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Journal articles on the topic 'Storage facility'

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Published: 4 June 2021
Last updated: 27 April 2022

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1

Sidorko, Peter, and Linda Lee. "JURA: a collaborative solution to Hong Kong academic libraries storage challenge." Library Management 35, no. 1/2 (January 7, 2014): 46–68. http://dx.doi.org/10.1108/lm-03-2013-0025.

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Purpose – The purpose of this paper is to discuss issues and concerns raised in a collaborative and cooperative central storage facility for Hong Kong academic libraries. Design/methodology/approach – The approach is to propose and to implement a joint storage business plan and a possibility of acting for others to consider similar storage facilities. Findings – Useful experiences have been gained while planning a central storage facility. Research limitations/implications – The proposed JURA project is for Hong Kong academic libraries. Practical implications – The sharing of JURA proposal to create a central storage will inform the libraries around the region of the benefits of having a useful facility in the long term. Originality/value – The paper will inform others wishing to set up collaborative storages on governance, storage systems, business plan, problems and issues in what is still a relatively unexplored approach to storage problems.
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2

Ettehad, Amin, Christopher Jablonowski, and Larry W. Lake. "Gas Storage Facility Design Under Uncertainty." SPE Projects, Facilities & Construction 5, no. 03 (September 1, 2010): 155–65. http://dx.doi.org/10.2118/123987-pa.

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3

Dakin, R. J., B. R. Lederer, and K. R. Parker. "A large scale network storage facility." Software: Practice and Experience 15, no. 9 (September 1985): 889–99. http://dx.doi.org/10.1002/spe.4380150904.

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4

Cheung, Maxwell C., and Maxwell C. Cheung. "8503494 Oil storage and transfer facility." Marine Pollution Bulletin 17, no. 1 (January 1986): ii. http://dx.doi.org/10.1016/0025-326x(86)90811-8.

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5

Vijjapu, P., M. M. Kimothi, S. Roy, S. Mamatha, and S. S. Ray. "GEOSPATIAL PERSPECTIVE FOR POST-HARVEST INFRASTRUCTURE MANAGEMENT: POSITIONING OF NEW COLD STORAGE." ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XLII-3/W6 (July 26, 2019): 339–44. http://dx.doi.org/10.5194/isprs-archives-xlii-3-w6-339-2019.

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<p><strong>Abstract.</strong> The deficiency in post-harvest infrastructure leads to loss of agricultural produce which in turn affects farmer’s income and food security. So, there is a need to improve post-harvest infrastructure in the country. Potato is a major horticultural crop requiring cold storage facility. This study was carried out for Bihar state of India, which has the least ratio of storage capacity to potato production in comparison to other states. An approach has been developed to identify the suitable locations for cold storages using geospatial technology to increase accessibility to cold storage facilities. Temporal variations in vegetation profiles were used to generate crop maps and from this crop area proportions were calculated at village level. These proportions were used to identify significant village clusters contributing to horticulture production. From this priority villages were identified. These priority villages were assigned to nearest major settlement which will be the sites for positioning new cold storage facility. The approach developed in this study has identified 63 locations in 17 districts for developing new cold storage facility. The proposed new locations for cold storages will reduce the distance to nearest cold storage for 14244 villages and this reduction in distance will be more than 8 kms for 9774 villages. Thus, the study validated the role of Remote Sensing and GIS for post-harvest infrastructure planning.</p>
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6

Smetnik, Alexander. "Long-Term Storage and Radioactive Waste Retrieval from Historical Radon-Type Storage Facility." MRS Advances 5, no. 5-6 (December 23, 2019): 283–91. http://dx.doi.org/10.1557/adv.2019.479.

