The Solid State K-capture Generator is a computer controlled system that utilizes the “K-Capture” principle to create electrical energy.
已知K-Capture戒除了巨大的能量,但没有人发现了一种控制能量的方法。K-Capture Generator对此作出,并且可能被证明是发现最伟大的能量之一。
Unshielded, it does emit x-ray particles.
预计原型模型(用于制造)将产生至少50kW的恒定电流,预计在加热到自动关闭电源的温度之前将浪涌和较重的负载处理1至2小时。。如果发生这种情况,则该单位不会受到伤害,但是当单位的温度降至约60°F时,必须重新开始。
大多数美国家庭平均每天5到7 kw。如何ever, a 100% electrically powered house could have peak usage of up to 35kw. With normal power usage, 50kw could handle from three to ten homes, depending on size and peak demand. Very few small commercial operations would ever require more than 50kw to supply their needs, if more power is required an additional unit or units could be added. Each one would operate as a standby unit and supply the required power without losing power as each one began its operation.
One unit measures approximately 2′ x 2′ x 6′ but can also be made smaller by using a different configuration when fitting the component parts together.
On a standard basis, the unit normally supplies 5kw of AC power and 45kw of DC power. This can be altered by the use of external inverters, transformers, etc.
It is estimated that under normal conditions that the fuel used will last over one-million years. However, since it does use other non moving components, it is expected to have malfunctions in such things as computer controls, diodes, capacitors, etc. When this occurs replacement would be required and the unit would have to be restarted.
Starting the unit requires 120 volts and 400 watts The power available is on an “as needed” basis and if all power was shut-off, there would be no harm to the unit.
The theory herein described is used as a power source by creating a radio nuclide by K-capture.
The process to reach this goal is initiated by producing a high intensity ultra-violet burst to cause an irregular condition where the K electrons in lithium isotope-6, creates a condition where K-capture is possible.
The ultra-violet burst is produced with a nitrogen laser. It has been known for some time that a high voltage discharge and high current electric discharge in nitrogen gas will generate a pulse of coherent radiation at 3,371 angstroms. The laser action encounters an electron moving in the discharge, absorbing its energy. The encounter leaves the molecule in an unstable state. It usually falls to a state of lower energy by emitting a photon at 3,371 angstroms.
The photon may encounter other excited molecules causing them to emit their energy in lock step with the encountering photon. The resulting pulse of radiation has twice the energy of each photon. This is laser action.
The process continues as long as there are excited molecules along the path. The process soon stops because when a large number of molecules are excited, they wil1 begin to cascade at random to lower states of energy.
The numbers of molecules at lower 1evels build up rapidly, eventually exceeding those at upper levels and terminating the amplification.
即使有兴奋的分子留下,激光也会迅速变为自身。关闭时间快,通常小于十纳秒。
在氮气中诱导激光作用取决于构建机构,该机构在大约100托的压力下横向通过气体柱横向地瞬间向高电压发送巨大的电子电流。
An appropriate switching mechanism that can handle tens of thousands of amperes within nanoseconds turns out to be quite simple both in principle and in construction.
No laser mirrors are needed, the optical gain of the rapid discharge is so large that the emission becomes super-radiant, that laser action takes place without an optical cavity.
Ultraviolet lasers can be scaled to higher powers. A discharge path one meter long will develop an output pu1se of almost one-million watts. Output is emitted from both ends of the column of excited gas, but a mirror at one end will more than double the power at the other end.
k捕获技术信息
在某些情况下,中子的比率protons is low, a type of decay has been found to exist. Where a proton is converted to a neutron in the nucleus by the capture of one of the extra nuclear electrons, with a neutrino being formed at the same time. The product of this type of radioactivity would have the same number as its parent, but its atomic number would be one unit lower.
The phenomenon described is referred to as a decay by electron capture. The electron is captured usually from the K level, or first quantum level, for such an electron is likely to be found near the nucleus; consequently, the expression K-electron capture, or K-capture is often employed. Instances of an electron being captured from the second quantum level, or L level, is not unknown although they are not common. The possibility of electron capture was predicted by the Japanese mathematical physicists H. Yukawa and S. Sakata in 1936. Proof of its reality was obtained in the United States by L. W. Alvarez in 1938.
k捕获的检测取决于k-电子离开k量子水平的孔的事实。来自较高量级电平的电子将进入填充位置,通过过量的能量作为特征X射线发射。由于K捕获前面先于电子的转变和X射线的发射,因此X射线将是产品核的特性,其具有较少的原子序数。其中的情况是钒同位素-49。发现衰减伴随着钛的K系列的特征X射线。显然,钒-49衰减k捕获。
When a Lithium-6 atom encounters an ultraviolet photon adding enough energy to cause a K-capture, its atomic number is changed and becomes a Helium-6 atom. Helium-6 is a radio nuclide having a beta emission of 3.58 MeV. No other radiation is present except for a characteristic X-ray of Helium.
β颗粒在磁场中捕获并在使用能量工作之前存储在电容器库中。
The number of reactions needed to produce a sizeable current flow is small.
In the terms of energy needs, the usefulness of this process is clear.
Disclaimer:
I did not write this article… I only edited it for clarity. Nor have I seen this device working. However, I did speak with a person at the 1998 Exotic Research Conference from Utah who had claimed to have built this type of device with a few of his associates. This guy stated that they did not know how to convert the x-rays to electricity. He said that the device was very dangerous and hard to control. It was also stated to have wiped out computer hard-drives within a few blocks of the operating device. This posted article seems to answer the conversion problem.
此时我没有其他有关此设备的信息。如果我有时间我会设置这个设备并使用铌酸锂水晶作为目标。我还将使用电极在加热时产生热电效应。如果您中的任何一个有氮激光器,则该设备应容易验证。请与我们其他人分享您的结果。
