• Ocean and Polar Research
• /
• 제26권2호
• /
• pp.361-365
• /
• 2004

Deep-sea Resources Research Center (DRRC) has been using a free-fall grab (FFG) for the resource evaluation of polymetallic nodules in the KODOS (Korea Deep Ocean Study) area, NE Pacific, since 1992. A FFG model (Model 4200, Benthos) adapting one glass buoy system (diameter 17 inch, net buoyance 25.4 kg) has been used until 1993. Since then, DRRC has carried out a study to increase the recovery rate of FFG and it was found that a revised system adapting an additional buoy (diameter 10 inch, net buoyance 4.5 kg) gives improved results. The nodule sampling tests were performed using two different models for the same study area and the resulting recovery rates were compared. The result shows no distinct difference in recovery time between two models, but average recovery rate of the revised model was increased to 99.44% from 96.06% of the original model.

• 한국해양학회지:바다
• /
• 제13권3호
• /
• pp.280-285
• /
• 2008

자유낙하식 시료채취기(Free Fall Grab, FFG)를 이용하여 산출한 망간단괴의 부존밀도는 보정이 필요하다. 그 이유는 FFG로 망간단괴를 채취할 때 해저면에 부존되어 있는 망간단괴의 실제 양 보다 적은 양만이 채취되는 것으로 알려져 있기 때문이다. 지난 1994년과 2002년에 각각 1.29와 1.13의 망간단괴 부존밀도 보정상수가 제시된 바 있으며, 이는 주로 해저면 영상자료의 분석을 통해 이루어 졌다. 이 연구에서는 동일한 정점에서 FFG와 상자형 시료채취기(Box Corer, BC)를 이용하여 회수한 망간단괴의 부존밀도를 비교하여 기존에 제시된 망간단괴 부존밀도 보정상수와 비교하였다. 그 결과 FFG를 이용한 망간단괴의 회수율이 BC에 비하여 낮으며, 그 차이는 약 1.4배로 기존의 보정상수에 비해 훨씬 더 크게 나타났다. 따라서 향후 추가 시료 획득과 해저면 영상분석의 개선을 통해 기존의 망간단괴 부존밀도 보정식을 재산정할 필요성이 제기된다.

• 자원환경지질
• /
• 제44권6호
• /
• pp.475-483
• /
• 2011

자유낙하식 망간단괴 채취기 (FFG)는 정점의 해저면에 분포하는 망간단괴를 모두 채취하기 어렵기 때문에 망간단괴의 부존률을 평가할 때 반드시 보정해서 사용해야 한다. 북동태평양에 위치한 대한민국의 망간단괴 광구 중에서 북쪽광구의 보정상수는 이미 해저면 영상분석으로 결정되어 있다. 그러나 남쪽광구는 망간단괴가 퇴적물에 피복되어 있어서 영상분석에의한 부존률 평가에 지장을 받을 가능성이 있다. 이번 연구에서는 과거에 남쪽광구에서 FFG로 획득한 부존률 자료에 사용한 보정상수를 검증하기 위하여 2007~2009년에 상자형 시료 채취기와 FFG를 동시에 운영하여 40개의 정점자료를 획득하였다. BC와 FFG의 상관분석을 통하여 BC가 FFG에 비하여 1.43배 부존률이 크게 나타났으며, 이것은 남쪽광구에서 실제 망간단괴 분포를 평가하기 위해서는 FFG 자료에 1.43의 보정상수를 곱해서 사용해야 되는 것을 의미한다. 이번에 획득한 보정상수는 기존에 영상분석을 통해 얻은 보정상수(1.42~1.45)와 유사한 결과로서 남쪽광구에서 사용할 보정상수가 검증되었다고 판단된다.

• Ocean and Polar Research
• /
• 제36권4호
• /
• pp.515-524
• /
• 2014

The Korea Institute of Ocean Science and Technology has acquired detailed biological, chemicophysical, and geological data in the northeastern Pacific through a manganese nodule program since 1983. Plenty of manganese nodules were collected to estimate the amount of resources by free-fall grab and box corer. The collected manganese nodules have been archived systematically in the rock and mineral storage section of the Library of Marine Samples (LIMS) since 2012. The LIMS provides essencial information on the stored samples including sample name, nodule type, sampling location, depth, and equipment. Although a high quality database of the information system is under construction, the samples have tagged information for manganese nodules like chemical composition, morphology, weight, size, abundance, and photograph. In this study, we attempted to provide information on the well-organized and easily accessible archived manganese nodule samples for future studies and to introduce the usefulness of the LIMS.

• 자원환경지질
• /
• 제29권4호
• /
• pp.429-437
• /
• 1996

The purpose of this study is to correct the nodule abundance of FFG (Free Fall Grab) sampler on KODOS (Korea Deep Ocean Study) area in North-East Pacific Ocean. The image analysis of sea-floor photography was carried out for correcting the abundance of nodules, and the image enhancement techniques and edge detection method were used to discriminate between nodules and sediments. The trace of nodules on sediments was detected to reduce the fractionation effect in calculating the coverage of nodules. The three methods, using the coverage of nodules, using the volume density, and using corrected volume density, were utilized for the correction of the nodule abundance. The method using the coverage of nodules was more convenient and available for the correction of nodule abundance than the other two methods. The method using the corrected volume density had the highest confidence level compared with the other methods.

• 자원환경지질
• /
• 제28권3호
• /
• pp.199-211
• /
• 1995

The deep sea camera system could render it possible to obtain the detailed information of the nodule distribution, but difficult to estimate nodule abundance quantitatively. In order to estimate nodule abundance quantitatively from deep seabed photographs, the nodule abundance equation was derived from the box core data obtained in KODOS area(long.: $154^{\circ}{\sim}151^{\circ}W$, lat.: $9^{\circ}{\sim}12^{\circ}N$) during two survey cruises carried out in 1989 and 1990. The regression equation derived by considering extent of burial of nodule to Handa's equation compensates for the abundance error attributable to partial burial of some nodules by sediments. An average long axis and average extent of burial of nodules in photographed area are determined according to the surface textures of nodules, and nodule coverage is calculated by the image analysis method. Average nodule abundance estimated from seabed photographs by using the equation is approximately 92% of the actual average abundance in KODOS area. The measured sampling points by box core or free fall grab are in general very sparse and hence nodule abundance distribution should be interpolated and extrapolated from measured data to uncharacterized areas. The another goal of this study is to depict continuous distribution of nodule abundance in KODOS area by using PC-version of geostatistical model in which several stages are systematically proceeded. Geostatistics was used to analyse spatial structure and distribution of regionalized variable(nodule abundance) within sets of real data. In order to investigate the spatial structure of nodule abundance in KODOS area, experimental variograms were calculated and fitted to a spherical models in isotropy and anisotropy, respectively. The spherical structure models were used to map out distribution of the nodule abundance for isotropic and anisotropic models by using the kriging method. The result from anisotropic model is much more reliable than one of isotropic model. Distribution map of nodule abundance produced by PC-version of geostatistical model indicates that approximately 40% of KODOS area is considered to be promising area(nodule abundance > $5kg/m^2$) for mining in case of anisotropy.