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ABSTRACTWithin the framework of the IAEA project “CRAFT” (2011-2014), specialists of JSC “VO “Safety” participated in working group “Safety assessment of the Radon-type facilities”. The IAEA GSG-3 methodology was used in order to address the issue of safety assessment of radioactive waste removal from historical near-surface storage facility of the Radon type. SAFRAN tool (Sweden) was used for safety assessment of a historical Radon type storage facility. Practical experience of SAFRAN application has shown that it can play a significant role in managing records and knowledge on radioactive waste, nuclear facility site, characteristics of geological environment and safety barriers. It can provide reliable long-term storage and effective management of safety related records for the purposes of safety reassessments, review and supervision.
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7

Kjaer, Mats, and Ehud I. Ronn. "Valuation of a natural gas storage facility." Journal of Energy Markets 1, no. 4 (December 2008): 3–22. http://dx.doi.org/10.21314/jem.2008.014.

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8

Peterson, Kenneth G. "New storage facility at Southern Illinois University." College & Research Libraries News 51, no. 1 (January 1, 1990): 39–43. http://dx.doi.org/10.5860/crln.51.1.39.

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9

Smith, Elizabeth H. "Mold Abatement in a Remote Storage Facility." Library & Archival Security 15, no. 1 (January 1999): 75–82. http://dx.doi.org/10.1300/j114v15n01_05.

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10

Safavi, Bijan. "Localization of Wheat Storage Facility in Iran." Academic Journal of Research in Economics and Management 2, no. 2 (February 2014): 1–9. http://dx.doi.org/10.12816/0006527.

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11

Kachanov, Petro, Oleh Yevseienko, and Nataliia Yevsina. "Devising a method to improve the accuracy of maintaining the pre-set temperature and humidity conditions at a vegetable storage facility under a food storing mode." Eastern-European Journal of Enterprise Technologies 2, no. 2 (110) (April 30, 2021): 89–98. http://dx.doi.org/10.15587/1729-4061.2021.229844.

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A vegetable storage facility is an energy-consuming object with distributed parameters. The quality of product storage depends on the microclimate in the vegetable storage facility: current temperature, humidity, and carbon dioxide level. Existing temperature controllers in a vegetable storage facility use a two-position law of control, which leads to the consumption of excess energy and product spoilage. The purpose of the study is to improve the work of the controller in the process of product storage at the storage phase due to closing the two-position controller through feedback in the form of a first-order aperiodic link. To achieve the goal, the procedure for calculating the transfer function of a control object through the equation of thermal balance was used. This procedure made it possible to take into consideration the parameters of a vegetable storage facility: the area and the type of thermal insulation material of floorings, the weight, and the type of a stored product, as well as thermal energy supplied to the vegetable storage facility. Based on the heat balance equation, the nature of the operation of controlling elements, transfer functions of a vegetable storage facility without a product, and the vegetable storage facility filled with a product, were calculated. The heat model of a vegetable storage facility was constructed in the MATLAB Simulink environment (USA) to check the algorithms of the temperature field control. The product storage for 180 days with changes in the daily temperature of outdoor air from minus 8 °C to plus 2 °C and changes in humidity from 50 % to 100 % was modeled. According to the results of modeling, it is possible to conclude that the addition of an aperiodic link to the feedback of the two-position controller will enable taking into consideration the inertia of a control object. This allows decreasing the maximum error in control of self-oscillations to 0.15 °C and decreasing the total operation time of controlling elements by 13 %
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12

Rovenchak, Ivan I., and Mariia A. Yaroshevych. "Geospatial distribution of gas storage facilities within the East European gas hub." Journal of Geology, Geography and Geoecology 29, no. 2 (July 9, 2020): 398–405. http://dx.doi.org/10.15421/112035.

