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海洋水文观测中,表层海水温度及表层海水盐度是重要的测量参数。提出了一种可防缠绕的温盐传感器浮子,浮子由浮体、转轴、减摇板、阻流板等构成。浮子的浮体部分可以脱离温盐传感器转动,减少了因流急使整个温盐系统和电缆随着转动而发生缠绕的问题;减摇板可增加浮子的稳定性;阻流板既可以阻止浮子转动,也可以保护浮子不会受到撞击。对"滑轮式"安装方式进行改装,加装导向杆,使浮子沿导向杆上下直线运动,配合改进的"滑轮式"安装方式,浮子转动小,可有效防止温盐浮子转动而造成电缆缠绕。该方法简单可靠,可在海洋站推广使用。 相似文献
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表层海水盐度是海洋水文观测中十分重要的观测项目之一,对其连续观测数据进行统计分析,可获得本海域表层海水盐度状况及变化规律,对海上防灾减灾,促进海洋经济发展有着重要的意义。因此能否获取可靠的观测数据就非常重要。文章介绍一种浮标式的温盐传感器载体装置,由防缠绕固定模块、浮体配重模块和防护过滤模块3部分组成,既能防海水污损,又能减少物理(缠绕、振动、碰撞)因素的影响,大大提高了温盐传感器的使用寿命及观测数据的连续性和可靠性,并且维护方便,非常适合海洋站使用。 相似文献
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本文介绍了自动校准的温度和盐度测量技术,该技术应用在海洋863项目中水质监测浮标的温盐传感器中,自动校准技术可使传器稳定性,准确芳得到很大提高,对应用到海洋领域进行长期观测的传感器具有重要意义。 相似文献
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一种精细化的海洋浮标数据质量控制方法 总被引:1,自引:0,他引:1
针对海洋浮标数据获取特点及常见数据错情,本文提出了一种精细化的海洋浮标温盐数据质量控制方法。通过范围检验、尖峰检验、莱因达准则等六个步骤实现浮标数据质量控制,其创新性在于有效集成了多种质量检验法,并且研究了一种融合传统尖峰检验与莱因达准则的质量检验新方法;并以中国近海观测研究网络黄、东海站浮标温盐观测数据为例,验证了本方法的有效性和适用性。该方法可广泛用于海洋浮标温盐观测数据的质量控制,识别出长时间序列数据的异常值。经过本方法质控后的浮标观测数据对于海洋科学研究、海洋气象预报、海洋灾害预警以及渔业发展等具有重要意义。 相似文献
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《山东海洋学院学报》1984,14(1):3-4
物理海洋学是海洋科学的基础学科,物理海洋学专业是全院中成立较早的专业之一。二十多年来,除担任繁重的教学任务外,还从事物理海洋学方面的科研工作,研究方向包括基础和应用方面,如海浪、海洋环流、潮汐、风暴潮、水团及水温预报、海—气相互作用、海洋工程、温盐结构以及内波等。 相似文献
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现代海洋仪器正向连续自动记录和自动化方面发展着。目前,电测式的海洋温度测量仪器,大都是由测温传感器、探测电缆和自动记录的二次仪表组成。 相似文献
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1997年3月在日本冲绳县那霸市召开了“第二次海底电缆应用国际会议”。美国华盛顿大学两名海洋科学工作者John Delaney和Bruce Howe参加了这次会议。前者由于发现了在海底热水带在光合作用下而能生活的生物,因此成为有名的海洋地质学者;后者是首次获得海洋声波层析成像的学者。日本近十年来积极倡导海底电缆的4D观测,在此领域世界领先。日本在1997年1月17日,应用1964年日本和美国间铺设的最早国际海底电缆。TPC-1和距东京400km的南伊豆小笠原的海底电缆设置了世界最早的海底地震站, 相似文献
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Hirata K. Aoyagi M. Mikada H. Kawaguchi K. Kaiho Y. Iwase R. Morita S. Fujisawa I. Sugioka H. Mitsuzawa K. Suyehiro K. Kinoshita H. Fujiwara N. 《Oceanic Engineering, IEEE Journal of》2002,27(2):170-181
A permanent real-time geophysical observatory using a submarine cable was developed and deployed to monitor seismicity, tsunamis, and other geophysical phenomena in the southern Kurile subduction zone. The geophysical observatory comprises six bottom sensor units, two branching units, a main electro-optical cable with a length of 240 km and two land stations. The bottom sensor units are: 1) three ocean bottom broadband seismometers with hydrophone; 2) two pressure gauges (PGs); 3) a cable end station with environmental measurement sensors. Real-time data from all the undersea sensors are transmitted through the main electro-optical cable to the land station. The geophysical observatory was installed on the continental slope of the southern Kurile trench, southeast Hokkaido, Japan in July 1999. Examples of observed data are presented. Sensor noises and resolution are mentioned for the ocean bottom broadband seismometers and the PGs, respectively. An adaptable observation system including very broadband seismometers is scheduled to be connected to the branching unit in late 2001. The real-time geophysical observatory is expected to greatly advance the understanding of geophysical phenomena in the southern Kurile subduction zone 相似文献
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To perform geophysical and multidisciplinary real-time measurements on the ocean floor, it has been attempted to reuse decommissioned submarine cables. The VENUS project reuses the TPC-2, which is one of these systems and runs across the entire Philippine Sea Plate between Guam Island and Okinawa Island. The VENUS system comprises an ocean floor observatory, a submarine cable, and a land system. The major components of the ocean floor observatory are geophysical instruments and a telemetry system. There are seven scientific instrument units including broadband seismometers and a hydrophone array. Digital telemetry using the old analog telephone cable obtains high data accuracy and real-time accessibility to data from a laboratory on land. The bottom-telemetry system and a part of sensor units were installed at a depth of 2157 m on the landward slope of the Ryukyu (Nansei-Syoto) Trench on August 29, 1999. The data from the hydrophone array and tsunami gauge have been correctly transmitted to the data center. The rest of the scientific instruments will be deployed by deep-tow equipment and a remotely operated vehicle. Using a decommissioned submarine cable will greatly reduce construction costs compared to using a new cable system 相似文献
