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China boasts breakthrough in nuclear technology

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Like I said, my intention is not to belittle another country. I only speak the truth and I think it's important that others hear it.

South Korea's nuclear power independence
"May 28, 2008 ... South Korea started its nuclear power program in the 1970s by licensing pressurized water reactor (PWR) technology from US-based Westinghouse..."

South Korean nuclear research programs - Wikipedia, the free encyclopedia
"Although plutonium has uses other than the manufacture of weapons, the United States later insisted that South Korea not attempt to reprocess plutonium in any way. In exchange, the US agreed to transfer reactor technology and give financial assistance to South Korea's nuclear energy program. It was revealed in 2004 that some South Korean scientists continued some studies; for example, in 1983 and 1984 Korea Atomic Energy Research Institute was conducting chemical experiments related to the handling of spent fuel that crossed the reprocessing boundary."
 
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US just recently succeed in testing the electromagnetic catapult system. But China is working on its own as well.

Construction of aircraft carrier catapult has been one of the few big problems. China electromagnetic catapult project by designer Walter Ma (Electrical Engineering Department of Tsinghua University in 1996 Chinese Academy of Engineering, Rear Admiral) lead a group of designers is research. Back in 1996 the Chinese research institutions had done on the experimental kinetic energy of electromagnetic energy conversion, the conversion rate can reach more than 50% amazing, instantaneous energy of 20 MJ with a mature and 100 MJ output level of the device. China will build its own nuclear-powered aircraft carrier that he led the successful development of the carrier-based aircraft carrier electromagnetic catapult. The Varyag will use the steam catapult, and to retain the way off skid. Chinese researchers now have full control of the steam catapult related technologies, and has been put into the manufacture of solid pieces. According to internal data, to be used Varyag catapult weighing 800 tons, about the past hundred meters, for the two-cylinder operation. Steam catapult to launch 40 tons of weight within the aircraft, to 300 to 400 kilometers per hour, the acceleration of gravity up to 5 ~ 6g, every 2 to 3 minutes to launch aircraft. Varyag two catapult mounted on a common, rather than the four hearsay. Whether this performance is the carrier or carrier-based early warning of heavy fighters are to meet the take-off conditions.

china news Varyag carry the dream of many Chinese people carrier, equipped browse the table!
 
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China announces nuclear fuel breakthrough - People's Daily Online January 04, 2011

P201101040824131750293858.jpg

This Dec 26, 2008 file photo shows a huge construction site of the expansion project of the two million-kw generating units in the Qinshan Nuclear Power Plant in Haiyan, East China's Zhejiang province. (Xinhua Photo)

Chinese scientists have made a breakthrough in spent fuel reprocessing technology that could potentially solve China's uranium supply problem, Chinese television reported on Monday.

The technology, developed and tested at the No.404 Factory of China National Nuclear Corp in the Gobi desert in remote Gansu province, enables the re-use of irradiated fuel and is able to boost the usage rate of uranium materials at nuclear plants by 60 folds.

"With the new technology, China's existing detected uranium resources can be used for 3,000 years," the China Central Television reported.

China, as well as France, the United Kingdom and Russia, actively supports reprocessing as a means for the management of highly radioactive spent fuel and as a source of fissile material for future nuclear fuel supply.

But independent scientists argued that commercial application of nuclear fuel reprocessing has always been hindered by cost, technology, proliferation risk and safety challenges.

China has 171,400 tonnes of proven uranium resources spread mainly in eight provinces -- Jiangxi, Guangdong, Hunan, Xinjiang, Inner Mongolia, Shaanxi, Liaoning and Yunnan.

China is planning a massive push into nuclear power in an effort to wean itself off coal, the dirtiest fossil fuel. It now has 12 working reactors with 10.15 gigawatt of total generating capacity.

China has set an official target of 40 gigawatts (GW) of installed nuclear generating capacity by 2020, but the government indicated it could double the goal to about 80 GW as faster expansion was one of the more feasible solutions for achieving emissions reduction goals.

As such, China will need to source more than 60 percent of the uranium needed for its nuclear power plants from overseas by 2020, even if the country moves forward with a modest nuclear expansion plan, Chinese researchers say.