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The purpose of this article is to elucidate the existing surplus of underground gas storage facilities of the Western region of Ukraine and to substantiate the possibilities of using gas storages not only for the state domestic needs but also for the needs of foreign importers. The gas storage system of the Western region of Ukraine consists of five gas storage facilities and is the basis for forming the future Eastern European gas hub. To better understand the impact of the geographical factor on the formation of the hub, a mapping method is used, which not only depicts the primary information on the position of the main gas storages but also provides an opportunity to analyze the effect of the location of an individual gas storage as it is used during a particular gas year. In order to evaluate the occupation degree of gas storage facilities, as well as to evaluate the possibilities of maximal use, the article analyzes each gas storage facility separately. There were used such methods as the comparative-geographical method, the idealization method, and the principle of causality in this article. The last is an important tool in the study because it allows the cause-and-effect relationship to be traced between the position of the gas storage and its fullness. Using the comparative-geographical method, two principles are taken into account: the similarity principle and the distinction principle. Using the principle of similarity, the article reveals similar characteristics of individual gas storage facilities, and using the distinction principle - on the contrary, highlights the differences. The core of the gas storage system of the Western region is the Bilche-Volyzko-Uherske gas storage facility - the largest gas storage with the total capacity of 17.050 million m³. It should be the core of the future Eastern European gas hub, as its capacity allows to pump the largest volumes of imported gas. The region’s second-largest gas storage facility, Bohorodchanske, at the time of peak gas pumping for the past gas year, was filled by 65% of its total capacity. The third-largest gas storage facility – Dashawske had the highest percentage of usage for the last gas year. If necessary, this gas storage could be filled up by another 207 million m³ (about 10% of the total capacity) according to the conditions of the previous gas year. Oparske and Uherske gas storage facilities were hardly used for the domestic needs of the previous gas year. The total capacity of these gas storage facilities amounted to 2857 million m³ (1710 million m³ Uherske and 1117 million m³ Oparske) in the past gas year.
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13

Valente, Domingos S. M., Daniel M. de Queiroz, Paulo C. Corrêa, Luis C. da Silva, and Sônia M. L. R. do Vale. "A decision support system for cost determination in grain storage facility operations." Engenharia Agrícola 31, no. 4 (2011): 735–44. http://dx.doi.org/10.1590/s0100-69162011000400012.

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Many research works have being carried out on analyzing grain storage facility costs; however a few of them had taken into account the analysis of factors associated to all pre-processing and storage steps. The objective of this work was to develop a decision support system for determining the grain storage facility costs and utilization fees in grain storage facilities. The data of a CONAB storage facility located in Ponta Grossa - PR, Brazil, was used as input of the system developed to analyze its specific characteristics, such as amount of product received and stored throughout the year, hourly capacity of drying, cleaning, and receiving, and dispatch. By applying the decision support system, it was observed that the reception and expedition costs were exponentially reduced as the turnover rate of the storage increased. The cleaning and drying costs increased linearly with grain initial moisture. The storage cost increased exponentially as the occupancy rate of the storage facility decreased.
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14

Niederer, Ulrich. "Hopes and sighs: the Swiss Cooperative Storage Facility." Library Management 37, no. 4/5 (June 13, 2016): 170–81. http://dx.doi.org/10.1108/lm-05-2016-0037.

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Purpose – The purpose of this paper is to present the Swiss Cooperative Storage Facility, a high bay, high density, automated, and oxygen reduced off-site storage facility which serves five research libraries from the German speaking part of Switzerland; it opened in February 2016. Design/methodology/approach – It describes the complete process of evaluating and planning this innovative facility. Findings – It explains the way the cooperation of the five libraries in highly federalist Switzerland was achieved, what principles guided its organization, and how the libraries prepared their holdings for this off-site storage. It shows the construction as an ecologically driven green building with economical advantages. Originality/value – The project seems to be the second automated and oxygen-reduced library storage facility worldwide, after the British Library’s Additional Storage Buildings, and the depth and detail of the evaluation phase is new.
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15

Mališ, Tanja, Anni Milling, and Antonia Jaguljnjak-Lazarević. "PRELIMINARY DESIGN OF POTENTIAL STORAGE FACILITY FOR LOW AND INTERMEDIATE LEVEL RADIOACTIVE WASTE." Rudarsko-geološko-naftni zbornik 33, no. 2 (2018): 27–35. http://dx.doi.org/10.17794/rgn.2018.2.3.

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16

Seabaugh, A., J. E. Pabon, and R. K. Srivastava. "Evaluation of Frozen Thawed Embryo Outcome After Transportation to a Long-Term Storage Facility Versus In-House Storage Facility." Fertility and Sterility 84 (September 2005): S187—S188. http://dx.doi.org/10.1016/j.fertnstert.2005.07.466.

