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| Total Pages | : 77 |
| Release | : 1974 |
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| Release | : 1974 |
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| Total Pages | : 850 |
| Release | : 1975-02 |
| Genre | : Nuclear energy |
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| Author | : Darshan Jitendra Sachde |
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| Total Pages | : 482 |
| Release | : 2011 |
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Technology to recover uranium from seawater may act as a potential backstop on the production cost of uranium in a growing international nuclear industry. Convincing proof of the existence of an effective expected upper limit on the resource price would have a strong effect on decisions relating to deployment of uranium resource consuming reactor technologies. This evaluation proceeds from a review of backstop technologies to detailed analyses of the production cost of uranium extraction via an amidoxime braid adsorbent system developed by the Japan Atomic Energy Agency (JAEA). An independent cost assessment of the braid adsorbent system is developed to reflect a project implemented in the United States. The cost assessment is evaluated as a life cycle discounted cash flow model to account for the time value of money and time-dependent performance parameters. In addition, the cost assessment includes uncertainty propagation to provide a probabilistic range of uranium production costs for the braid adsorbent system. Results reveal that uncertainty in adsorbent performance (specifically, adsorption capacity, kg U/tonne adsorbent) is the dominant contributor to overall uncertainty in uranium production costs. Further sensitivity analyses reveal adsorbent capacity, degradation and production costs as key system cost drivers. Optimization of adsorbent performance via alternate production or elution pathways provides an opportunity to significantly reduce uranium production costs. Finally, quantification of uncertainty in production costs is a primary policy objective of the analysis. Continuing investment in this technology as a viable backstop requires the ability to assess cost and benefits while incorporating risk.
| Author | : D. C. Stewart |
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| Total Pages | : 36 |
| Release | : 1953 |
| Genre | : Seawater |
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A new method for the analysis of uranium in sea water has been described. The procedure utilizes a solvent mixture to concentrate the uranium, following which, the amount present is estimated by fission fragment counting in a neutron reactor. With no special precautions being taken, ocean water samples of 20-50 milliliter size can be assayed with a precision of (plus or minus) 5%. The method should make it possible to determine the uranium in a semi-quantitative way in as little as 0.1 ml of sample by a moderate amount of effort in reducing counting backgrounds, or by using coincidence counting techniques.
| Author | : Harry Dreyfus Lindner |
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| Total Pages | : 142 |
| Release | : 2014 |
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Even at 3.3 ppb, seawater contains a uranium supply large enough to power the world's nuclear fleet for 13,000 years. This large supply has prompted interest in technologies for recovering uranium from seawater. Since the 1960's, economic models of such technologies have failed to produce an economically competitive strategy when compared to conventional uranium recovery from terrestrial mining. Thus, uranium from seawater is researched as a potential price ceiling because of the large supply but high recovery cost. Such an upper bound is still valuable research because it allows for more certainty in uranium prices for planning, research, development and deployment of nuclear power systems. This thesis explores past cost estimates for uranium recovery from seawater and adds a new cost estimate to the pool of literature. The past estimates showed a development from systems that actively moved seawater to systems that allowed adsorbent to sit passively in seawater. The adsorbent material changed from hydrous titanium oxide to the higher-capacity amidoxime ligand. Capacity was the strongest driver of cost. Early models with the amidoxime ligand used an acrylic substrate or backbone. This substrate was later replaced by polyethylene because of its increased durability and lower cost. However, each of those materials could contribute to the problem of plastics in the ocean. The new technology assessed for cost in this paper attempts to address the plastics concern by replacing the plastic with a high molecular weight chitin nanomat as the substrate for the amidoxime ligand. The cost assessment showed the technology is presently cost prohibitive largely due to the adsorption capacity and chitin nanomat production costs. To increase capacity, the grafting efficiency onto the chitin substrate must be improved in order to achieve capacities comparable to those observed for the amidoxime-polyethylene adsorbent. To reduce chitin nanomat production costs, the ionic liquid (IL) consumption must be reduced and the recyclability of IL must be achieved.