Source:Xinhua

P201101040823412922620234.jpg

This Dec 26, 2008 file photo shows a huge construction site of the expansion project of the two million-kw generating units in the Qinshan Nuclear Power Plant in Haiyan, East China's Zhejiang province. (Xinhua Photo)
 
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Is BigTreeCN a Chinese of Korean descent? Just curious.

我是100%的中国人。

我拿韩国来做例子并不是因为我有韩国血统或者说是我很哈韩,我并不是高丽棒子的崇拜者。我只是想说明,中国在有些方面是落后的,甚至比韩国都落后,这是事实。

不管韩国是如何获得核技术的,重要的是韩国人已经吸收和掌握了这些核技术,现在正在出口核技术是韩国,而正在进口核技术的是中国。事实如此之清楚,为什么还有人要反驳。

中国比韩国更早发展核技术,但是在民用核领域,却一直在进口核技术,从最开始的秦山核电站和大亚湾核电站到现在正在大规模建设当中的核电站,中国进口了一代又一代核技术,试问中国何时才能拥有自己的技术?
 
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我是100%的中国人。

我拿韩国来做例子并不是因为我有韩国血统或者说是我很哈韩,我并不是高丽棒子的崇拜者。我只是想说明,中国在有些方面是落后的,甚至比韩国都落后,这是事实。

不管韩国是如何获得核技术的,重要的是韩国人已经吸收和掌握了这些核技术,现在正在出口核技术是韩国,而正在进口核技术的是中国。事实如此之清楚,为什么还有人要反驳。

中国比韩国更早发展核技术,但是在民用核领域,却一直在进口核技术,从最开始的秦山核电站和大亚湾核电站到现在正在大规模建设当中的核电站,中国进口了一代又一代核技术,试问中国何时才能拥有自己的技术?

如果是朝鲜族没啥关系,朝鲜族和其他少数民族一样都对中华民族共和国有认同感,绝对不是北棒子和南棒子。
 
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Here's an overly simplified explanation. Suppose you burn a big log in the fireplace. After the log produced light and heat from the burning, you decide to reprocess the burnt log. You take a tool (e.g. a chisel) and remove the charred outside. Voila! You can now burn the log again. That's basically reprocessing in a nutshell.

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Nuclear Fuel Cycle

A key to understanding the uranium industry is to first review the nuclear fuel cycle. The nuclear fuel cycle essentially involves the conversion of uranium ore to electricity by processing uranium through various forms and increasing its concentration.

Uranium found in nature consists largely of two isotopes, U235 and U238. The production of energy in nuclear reactors is from the fission or splitting of the U235 atoms, a process which releases energy in the form of heat. Natural uranium contains 0.7% of the U235 isotope. The remaining 99.3% is primarily the U238 isotope that doesn't contribute directly to the fission process. U235 and U238 are chemically identical but differ in their mass. U238 has three additional neutrons. This difference in mass is significant because it allows the U235 and U238 isotopes to be separated and makes it possible to increase or enrich the percentage of U235.

The major stages in the production of nuclear fuel are uranium exploration, mining and milling, refining and conversion, enrichment and fuel fabrication. The diagram below depicts the nuclear fuel cycle.

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According to the WNA, the proportion of the cost of nuclear fuel breaks down by stage of the nuclear fuel cycle as follows: (i) mining - 46%, (ii) conversion - 5%, (iii) enrichment - 36%, (iv) fuel fabrication - 13%. While uranium accounts for approximately 46% of the total cost of the fuel for nuclear generators, it accounts for approximately only 6.5% of the total cost of electricity charged to electricity consumers.

Mining

Before uranium can be turned into a useable fuel source, uranium ore must be mined in one of a variety of ways depending on the characteristics of the deposit. Uranium deposits close to the surface can be recovered using an open pit mining method. Higher-grade, deeper deposits can be mined using conventional underground mining methods. If ground conditions are appropriate, the ore can be mined via in situ leaching, whereby oxidizing agents dissolve the uranium contained within the ore body, and the resulting solution is pumped to the surface for uranium recovery. Historically, the price of uranium has been too low to justify its recovery from mineral processing wastes known as tailings. However, with the increased price of uranium in recent years, it has become economically feasible to process the contents of surface tailings dumps to recover any contained uranium. These dams can be mined with high-pressure water cannons, creating a slurry which is pumped to the processing plant for uranium recovery.