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17

Brkić, Vladislav, Ivan Zelenika, Petar Mijić, and Igor Medved. "Underground Gas Storage Process Optimisation with Respect to Reservoir Parameters and Production Equipment." Energies 14, no. 14 (July 18, 2021): 4324. http://dx.doi.org/10.3390/en14144324.

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The storage of natural gas in geological structures such as depleted fields, aquifers and salt caverns plays an important role in a gas supply system as it balances the fluctuation of gas demand and price. Hydraulic loss due to fluid flow through gas storage production equipment and an interfering effect from nonequal productivity index of storage wells may have an important influence on gas storage performance. An integrated mathematical model is developed based on underground gas storage facility production data. Using this model, the hydraulic loss is determined. A real test case that consists of a gas storage reservoir linked to the surface facility is analysed. The mathematical model uses an experimentally determined pressure drop coefficient in chokes. The base case scenario created using real gas storage facility data enables the achievement of a good history match with the given parameters of the gas storage reservoir. Using the history match simulation case as an initial scenario (a base case), two different scenarios are created to determine the injection and withdrawal performance of the gas storage field. The results indicate that the pressure drop in chokes, when fully open as a constraints in an underground gas storage facility, has a significant impact on gas storage operations and deliverability.
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18

Nagornov, Stanislav, Maksim Levin, and Ekaterina Levina. "Concept of “smart” oil storage facility for agricultural purposes." BIO Web of Conferences 17 (2020): 00176. http://dx.doi.org/10.1051/bioconf/20201700176.

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Technological parameters and technical level of the equipment at an oil storage facility influence motor fuel’s quality and its waste during reception, storage and transfer. The use of intelligent systems during the oil storage and handling process enhances quality preservation and reduction of motor fuel waste caused by evaporation, oxidation and hydration while stored in above-ground horizontal steel tanks. Systems managing “smart” oil-storage facilities combine technologies for on-line collection, transmission and storage of information with instant data processing and analysis, and managerial decision-making techniques. A methodological framework, that includes algorithms and a program with sensors to monitor indicators of an automated horizontal oil reservoir, has been developed to control the technological parameters (temperature, pressure, fuel level) of the tanks during storage of light oil products, and to protect fuel against flooding and evaporation. The application of the neural network forecasting technique for fuel waste from evaporation during storage, and processing of the data array, made it possible to calculate with a 98% accuracy rate the gasoline waste during storage in horizontal on-ground tanks with up to 100 m3 in volume capacity. The application of a neural network enables development of new fuel storage algorithms and calculation of the optimal storage amount to minimise losses. The concept and developed digital intelligent control solutions for oil storage allows combining data in oil management into a single information space, and to control the automated oil storage system with application of neural networks, deep learning and Big Data.
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19

Cousino, Julie, Jamie Brescol, and James Broz. "Ottawa River CSO and Sanitary Relief Storage Facility." Proceedings of the Water Environment Federation 2015, no. 1 (January 1, 2015): 1–26. http://dx.doi.org/10.2175/193864715819523477.

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20

Murphy, John L., and James D. Ring. "Kenduskeag East CSO Storage Facility in Bangor, Maine." Proceedings of the Water Environment Federation 2001, no. 14 (January 1, 2001): 623–39. http://dx.doi.org/10.2175/193864701802779657.

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21

Kulinska, Ewa, and Julia Giera. "Risk Management Model in an Ecological Storage Facility." EUROPEAN RESEARCH STUDIES JOURNAL XXIII, Special Issue 1 (November 1, 2020): 389–97. http://dx.doi.org/10.35808/ersj/1767.

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22

Rogozina, M., M. Zhukovsky, A. Ekidin, and M. Vasyanovich. "Thoron progeny size distribution in monazite storage facility." Radiation Protection Dosimetry 162, no. 1-2 (July 7, 2014): 10–13. http://dx.doi.org/10.1093/rpd/ncu208.

