GMS150高精度气体调控系统能够将最多4种分歧气体进行精确混合��。每路输入气体的流量使用热式质量流量计精确丈量������,并由内置的质量流量节造器进行精准节造������,输出的是齐全混合的均质气体��。气体输入输出使用Prestolok急剧安全接头������,保障使用过程中的便捷性与安全性��。
GMS150高精度气体调控系统可用于二氧化碳、氮气、一氧化碳、甲烷、氨气以及其他气体的浓度节造��。
GMS150高精度气体调控系统分为GMS150版和GMS150-MICRO版������,其中GMS150版精度更高������,GMS150-MICRO版可调控流速更大��。
利用领域:
?与植物造就箱、光养生物反映器等联用������,进行精确气体节造造就
?仿照分歧CO2浓度环境������,钻研温室效应对植物/藻类的影响
?钻研CO2浓杜纂光合作用的关系
?仿照烟气蹬仔害气体对植物/藻类的影响
?钻研植物/藻类对有害气体的处置与利用
技术参数:
?丈量道理:热式质量流量丈量法
?可调控气体:空气、氮气、二氧化碳、氧气、一氧化碳、甲烷、氨气等干燥纯净、无侵蚀性、无爆炸性气体������,气源需用户自备
?调控通路:标配为2通路������,通路1为Air-N2������,通路2为CO2������,最多可扩大为4通路
?工作温度:15-50℃
?输入/输出接头:Parker Prestolok接头(6mm)
?输入压力:3-5bar
?密封:氟化橡胶
?显示屏:8×21字符液晶显示屏
?尺寸:37cm×28×15cm
?供电:115-230V互换电
?可联用仪器:FMT150藻类造就与在线监测系统、MC1000 8通路藻类造就与在线监测系统、FytoScope系列智能LED光源成长箱、用户自行设计的造就箱或反映器(可提供气路衔接规划)等
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| 与FMT150藻类造就与在线监测系吐洫用 |
与FytoScope智能LED光源成长箱联用 |
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| 与中科院海洋所自行设计的造就装置联用 |
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GMS150版调控参数:
?最幼流量领域:0.02 - 1 ml/min
?最大流量领域:20 - 1000 ml/min
?可定造流量领域:可在最大流量和最幼流量之间定造��。尺度配置通路1(Air-N2): 20-1000 ml/min�����;通路2(CO2): 0.4-20 ml/min�����;可调控CO2浓度0.04% - 100%(现实调控浓杜纂流量有关)
?精度:±0.5%������,加全量程±0.1%(3-5ml/min为全量程±1%������,<3ml/min为全量程±2%)
?不变性:<全量程±0.1%(参考1ml/min N2)
?稳按功夫:1~2s
?预热功夫:30min预热达到最佳精度������,2min预热误差±2%
?温度活络度:<0.05%/℃
?压力活络度:0.1%/bar(参考N2)
?姿势活络度:1bar 压力下与水平面维持90°最大误差0.2%(参考N2)
?沉量:7kg
GMS150-MICRO版调控参数:
?最幼流量领域:0.2 - 10 ml/min
?最大流量领域:100 - 5000 ml/min
?可定造流量领域:可在最大流量和最幼流量之间定造��。尺度配置通路1(Air-N2): 40-2000 ml/min�����;通路2(CO2): 0.8-40 ml/min�����;可调控CO2浓度0.04% - 100%(现实调控浓杜纂流量有关)
?精度:±1.5%������,加全量程±0.5%
?沉复性:流量<20 ml/min为全量程±0.5%������,流量>20 ml/min为现实流量±0.5%
?稳按功夫:1s
?预热功夫:30min预热达到最佳精度������,2min预热误差±2%
?温度活络度:零点<0.01%/℃������,满度<0.02%/℃
?姿势活络度:1bar 压力下与水平面维持90°最大误差0.5 ml/min(参考N2)
?沉量:5kg
利用案例:
与FMT150藻类造就与在线监测系吐洫用钻研蓝藻Cyanothece sp. ATCC 51142 的超日代谢节律(Cerven?, 2013, PNAS)
产地:欧洲
参考文件:
1.Strenkert D, et al. 2019. Multiomics resolution of molecular events during a day in the life of Chlamydomonas. PNAS, 116 (6): 2374-2383
2.Suka?ová K, et al. 2019. Optimization of microalgal growth and cultivation parameters for increasing bioenergy potential: Case study using the oleaginous microalga Chlorella pyrenoidosa Chick (IPPAS C2). Algal Research 40: 101519
3.Cordara A, et al. 2018. Analysis of the light intensity dependence of the growth of Synechocystis and of the light distribution in a photobioreactor energized by 635 nm light. PeerJ, 6:e5256, DOI 10.7717/peerj.5256
4.Cordara A, et al. 2018. Response of the thylakoid proteome of Synechocystis sp. PCC 6803 to photohinibitory intensities of orange-red light. Plant physiology and biochemistry, 132: 524-534
5.Alphen P, et al. 2018. Increasing the Photoautotrophic Growth Rate of Synechocystis sp. PCC 6803 by Identifying the Limitations of Its Cultivation. Biotechnology Journal 13(8): 700764
6.Sarayloo E, et al. 2018. Enhancement of the lipid productivity and fatty acid methyl ester profile of Chlorella vulgaris by two rounds of mutagenesis. Bioresource Technology, 250: 764-769
7.Mitchell M C, et al. 2017. Pyrenoid loss impairs carbon-concentrating mechanism induction and alters primary metabolism in Chlamydomonas reinhardtii. Journal of Experimental Botany, 68(14): 3891-3902
8.Hulatt C J, et al. 2017. Polar snow algae as a valuable source of lipids? Bioresource Technology, 235: 338-347
9.Jouhet J, et al. 2017. LC-MS/MS versus TLC plus GC methods: Consistency of glycerolipid and fatty acid profiles in microalgae and higher plant cells and effect of a nitrogen starvation. PLoS ONE 12(8): e0182423
10.Angermayr S A, et al. 2016. Culturing Synechocystis sp. Strain PCC 6803 with N2 and CO2 in a Diel Regime Reveals Multiphase Glycogen Dynamics with Low Maintenance Costs. Appl. Environ. Microbiol., 82(14):4180-4189
11.Acu?a A M, et al. 2016. A method to decompose spectral changes in Synechocystis PCC 6803 during light-induced state transitions. Photosynthesis Research, 130(1-3): 237-249