Once the uranium ore or solution has been extracted via one of the above mining methods, it is transferred to a mill for primary refining. Mined ore is ground up and leaching is used to extract the uranium. The uranium is then removed from the leach solution and precipitated, producing concentrates containing 80-90% uranium oxide (U3O8). Uranium oxide (which is also known as yellowcake) is the most commonly priced and sold form of uranium. One tonne of uranium contains 2,600 lbs of U3O8 .

Conversion

U3O8 is typically shipped from the mine site in drums to a conversion facility for refining into uranium trioxide (UO3). The UO3 can then be processed for use in either light water nuclear reactors (LWRs) or in heavy water nuclear reactors (HWRs). In both cases, the uranium must be converted but no enrichment is necessary for the HWRs. Since most of the world's nuclear reactors are currently LWRs and approximately 94% of mined uranium is used in LWRs, the remaining discussion will focus on the fuel cycle for LWRs. The UO3 is further purified and converted into a gaseous uranium hexafluoride commonly referred to as UF6 or ‘‘hex''. Conversion plants are operating commercially in the United States, Canada, France, the United Kingdom and Russia.

Enrichment

The UF6 is then fed into an enrichment facility which increases the proportion of U235 from 0.7% to approximately 3.5 to 5.0%, depending on the specifications of the nuclear reactor for which the uranium is destined. In the enrichment process approximately 85% of the natural uranium feed is rejected as ‘‘depleted uranium'' or ‘‘tails'' (consisting primarily of U238).

As depicted in the table below (based on 2003 OECD and WNA estimates), large commercial enrichment plants are in operation in France, Germany, Netherlands, the United Kingdom, the United States and Russia, with smaller plants elsewhere. The enrichment market is an oligopoly, with four principal companies - Techsnabexport/Rosatom (38%), USEC Inc. (22%), Eurodif/Areva SA (21%) and Urenco Group (14%) - controlling approximately 95% of the global uranium enrichment capacity.

Location of Enrichment Facility Enrichment Process Capacity

(1000kg SWU/annum)
Russia Centrifuge 20,000
France Diffusion 10,800
United States Diffusion 8,000
Germany-Netherlands-UK Centrifuge 5,850
China Mostly Centrifuge 1,300
Japan Centrifuge 900

The capacity of enrichment plants is measured in terms of ‘‘separate work units'' or SWUs. The SWU is a complex unit which is a function of the amount of uranium processed and the degree to which it is enriched and the level of depletion of the remainder. Enrichment accounts for approximately 36% of the cost of nuclear fuel and approximately 5% of the total cost of the electricity generated by a nuclear reactor. Enrichment services are sold in SWUs. Where the price of uranium is relatively low, a customer (such as a utility company) may request that the enrichment facility use more uranium and less SWUs in order to enrich the UF6. Conversely, as the price of uranium rises, SWUs become relatively cheaper and the customer may specify that more SWUs be used and less uranium.

Two main enrichment processes are used on a commercial scale, the gaseous diffusion process and the centrifuge process. At present, the gaseous diffusion process accounts for about 40% of the global uranium enrichment capacity. The diffusion process involves forcing UF6 under pressure through a series of porous membranes or diaphragms. As U235 molecules are lighter than the U238 molecules, they move faster and have a slightly better chance of passing through the pores in the membrane. The UF6 that diffuses through the membrane is thus slightly enriched, while the gas which did not pass through is depleted in U235. This process is repeated many times in a series of diffusion stages called a cascade. The gas must be processed through approximately 1,400 stages in order to obtain a product with a concentration of 3-4% U235.

The centrifuge process is economic at a smaller scale as compared to the diffusion process. It involves the feeding of UF6 gas into a series of vacuum tubes each containing a rotor one to two metres in length and 15-20 cm in diameter. When the rotors are spun rapidly, at 50,0000 to 70,000 rpm, the heavier molecules with U238 increase in concentration towards the cylinder's outer edge. There is a corresponding increase in the concentration of U235 molecules near the centre. These concentration changes are enhanced by inducing gas to circulate axially within the cylinder. The enriched gas forms part of the feed for the next stages while the depleted UF6 gas goes back to the previous stage. Eventually enriched and depleted uranium are drawn from the cascade at the desired assays.

