R. R. Gradinger, M. E. M. Baumann,1991.Distribution of phytoplankton communities in relation to the large-scale hydrographical regime in the Fram Strait.Marine Biology.111(2),311-321.
3.R. J. Gowen, B.M. Stewart, D.K. Mills and P. Elliott,1994.Regional differences in stratification and its effect on phytoplankton production and biomass in the northwestern Irish Sea.Journal of Plankton Research.17(4):753-769.
4.R.J. Gowen, G. McCullough, M. Dickey-Collas and G.S. Kleppel,1997.Copepod abundance in the western Irish Sea: relationship to physical regime, phytoplankton production and standing stock.Journal of Plankton Research.20(2):315-330.
5.K. Richardson, S.H. Jónasdóttir, S.J. Hay, A. Christoffersen,1999.Calanus finmarchicus egg production and food availability in the Faroe–Shetland Channel and northern North Sea: October–March.Fisheries Oceanography.8(1):153–162.
6.M. Trimmer, R. J. Gowen, B. M. Stewart, D. B. Nedwell,1999.The spring bloom and its impact on benthic mineralisation rates in western Irish Sea sediments.Marine Ecology Progress series.185:37-46.
7.Harri T. Kankaanpää, Vesa O. Sipiä, Jorma S. Kuparinen, Jennifer L. Ott, and Wayne W. Carmichael ,1999.Nodularin analyses and toxicity of a Nodularia spumigena (Nostocales, Cyanobacteria) water-bloom in the western Gulf of Finland, Baltic Sea, in August 1999.Phycologia.40(3):268-274.
8.Andrea M. Sass, Henrik Sass, Marco J. L. Coolen, Heribert Cypionka, and Jörg Overmann,2001.Microbial Communities in the Chemocline of a Hypersaline Deep-Sea Basin (Urania Basin, Mediterranean Sea).Applied and Envioronmental Mcrobiology.67(12):5392-5402.
9.Victor W Truesdale, Günther Nausch, Alex Baker,2001.The distribution of iodine in the Baltic Sea during summer.Marine Chemistry.74(2–3):87–98.
10.Ann K. Manske, Jens Glaeser, Marcel M. M. Kuypers and Jörg Overmann,2005.Physiology and Phylogeny of Green Sulfur Bacteria Forming a Monospecific Phototrophic Assemblage at a Depth of 100 Meters in the Black Sea.Applied and Envioronmental Mcrobiology.71(12):8049-8060.
11.Maik Inthorn, Michiel Rutgers van der Loeff, Matthias Zabel,2006.A study of particle exchange at the sediment–water interface in the Benguela upwelling area based on 234Th/238U disequilibrium.Deep Sea Research Part I: Oceanographic Research Papers.53(11):1742–1761.
12.Tim J. Waite, Victor W. Truesdale, Jon Olafsson,2006.The distribution of dissolved inorganic iodine in the seas around Iceland.Marine Chemistry.101(1–2):54–67.
13.MAJANEVA Markus, AUTIO Riitta, HUTTUNEN Maija, KUOSA Harri, KUPARINEN Jorma,2009.Phytoplankton monitoring: the effect of sampling methods used during different stratification and bloom conditions in the Baltic Sea.Boreal environment research.14(2):313-322.
14.Bertics, Victoria J., Löscher, C. R., Salonen, I., Dale, Andy W., Gier, Jessica, Schmitz, R.A. and Treude, Tina,2013.Occurrence of benthic microbial nitrogen fixation coupled to sulfate reduction in the seasonally hypoxic Eckernförde Bay, Baltic Sea.Biogeosciences(BG).10(3):1243-1258.
15.W. DAVISON,1977.Sampling and handling procedures for the polarographic measurement of oxygen in hypolimnetic waters.Freshwater Biology.7(4):393–401.
16.Austin B. M. Egbore,1978.Seasonal variations in the density of a small West African lake.Hydrobiologia.61(3):195-203.
17.Dr. U. Zaiss, P. Winter, H. Kaltwasser,1982.Microbial methane oxidation in the River Saar.Journal of Basic Microbiology.22(2):139–148.
18.V.F. Samanidou & I.N. Papadoyannis,1992.Study of heavy metal pollution in the waters of Axios and Aliakmon rivers in northern Greece.Journal of Environmental Science and Health . Part A: Environmental Science and Engineering and Toxicology.27(3):587-601.
19.Nilgün Kazanci, Reiner-Hartmut Plasa, Eike Neubert & Afife İzbirak,1992.On the limnology of Lake Köycegiz (SW Anatolia).Zoology in the Middle East.6(1):109-126.
20.Eduardo González-Mazo, Jesus María Forja, Abelardo Gómez-Parra ,1998.Fate and Distribution of Linear Alkylbenzene Sulfonates in the Littoral Environment.Environ. Sci. Technol..32(11):1636–1641.
21.V.M León, E González-Mazo, A Gómez-Parra,2000.Handling of marine and estuarine samples for the determination of linear alkylbenzene sulfonates and sulfophenylcarboxylic acids.Journal of Chromatography A.889(1-2):211–219.
22.Claus-Peter Stelzer,2001.RESOURCE LIMITATION AND REPRODUCTIVE EFFORT IN A PLANKTONIC ROTIFER.Ecology.82(9):2521–2533.
23.Udo Noack, Thomas Geffke, Ramani Balasubramanian, Jutta Papenbrock, Mike Braune, Dirk Scheerbaum,2004.Effects of the Herbicide Metazachlor on Phytoplankton and Periphyton Communities in Outdoor Mesocosms.Acta hydrochimica et hydrobiologica.31(6):482–490.
24.L. R. Rodríguez-Gallego, N. Mazzeo, J. Gorga, M. Meerhoff, J. Clemente, C. Kruk, F. Scasso, G. Lacerot, J. García, F. Quintans,2004.The effects of an artificial wetland dominated by free-floating plants on the restoration of a subtropical, hypertrophic lake.Lakes & Reservoirs: Research & Management.9(3-4):203–215.
25.Kristina Samuelsson, Johnny Berglund, and Agneta Andersson,2006.Factors structuring the heterotrophic flagellate and ciliate community along a brackish water primary production gradient.Journal of Plankton Research.28(4):345-359.
26.George Kehayias, Ekaterini Chalkia, Stavroula Chalkia, George Nistikakis, Ierotheos Zacharias, Anastasios Zotos,2008.Zooplankton dynamics in the upstream part of Stratos reservoir (Greece).Biologia.63(5):699-710.
27.MAJANEVA Markus, AUTIO Riitta, HUTTUNEN Maija, KUOSA Harri, KUPARINEN Jorma,2009.Phytoplankton monitoring: the effect of sampling methods used during different stratification and bloom conditions in the Baltic Sea.Boreal environment research.14(2):313-322.
更多关键词:小型分层采水器,Multi Water Sampler,CTD采水器,德国HYDRO-BIOS公司,分层采水器,多通道采水器,水样采集,多筒采水器,微型多通道水样采集器,多瓶采水器,玫瑰花型采水器,多通道水样采集器,多功能水质采样器,水质等比例采样器
产品替代
声明:本产品内容及配图源自互联网收集或平台用户自行上传,目的在于传递更多信息,并不代表本网赞同其观点或证实其内容真实性,不承担此类作品侵权行为的直接责任及连带责任。如涉及作品内容、版权等问题,请联系本网处理,侵权内容将在一周内下架整改。
采水器相关品牌
采水器同类产品
加载中···