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David Harris Robert K. Cessaro Fred K. Duennebier David A. Byrne 《Marine Geophysical Researches》1987,9(1):67-94
The Hawaii Institute of Geophysics began development of the Ocean Subbottom Seisometer (OSS) system in 1978, and OSS systems were installed in four locations between 1979 and 1982. The OSS system is a permanent, deep ocean borehole seismic recording system composed of a borehole sensor package (tool), an electromechanical cable, recorder package, and recovery system. Installed near the bottom of a borehole (drilled by the D/V Glomar Challenger), the tool contains three orthogonal, 4.5-Hz geophones, two orthogonal tilt meters; and a temperature sensor. Signals from these sensors are multiplexed, digitized (with a floating point technique), and telemetered through approximately 10 km of electromechanical cable to a recorder package located near the ocean bottom. Electrical power for the tool is supplied from the recorder package. The digital seismic signals are demultiplexed, converted back to analog form, processed through an automatic gain control (AGC) circuit, and recorded along with a time code on magnetic tape cassettes in the recorder package. Data may be recorded continuously for up to two months in the self-contained recorder package. Data may also be recorded in real time (digital formal) during the installation and subsequent recorder package servicing. The recorder package is connected to a submerged recovery buoy by a length of bouyant polypropylene rope. The anchor on the recovery buoy is released by activating either of the acoustical command releases. The polypropylene rope may also be seized with a grappling hook to effect recovery. The recorder package may be repeatedly serviced as long as the tool remains functionalA wide range of data has been recovered from the OSS system. Recovered analog records include signals from natural seismic sources such as earthquakes (teleseismic and local), man-made seismic sources such as refraction seismic shooting (explosives and air cannons), and nuclear tests. Lengthy continuous recording has permitted analysis of wideband noise levels, and the slowly varying parameters, temperature and tilt.Hawaii Institute of Geophysics Contribution 1909. 相似文献
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A cabled ocean observatory system that can provide abundant power and broad bandwidth communication for undersea instruments is developed. A 10 kV direct current (kVDC) with up to 10 kW power, along with 1 Gigabit/sec Ethernet communication, can be transmitted from the shore to the seafloor through an umbilical armored cable. A subsea junction box is fixed at a cable terminal, enabling the extension of up to nine connections. The box consists of three main pressure vessels that perform power conversion, power distribution, and real-time communication functions. A method of stacking modules is used to design the power conversion system in order to reduce the 10 kV voltage to levels that can power the attached instruments. A power distribution system and an Ethernet communication system are introduced to control the power supply and transmit data or commands between the terminals and the shore station, respectively. Specific validations of all sections were qualified in a laboratory environment prior to the sea trial. The ocean observatory system was then deployed at the coast of the East China Sea along with three in situ instruments for a 14-day test. The results show that this high voltage-powered observatory system is effective for subsea long-term and real-time observations. 相似文献