Although the capacity of a single centrifuge is much smaller than that of a single diffusion stage, its capability to separate isotopes is much greater. Centrifuge stages normally consist of a large number of centrifuges in parallel. Such stages are then arranged in cascade similarly to those for diffusion. In the centrifuge process however, the number of stages may be only 10 to 20 instead of a thousand or more for diffusion.

The trend in the enrichment industry is to retire obsolete diffusion plants. As set out in the September 2006 Nuclear Issues Briefing Paper 33 prepared by the Uranium Information Centre, it is estimated that centrifuge enrichment plants will account for approximately 65% of uranium enrichment in 2007 and 96% by 2017.

After Enrichment

The enriched uranium is finally converted by a fabricator and made into fuel pellets (ultimately a sintered ceramic), which are encased in metal tubes to form fuel rods, typically up to four metres in length. A number of fuel rods compose a fuel assembly that is loaded into the nuclear reactor. The complete cycle from exploration for uranium to production of electricity is referred to as the front-end of the nuclear fuel cycle.

Utilities may also purchase uranium through spot and near-term purchases from traders as well as producers. Spot market buying usually calls for delivery within one year rather than multiple year delivery dates. In this regard, traders generally purchase uranium through organizations, such as utilities, that hold excess inventory.

It is important to understand the way in which utilities with nuclear power plants buy their fuel. Instead of buying fuel bundles from the fabricator, the usual approach is for utilities to enter into contracts with various suppliers at each stage of the uranium processing stages. Utilities may purchase a combination of U3O8, UF6, enriched uranium and fabricated fuel pellets. Sellers consist of suppliers at each of the four stages of uranium processing as well as brokers and traders. Depending on the stage at which the uranium product is purchased, the purchasing utility will be responsible for any remaining processing of the uranium required in order to generate the appropriate fuel for its nuclear plant. Although uranium prices have increased considerably during the last few years, many uranium producers are still parties to legacy contracts with purchasers at lower historical prices.

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我是100%的中国人。

I can read that. I am also 100% Han. :cheers:
 
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如果是朝鲜族没啥关系,朝鲜族和其他少数民族一样都对中华民族共和国有认同感,绝对不是北棒子和南棒子。

我也不是朝鲜族,我也不懂思密达语。我对高丽棒子的评价是我建立我对韩国整体工业能力的客观了解上的。或许我高估了高丽棒子(尽管我认为这里大多数人低估了他们),但是我并不是在袒护棒子。我并不欣赏棒子,我绝对不是因为崇拜他们而说那番话的。
 
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Like I said, my intention is not to belittle another country. I only speak the truth and I think it's important that others hear it.

South Korea's nuclear power independence
"May 28, 2008 ... South Korea started its nuclear power program in the 1970s by licensing pressurized water reactor (PWR) technology from US-based Westinghouse..."

South Korean nuclear research programs - Wikipedia, the free encyclopedia
"Although plutonium has uses other than the manufacture of weapons, the United States later insisted that South Korea not attempt to reprocess plutonium in any way. In exchange, the US agreed to transfer reactor technology and give financial assistance to South Korea's nuclear energy program. It was revealed in 2004 that some South Korean scientists continued some studies; for example, in 1983 and 1984 Korea Atomic Energy Research Institute was conducting chemical experiments related to the handling of spent fuel that crossed the reprocessing boundary."

Most nationalists do not like the truth. ROK indeed has many advanced technologies.

But, this tiny country, unlike EU or Japan, is highly dependent on the US, more like a puppet. It is too small to conduct all the technology research including controllable nuclear fusion. South Korean's nuclear technology is based on the help of the US, so severely restrained by the US.:lazy:
 