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23

Zhao, Guangzhi, and Matt Davison. "Optimal control of hydroelectric facility incorporating pump storage." Renewable Energy 34, no. 4 (April 2009): 1064–77. http://dx.doi.org/10.1016/j.renene.2008.07.005.

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24

Tatarniuk, Christina, Robert Donahue, and David Sego. "Snow Characterization at a City Snow Storage Facility." Journal of Cold Regions Engineering 23, no. 4 (December 2009): 136–42. http://dx.doi.org/10.1061/(asce)cr.1943-5495.0000011.

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Remillard, Jesse S. "Facility Scale Energy Storage: Applications, Technologies, and Barriers." Strategic Planning for Energy and the Environment 36, no. 2 (September 2016): 22–42. http://dx.doi.org/10.1080/10485236.2016.11771074.

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26

Martin, Barb, and Tom Ries. "Optimize Storage Facility Operation to Maintain Water Quality." Opflow 42, no. 7 (July 2016): 6–7. http://dx.doi.org/10.5991/opf.2016.42.0043.

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27

Manocchi, F. H., M. P. Campos, J. C. Dellamano, and G. M. Silva. "Radon exposure at a radioactive waste storage facility." Journal of Radiological Protection 34, no. 2 (April 4, 2014): 339–46. http://dx.doi.org/10.1088/0952-4746/34/2/339.

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28

Yoder, Kenyon D. "Managing a Low-level Mixed Waste Storage Facility." Health Physics 82, Supplement (May 2002): S77—S81. http://dx.doi.org/10.1097/00004032-200205001-00008.

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29

Fuls, W. F., C. Viljoen, C. Stoker, C. Koch, and M. Kleingeld. "The interim fuel storage facility of the PBMR." Annals of Nuclear Energy 32, no. 17 (November 2005): 1854–66. http://dx.doi.org/10.1016/j.anucene.2005.05.006.

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30

Abulfaraj, Waleed H., Tamim A. Samman, and Salah El-Din M. Kamal. "Design of a temporary radioactive waste storage facility." Radiation Physics and Chemistry 44, no. 1-2 (July 1994): 149–56. http://dx.doi.org/10.1016/0969-806x(94)90121-x.

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31

Kuntjoro, Sri. "CRITICALITY ANALYSIS OF URANIUM STORAGE FACILITY WITH FORMATION RACKS." JURNAL TEKNOLOGI REAKTOR NUKLIR TRI DASA MEGA 19, no. 1 (March 13, 2017): 41. http://dx.doi.org/10.17146/tdm.2017.19.1.3251.

