海洋微生物原位浓缩保压采样控制系统设计
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摘要
为了实现大量海洋微生物样本的自动采集,设计了一个基于STC单片机的自容式海洋微生物原位浓缩保压采样控制系统。该控制系统采用磁力传动的方式解决电机可靠密封与运行的问题,以单片机作为主控制器,通过检测系统周围海水压力和工作状态,控制电机和电磁阀工作,结合蓄能器的保压特性和采样过滤装置实现对海洋微生物无污染无压力突变浓缩采样。通过对控制系统结构简化设计,提高了可靠性。实验表明,系统结构简单,功能完备,能够实现对海洋微生物的自动采样控制目的。
An autonomous control system for marine microorganism in situ concentration pressure-retaining sampler based on STC microcontroller is designed in order to realize the automatic collection of a large number of marine planktonic samples. The control system uses the method of magnetic transmission to ensure the reliable sealing and safety operation for motor. The control system uses the single chip microcontroller as the main controller; by measuring the seawater pressure and system working status, it controls the motor and solenoid valves to achieve the automatic sampling of marine microorganism combining with accumulator and the sampling filter device. Reliability is improved by simplifying the design of the control system structure. Experiments show that the sampler control system designed in this paper has simple structure and complete function and has successfully achieved the purpose of automatic sampling control of marine plankton.
An autonomous control system for marine microorganism in situ concentration pressure-retaining sampler based on STC microcontroller is designed in order to realize the automatic collection of a large number of marine planktonic samples. The control system uses the method of magnetic transmission to ensure the reliable sealing and safety operation for motor. The control system uses the single chip microcontroller as the main controller; by measuring the seawater pressure and system working status, it controls the motor and solenoid valves to achieve the automatic sampling of marine microorganism combining with accumulator and the sampling filter device. Reliability is improved by simplifying the design of the control system structure. Experiments show that the sampler control system designed in this paper has simple structure and complete function and has successfully achieved the purpose of automatic sampling control of marine plankton.
引文
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[2]李俊峰,韩晓红,段效辉.海洋微生物活性物质研究进展[J].氨基酸和生物资源,2014,36(4):12-16.
[3]朱汉斌,徐海,陈忠.深海微生物来源抗生素研究获突破[J].中国战略新兴产业,2017(33):95.
[4]柏凤月,倪孟祥.海洋微生物来源的抗菌活性物质研究进展[J].化学与生物工程,2016,33(5):15-19,25.
[5]HASAN N A,GRIM C J,LIPP E K,et al.Deep-sea hydrothermal vent bacteria related to human pathogentic Vibrio species[J].Proceedings of the National Academy of Sciences of the United States of America,2015,112(21):E2813-2819.
[6]刘镇盛,杜明敏,章菁.国际海洋浮游动物研究进展[J].海洋学报(中文版),2013,35(4):1-10.
[7]山东省科学院海洋仪器仪表研究所.一种深海用海水液压两位三通电磁阀:中国,CN104964043A[P].2015-10-07.
[8]宏晶科技.STC12C5620AD系列单片机器件手册[EB/OL].[2017-05-24].www.stcmcu.com.
[9]何宾.STC单片机原理及应用[M].北京:清华大学出版社,2015.
[10]代少玉,吴兴林.单片机原理与应用技术[M].西安:西安电子科技大学出版社,2017.
[11]李书灵,王晓霞,李文新,等.磁力传动齿轮泵结构设计及分析[J].机床与液压,2016,44(4):73-75.
[12]杨峰,胡彬,罗青青.STC单片机AD转换及EEPROM使用[J].数字技术与应用,2011(9):169-171.
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