| Author | : Oak Ridge National Laboratory |
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| Total Pages | : 952 |
| Release | : 1976 |
| Genre | : Power resources |
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| Author | : Oak Ridge National Laboratory |
| Publisher | : |
| Total Pages | : 948 |
| Release | : 1976 |
| Genre | : Power resources |
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| Total Pages | : 720 |
| Release | : 1977 |
| Genre | : Ocean mining |
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| Author | : Maha Niametullah Haji |
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| Total Pages | : 167 |
| Release | : 2017 |
| Genre | : Ocean |
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Seawater is estimated to contain 4.5 billion tonnes of uranium, approximately 1000 times that available in conventional terrestrial resources. Finding a sustainable way to harvest uranium from seawater will provide a source of nuclear fuel for generations to come, while also giving all countries with ocean access a stable supply. This will also eliminate the need to store spent fuel for potential future reprocessing, thereby addressing nuclear proliferation issues as well. While extraction of uranium from seawater has been researched for decades, no economical, robust, ocean-deployable method of uranium collection has been presented to date. This thesis presents a symbiotic approach to ocean harvesting of uranium where a common structure supports a wind turbine and a device to harvest uranium from seawater. The Symbiotic Machine for Ocean uRanium Extraction (SMORE) created and tested decouples the function of absorbing uranium from the function of deploying the absorbent which enables a more efficient absorbent to be developed by chemists. The initial SMORE concept involves an adsorbent device that is cycled through the seawater beneath the turbine and through an elution plant located on a platform above the sea surface. This design allows for more frequent harvesting, reduced down- time, and a reduction in the recovery costs of the adsorbent. Specifically, the design decouples the mechanical and chemical requirements of the device through a hard, permeable outer shell containing uranium adsorbing fibers. This system is designed to be used with the 5-MW NREL OC3-Hywind floating spar wind turbine. To optimize the decoupling of the chemical and mechanical requirements using the shell enclosures for the uranium adsorbing fibers, an initial design analysis of the enclosures is presented. Moreover, a flume experiment using filtered, temperature- controlled seawater was developed to determine the effect that the shells have on the uptake of the uranium by the fibers they enclose. For this experiment, the AI8 amidoxime-based adsorbent fiber developed by Oak Ridge National Laboratory was used, which is a hollow-gear-shaped, high surface area polyethylene fiber prepared by radiation-induced graft polymerization of the amidoxime ligand and a vinylphosphonic acid comonomer. The results of the flume experiment were then used to inform the design and fabrication of two 1/10th physical scale SMORE prototypes for ocean testing. The AI8 adsorbent fibers were tested in two shell designs on both a stationary and a moving system during a nine-week ocean trial, with the latter allowing the effect of additional water flow on the adsorbents uranium uptake to be investigated. A novel method using the measurement of radium extracted onto MnO2 impregnated acrylic fibers to quantify the volume of water passing through the shells of the two systems was utilized. The effect of a full-scale uranium harvesting system on the hydrodynamics of an offshore wind turbine were then investigated using a 1/150th Froude scale wave tank test. These experiments compared the measured excitation forces and responses of two versions of SMORE to those of an unmodified floating wind turbine. With insights from the experiments on what a final full-scale design might look like, a cost-analysis was performed to determine the overall uranium production cost from a SMORE device. In this analysis, the capital, operating, and decommissioning costs were calculated and summed using discounted cash ow techniques similar to those used in previous economic models of the uranium adsorbent. Major contributions of this thesis include fundamental design tools for the development and evaluation of symbiotic systems to harvest uranium or other minerals from seawater. These tools will allow others to design offshore uranium harvesting systems based on the adsorbent properties and the scale of the intended installation. These flexible tools can be tuned for a particular adsorbent, location, and installation size, thereby allowing this technology to spread broadly.