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Uranium materials are needed for the uranium fuel production of research reactors and radioisotope. Before the uranium material is used, it is stored in the storage facility. One of the prerequisites for uranium material storage facilities is that it must be in the sub-critical condition. The purpose of this study is to analyze the criticality condition of uranium material storage facility located in PT. Inuki (Persero) and to ensure that the criticality condition is always in sub-critical state. Criticality analysis was performed using MCNP-5 program to determine the level of criticality of the three uranium material storage facilities at initial conditions and conditions after adding the storage racks. For analysing storage facilities 1 and 2, three scenarios of container on the storage rack formations were considered. Meanwhile, for analysing the storage facility 3, one scenario was considered. The results confirm that all strorages at initial condition and after adding storage racks formation were still in sub-critical condition (k-eff<1). These results are then used as the basis for the uranium materials management. It is also used as a basis for issuing an operational license by the nuclear energy regulatory body (BAPETEN).Keywords : criticality, uranium storage facility, k-eff ANALISIS KRITIKALITAS DI FASILITAS PENYIMPANAN BAHAN URANIUM DENGAN FORMASI PENGATURAN RAK. Bahan uranium dibutuhkan untuk produksi bahan bakar reaktor penelitian dan radioisotop. Bahan uranium sebelum digunakan terlebih dahulu disimpan pada fasilitas penyimpanan. Salah satu prasyarat fasilitas penyimpanan bahan uranium adalah fasilitas tersebut harus dalam kondisi sub-kritis. Bila kondisi kritis terjadi mengakibatkan proses fissi pada bahan uranium tidak terkendali, sehingga akan menimbulkan suhu yang sangat tinggi. Tujuan dari penelitian ini adalah untuk menganalisa kondisi kritikalitas dari fasilitas penyimpanan bahan uranium yang berada di PT. INUKI (Persero) untuk menjamin fasilitas tersebut dalam kondisi sub-kritis. Analisis kritikalitas dilakukan menggunakan program MCNP-5 untuk mengetahui tingkat kritikalitas dari tiga fasilitas penyimpanan bahan uranium untuk kondisi awal dan kondisi setelah ditambahkan rak penyimpanan. Untuk fasilitas penyimpanan 1 dan 2 dibuat tiga skenario pengaturan container pada rak penyimpanan, sedangkan pada fasilitas penyimpanan 3 dilakukan 1 skenario. Hasil ini menunjukkan seluruh fasilitas penyimpanan pada kondisi awal dan setelah ditambah rak penyimpanan dalam kondisi sub-kritis (k-eff<1). Hasil tersebut selanjutnya dipergunakan sebagai dasar untuk menyusun manejemen pengelolaan bahan uranium. Selain itu juga digunakan sebagai dasar untuk pembuatan ijin dari badan pengawas (BAPETEN).Kata Kunci : kritikalitas, fasilitas penyimpanan berbahan uranium, k-eff
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Mdlalose, Siphiwe, Sipho Sibanda, Tilahun Workneh, and Mark Laing. "Innovative Low-Cost Naturally Ventilated Maize Seed Storage System." Journal of Agriculture and Crops, no. 81 (December 27, 2021): 39–49. http://dx.doi.org/10.32861/jac.81.39.49.

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A 22-m3 residential room was converted to a seed storage facility by retrofitting a solar collector on the roof. Three different chimney sizes of diameter and height of 200 mm x 3.6 m, 200 mm x 4.8 m, 300 mm x 3.6 m, and 300 mm x 4.8 m were investigated to determine the best size of the chimney to be used for ventilation in a storage facility. The parameters measured were the air velocity in the chimney duct, as well as the air temperature and relative humidity at the inlet, centre, and outlet of the storage facility. The diameter of the chimney had a significant effect (P<0.05) on the ventilation rate achieved in the storage facility. Significant differences were found between the different chimney diameters and heights (P≤0.05). The 300 mm diameter chimneys were able to extract hot air from the roof solar collector; however, the 200 mm diameter failed. The modified naturally-ventilated seed storage room was able to reduce the relative humidity from 69.7% to a safe relative humidity of 37.9%, while at the same time the temperature increased from 23.3℃ to 35℃ in the 300 mm x 4.8 m chimney.
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Karachristou, I., St Chouvardas, G. Terzoudi, and A. Savidou. "Radiation Protection Calculations for the New Radioactive Waste Interim Storage Facility of NCSR “Demokritos"." HNPS Proceedings 21 (March 8, 2019): 141. http://dx.doi.org/10.12681/hnps.2019.

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The present study concerns the determination of the maximum acceptable contact dose rate per radioac- tive waste package for safekeeping at the New Radioactive Waste Interim Storage (NRWIS) of the National Centre for Scientific Research “Demokritos” (NCSR “D”). The NRWIS facility is used for temporary storage of spent/ orphan sealed sources, devices like lightning rods and primary radioactive waste. The contact dose rate per package is determined in a level that even in case the highest radiation background is built up in- side the storage facility, the doses to the workers will not exceed the maximum permissible doses. The total dose that a worker receives inside the facility should not exceed one half of the annual occupational dose constraint of 6 mSv. Furthermore in cases of the highest radiation background inside the facility, shielding calculations are performed.
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34

Norcini, Jeffrey G., and James H. Aldrich. "Storage Effects on Dormancy and Germination of Native Tickseed Species." HortTechnology 17, no. 4 (October 2007): 505–12. http://dx.doi.org/10.21273/horttech.17.4.505.