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很多人确实高估了棒子。别以为他们有个三星就在电子方面很牛逼,其实三星跟富士康差不多,只不过他们还有一点点设计能力,但是核心技术仍然是别人的。2009年在全球最大的18名半导体生产企业中,只有三家韩国企业(Dongbu,三星,MagnaChip),并且三个加起来都没有中芯大。我们默默无闻的宏力半导体和韩国巨头三星的排名不相上下,而在2008年三星却远不如宏利,甚至不如我们最差的华润微电子!半导体生产线可不是一天半天建起来的,每个生产线的投资高达10亿米元,所以三星的突然出现只能归纳为他们合并了一家半导体公司,而并不是他们有独立的技术!在汽车方面我更不想说了,韩国的消费型车辆或许还可以,他们的工程车呢?他们的哪样工程车能跟三一重工的比较?他们的发动机都是日本三菱给他们卖的。所以说,别被表象蒙骗了,我们的技术有很多地方不足但绝对不是棒子能比的。

Foundry model - Wikipedia, the free encyclopedia
 
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我也不是朝鲜族,我也不懂思密达语。我对高丽棒子的评价是我建立我对韩国整体工业能力的客观了解上的。或许我高估了高丽棒子(尽管我认为这里大多数人低估了他们),但是我并不是在袒护棒子。我并不欣赏棒子,我绝对不是因为崇拜他们而说那番话的。

很喜欢你的头像~~~ :smitten:
 
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很多人确实高估了棒子。别以为他们有个三星就在电子方面很牛逼,其实三星跟富士康差不多,只不过他们还有一点点设计能力,但是核心技术仍然是别人的。2009年在全球最大的18名半导体生产企业中,只有三家韩国企业(Dongbu,三星,MagnaChip),并且三个加起来都没有中芯大。我们默默无闻的宏力半导体和韩国巨头三星的排名不相上下,而在2008年三星却远不如宏利,甚至不如我们最差的华润微电子!半导体生产线可不是一天半天建起来的,每个生产线的投资高达10亿米元,所以三星的突然出现只能归纳为他们合并了一家半导体公司,而并不是他们有独立的技术!在汽车方面我更不想说了,韩国的消费型车辆或许还可以,他们的工程车呢?他们的哪样工程车能跟三一重工的比较?他们的发动机都是日本三菱给他们卖的。所以说,别被表象蒙骗了,我们的技术有很多地方不足但绝对不是棒子能比的。

Foundry model - Wikipedia, the free encyclopedia


棒子鼻屎一样大的国家能有多大能耐,还不是它米国干爸爸给的技术。

思密达比小鬼子更无耻,至少小鬼子还是有几把刷子的。

不知道那个“落了好”要多少次才能修成正果。。。。。。
 
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我也不是朝鲜族,我也不懂思密达语。我对高丽棒子的评价是我建立我对韩国整体工业能力的客观了解上的。或许我高估了高丽棒子(尽管我认为这里大多数人低估了他们),但是我并不是在袒护棒子。我并不欣赏棒子,我绝对不是因为崇拜他们而说那番话的。


我尊重韩国人在经济和科技上取得的成就。
毕竟对于一个夹在美中俄日四大国之间的倒霉蛋来说,能得到这种成就已经很了不起了。他们的错误仅仅在于“离天堂太远,离流氓们太近”。

但我受不了韩国那种肆意篡改历史的野蛮行为和疯狂的民族主义思想,这和谦虚内敛中庸的东亚民族传统是格格不入的。

韩国人创造历史,印度人拥抱未来。
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其实这篇文章写得不错,虽然技术含量不高,但其观点却是一针见血。

可惜发到铁血和中华网都别人喷,想不到那里的黄鹅毛还那么多。今天的鹅毛都混到这副惨样,都被土鳖给比下去了,还居然还有人把它当神拜。。。。。。

¶íÂÞ˹¾ü¹¤ÒÑÔ¶Ô¶ÂäºóÓÚÅ·ÃÀÉõÖÁÖйú - º£¾üÂÛ̳ - ÌúѪÉçÇø
 
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其实这篇文章写得不错,虽然技术含量不高,但其观点却是一针见血。

可惜发到铁血和中华网都别人喷,想不到那里的黄鹅毛还那么多。今天的鹅毛都混到这副惨样,都被土鳖给比下去了,还居然还有人把它当神拜。。。。。。

¶íÂÞ˹¾ü¹¤ÒÑÔ¶Ô¶ÂäºóÓÚÅ·ÃÀÉõÖÁÖйú - º£¾üÂÛ̳ - ÌúѪÉçÇø

Hey, guys english please.

BTW: 圣诞节大烟花真好看:lol:
 
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