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论文结合中国科学院海洋研究所2017年至2018年在西太平洋布放的一套6000m深自容式锚泊潜标系统,利用其温、深、盐及海流数据,参考卫星观测的海面资料,依据潜标结构组成,创新性地选用多体动力学软件ADAMS建立柔性缆体有限元模型,进行复原式姿态模拟,对此潜标异常沉降情况进行原因探究,提出减小因潜标大深度沉降导致影响的方法。本文所提出的柔性体模型,可依据海流参数变化改变有限元长度,自定义流阻状态,已被证明在较小海流和海流异常大两种分布模型的拟下,计算机有限元模型分析所得绝对沉降误差达缆绳总长0.18%和0.41%。通过计算机模型依据实际情况的模拟结果,最终印证异常沉降值的形成原因:(1)在系泊结构既定且安全布放的前提下,其沉降异常值的出现只能与其当日所处环境的海流分布状态相关。模型锚泊最大受力8621N,合理选择布放地点、潜标材料可降低系泊损坏风险;(2)若大洋中尺度涡形成和临近导致流速激增,其对整个系统的作用将决定锚系系统布放期间异常沉降深度,由于中尺度涡的形成与迁移具有可预报性,结合系泊深度和位置的及时调整可减小超深度沉降所导致的影响。 相似文献
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Ben J. Korgen 《Marine Geophysical Researches》1971,1(3):354-357
A versatile probe for simultaneous studies of heat flow and near-bottom water parameters has evolved through modifications of the Bullard heat probe frame. Suitable sensor arrays have been used with this instrument to study (1) heat flow through the ocean floor, (2) water column temperature structure, (3) near-bottom current speeds, and (4) the differential cooling of water-column temperature sensors placed in a current speed gradient.Some of the advantages of such a modified Bullard probe are: (1) several parameters, including heat flow, can be measured across the sediment-water interface simultaneously, (2) the instrument frame is rigidly pinned to the ocean floor during measurement, permitting true Eulerian measurement in the water column with no effects of ship movement, swaying moorings or cable oscillation, and (3) the device is inexpensive and simple. 相似文献
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Takane Hori Mamoru Hyodo Shin’ichi Miyazaki Yoshiyuki Kaneda 《Marine Geophysical Researches》2014,35(3):285-294
One possible approach to estimating the time interval between large-scale Tōnankai (Tōkai) and Nankai earthquakes on the Japan arc is sequential assimilation of crustal deformation data. We conducted numerical modeling of sequential assimilation using surface deformation calculated from earthquake generation cycle simulations along the Nankai Trough. To account for observation noise, we used measured ocean bottom pressure gauge data, excluding tidal modulation, from a station on the ocean bottom cable network Dense Oceanfloor Network System for Earthquakes and Tsunamis in the Kumano basin. We used sequential importance sampling as our data assimilation method. We found that as the amount of data increased, the estimated time interval between the Tōnankai and Nankai earthquakes approached the “true” observed interval. In addition, the noise in the pressure gauge data was sufficiently small that simulated crustal deformation patterns could be distinguished for different time intervals. 相似文献
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The motion of the ocean through the Earth's magnetic field creates a cross-stream voltage proportional to the transport of the stream. These motion-induced voltages have been observed for more than ten years by the use of an abandoned cable spanning the Florida Current. In-service undersea telephone cables, including fiber optic cables with branch lines, can also be used to determine the motion-induced voltages between the cable sea-Earth grounds because the repeaters in these cables are powered by a nearly constant electric current, the return path for this current is through the ocean via the sea-Earth grounds, and the power voltage and current are readily measured at the cable station or stations. Ocean voltages between West Palm Beach, FL, and Eight Mile Rock, Grand Bahama Island, observed since 1985 by use of an in-service cable yield monthly estimates of the Florida Current transport with an r.m.s. accuracy of 1.1 Sv when compared with the monthly voltage-derived transports between Jupiter, FL, and Settlement Point, Grand Bahama Island, observed by the use of an abandoned cable. This corresponds to an accuracy of 3% of the mean transport of 32.3 Sv 相似文献