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Fresh seeds of prevariety germplasms of goldenmane tickseed (Coreopsis basalis), florida tickseed (Coreopsis floridana), lanceleaf tickseed (Coreopsis lanceolata), and leavenworth's tickseed (Coreopsis leavenworthii) were harvested from cultivated plants and stored under dry conditions for 1 to 24 weeks at 15 or 32 °C to alleviate dormancy, that is, to promote after-ripening. The relative humidity (RH) was 33% for all species except lanceleaf tickseed (23% RH). Seeds were subsequently stored for 24 weeks in a commercial storage facility at 23% RH/17 to 19 °C to determine whether after-ripened seeds could be stored without loss in quality (viability, germination velocity). The only substantial after-ripening occurred with seeds of lanceleaf tickseed, although most after-ripening of lanceleaf tickseed seeds occurred during the 24 weeks of dry storage in the commercial storage facility regardless of storage conditions for the previous 24 weeks. After the 24 weeks in commercial storage, germination of lanceleaf tickseed seeds was 48% to 80%, but germination was only 2% to 15% after 24 weeks of dry storage at 15 or 32 °C, respectively. Freshly harvested seeds of the other three species were much more nondormant than seeds of lanceleaf tickseed, but after-ripening effects were still evident because there were increases in germination or germination velocity (an indicator of after-ripening). Maintenance of seed quality was species-dependent. Seed quality of the two upland species, goldenmane tickseed and lanceleaf tickseed, was maintained during the initial 24 weeks of dry storage plus the subsequent 24 weeks in the commercial storage facility. In contrast, viability of seeds of the two wetland species, florida tickseed and leavenworth's tickseed, declined to varying degrees either during the initial 24 weeks of after-ripening or during storage in the commercial facility. The greatest decline in quality occurred for florida tickseed seeds that were stored for 24 weeks at 32 °C and then for 24 weeks in the commercial storage facility.
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35

Seaman, Scott. "Collaborative Collection Management in a High-density Storage Facility." College & Research Libraries 66, no. 1 (January 1, 2005): 20–27. http://dx.doi.org/10.5860/crl.66.1.20.

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This case study reviews selected collection management issues encountered in a collaboratively managed high-density remote storage facility. In 2000, four Colorado institutions—the University of Colorado at Boulder, the University of Colorado at Denver, the University of Colorado Health Sciences Center, and the University of Denver—opened a shared high-density storage facility. This mix of public and private institutions agreed to collaborative collection management, including a nonduplication policy and the granting of direct access to stored materials for nonparticipating institutions through a statewide union catalog. Ownership of stored materials, selection of items for storage, operational management, and online and physical access proved to be challenging policy issues requiring committees, patience, and compromise to resolve.
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KOMURA, Koh, and Susumu MUKOHARA. "Outline of Waste Storage Facility for Returned Glass Canister." Journal of the Atomic Energy Society of Japan / Atomic Energy Society of Japan 37, no. 7 (1995): 587–92. http://dx.doi.org/10.3327/jaesj.37.587.

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JPT staff, _. "Air Emissions Testing at a Cement-Bulk-Storage Facility." Journal of Petroleum Technology 50, no. 08 (August 1, 1998): 83–84. http://dx.doi.org/10.2118/0898-0083-jpt.

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38

Hemphill, Brian, Rick Shanley, and Ted Mikowski. "INNOVATIVE MATERIAL HANDLING SYSTEM AT BIOSOLIDS CAKE STORAGE FACILITY." Proceedings of the Water Environment Federation 2002, no. 3 (January 1, 2002): 920–31. http://dx.doi.org/10.2175/193864702785302564.

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Takeda, Hirofumi, Tomonari Koga, Masumi Wataru, and Kazuaki Sakamoto. "Evaluation of heat removal characteristic of cask storage facility." Journal of Nuclear Fuel Cycle and Environment 8, no. 2 (2002): 145–53. http://dx.doi.org/10.3327/jnuce.8.145.

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40

Brown, Jeff L. "Into Darkness: The Red Hill Underground Fuel Storage Facility." Civil Engineering Magazine Archive 84, no. 5 (May 2014): 46–49. http://dx.doi.org/10.1061/ciegag.0000583.

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41

Razazian, M., F. Saeidi, S. Yousefnejad, and J. Rahighi. "Magnet design for Iranian Light Source Facility storage ring." Journal of Instrumentation 15, no. 08 (August 7, 2020): P08002. http://dx.doi.org/10.1088/1748-0221/15/08/p08002.

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Verma, Vishnu, A. K. Ghosh, and H. S. Kushwaha. "Simulated model studies for solid waste storage surveillance facility." Nuclear Engineering and Design 211, no. 2-3 (February 2002): 121–38. http://dx.doi.org/10.1016/s0029-5493(01)00448-4.

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Mahfoudi, Nadjiba, Abderahman Khachkouch, Abdelhafid Moummi, Boubaker Benhaoua, and Mohamed El ganaoui. "Design and characterization of a portable heat storage facility." Mechanics & Industry 16, no. 4 (2015): 411. http://dx.doi.org/10.1051/meca/2015021.

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Furst, M. L., R. M. Graves, L. R. Canfield, and R. E. Vest. "Radiometry at the NIST SURF II storage ring facility." Review of Scientific Instruments 66, no. 2 (February 1995): 2257–59. http://dx.doi.org/10.1063/1.1145723.

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Cheung, Maxwell C. "4660606 Offshore oil storage and transfer facility and method." Marine Pollution Bulletin 18, no. 9 (September 1987): ii. http://dx.doi.org/10.1016/0025-326x(87)90373-0.

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Doeswijk, T. G., K. J. Keesman, and G. van Straten. "Uncertainty analysis of a storage facility under optimal control." Biosystems Engineering 99, no. 1 (January 2008): 67–75. http://dx.doi.org/10.1016/j.biosystemseng.2007.09.017.

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Nikitina, N. V., and I. V. Tsidylo. "Stability of a transport facility with flywheel energy storage." Soviet Applied Mechanics 24, no. 12 (December 1988): 1236–41. http://dx.doi.org/10.1007/bf00887933.

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48

Khan, A. A. "Risk analysis of an LPG storage facility in India." Journal of Loss Prevention in the Process Industries 3, no. 4 (October 1990): 406–8. http://dx.doi.org/10.1016/0950-4230(90)80011-x.

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Steinmann, W. D. "The CHEST (Compressed Heat Energy STorage) concept for facility scale thermo mechanical energy storage." Energy 69 (May 2014): 543–52. http://dx.doi.org/10.1016/j.energy.2014.03.049.

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Wróżyńska, Magdalena. "Prediction of Postflotation Tailings Behavior in a Large Storage Facility." Minerals 11, no. 4 (March 30, 2021): 362. http://dx.doi.org/10.3390/min11040362.

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Abstract:
Extracting and copper production on a large scale generates large volumes of postflotation mine tailings. The scale of operation and development of tailings storage facilities (TSFs) forces the use of innovative solutions enabling safe storage now and in the future. Any changes to the operation require multi-directional monitoring of the impact of these changes on storage safety. The ongoing exploitation will be ensured by expansion of the TSF and a change in tailings storage technology. This approach will preclude the need for changes to the new location, such as changes of land use, and will minimise the volume of mine waste. The paper presents the results of pilot studies carried out to implement the change in postflotation tailings storage technology at Żelazny Most TSF (Poland) in the future. The aim of the paper was settlements prediction of tailings and comparison of deformations with observed settlements. Settlements prediction of tailings was made on the basis of the results of the DMT (Marchetti Dilatometer Test), recommended for the prediction of natural soil settlement. Depending on the analysed zone of the TSF, settlements ranged from a few centimetres to over 1.5 m. Despite the difference shown, the results of DMT and geodetic measurements indicate a convergent trend of settlement.
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