高压包.rar 585.11KB RAR 50次下载   
tesla.rar 877.67KB RAR 82次下载

上面资料为论坛已有资料
为flyback driver & teslacoil 电路
下面请注明
并且图片格式的尽量贴出 不要发成压缩包形式

低压供电
注明：此为boost升压电路 不是高频加热 不要搞错了

高频加热

LM331参数计算器.rar 59.40KB RAR 40次下载
电子表格 格式 很好用

几个无线输电的实验：










相关PCB制作资料和电路图等：

project.rar 493.04KB RAR 45次下载

早就有成品了，我都一大堆了！手机充电的。

我觉的利用特斯拉的性质做传送或许更好些。。 [s:251]

具体的参数有吗?? [s:251]

更像是通过电磁感应而非电磁波实现能量传输

电路和效果图均有，效果不说了，肯定是看的大伙口水流。

电源是110V，功率管用MOS 比较好。

电路简单，555驱动。







    

电路图：

嗯？！有机会试试看！

[s:253] 这么小就有这么长的弧。。。

這不是自激的么。。。�丨

体积好小啊……

IGBT的型号呢....  随便都行?
左边那个电感是和初级在一起的反馈线圈么? 开路偶合??

第一感觉--这么长 ！！[s:108]
第二感觉--这么小？？？？

粘贴的外国技术文档，我就不翻译了，大家可以去看看，就是利用线圈输出高压后再继续谐振。

基本就是一次TC 输出比较连续的功率强劲的电弧，二次线圈把这个电弧继续谐振变成更高的高压。

什么是放大镜成功的关键地方：

What Are The Keys To Magnifier Success?
Power Conditioning
Input power must be conditioned in any magnifier using non-shunted transformers! The simple neon sign transformer can be used as is and requires no conditioning. This would place an upper limit on non-conditioned AC line power of under two kilowatts. We found these smaller magnifier systems were superb concept demonstrators, but the same power in the hands of an expert two coil builder could yield almost equivilant results. The magnifier really comes into its own at powers over two kilowatts! The best transformers are large potential transformers or small distribution transformers under 15KVA rating. We found the best control of the input energy was secured by mixing both resistive and inductive ballast in series with the power transorfmers primary winding. The resistance is often well under 1 ohm and the inductance under 5 milliHenries. These values are typical and will vary from system to system.
Without power conditioning, the main transformer will saturate and power will be wasted. If pure inductance is used, a see-saw action of the transformer and ballast can result in some frightening current exchanges between the two and uneven operation will result. Using only resistive ballasting, a large amount of energy is lost in heat. With a ballance of the two, energy is saved, smooth operation is secured, and very long run times are possible at high powers.

Input Voltage
Only one rule applies here. The voltage must be as high as possible!!! Watch it though, many new and unfamiliar problems occur above 20, 000 volts. Corona and flashovers become a real system gremlin. The average coiler has little experience in this area and new techniques must be developed, not to mention the expense of extremely high voltage pulse capacitors. Tesla never ran his large systems with voltages over 20,000 olts more than enough times to destroy bottles within his capacitors and realize his materials were not up to the task. This is verified in the Colorado Springs Notes. Do not let anyone tell you differently. With reduced capacitance he could experiment above 30,000 volts, but shunned the practice. The desirablity of such high input voltages will become apparent with the discussion of the driver system.
Spark Gap
A crucial component in a working magnifier is the spark gap system. Tesla's gap system in Colorado was very poor indeed and just barely sufficed for experimental purposes. He had trouble with it at the elevated input voltages during a few experiments. The Corums have led the way here, in that they tell us that the spark gap must quench in some tens of microseconds. This is beyond the casual coiler's gap inventory. Special gap construction is a must!
The secret is to not strain the gap. Break the arc up into as many individual arcs as possible to spread the energy out evenly over as many surfaces as possible. Also include a rotary in series the chain somewhere. This is done to give a precisely controlled break rate and dwell period.
Any series gaps must be either vacuum or compressed air cooled within plenums. We have designed a special series arc rotary quench gap that can actually quench faster than required (also a bad condition). It is all in the operation and handling of the arc that the magnifier really sings. This is where the casual coiler is separated from the experimentalist. The gap is the bottleneck in any magnifier system.

Primary Tank Circuit
We tried many different primary tank circuit configurations and found Tesla's original Colorado Springs circuit to be the best operationally, but the most difficult to balance and adjust, (see figure 2). Tesla really knew his stuff.
The spark gap shouls appear acros the power transformer's high voltage secondary and two absolutely matched and balanced capacitors should then be placed in the tank circuit connecting each side of the gap to the primary leads. Due to the critical need for tight coupling and conveying rapid rise time energy pulses to the primary coil, very short, fat low inductance connections must be used throughout. Tesla was forced to use a regulating coil to tune his primary tank circuit. This was terribly ruinous to his efficiency but was unavoidable with his physical configuration. You must not use such a device!!!!
In smaller systems, we use a number of easily accessable turns, so tune and tap directly to the primary turns. Tesla's primary turns were one or two turns fully insulated and were neither accessable nor tappable. He paid a terrible price in reduced coupling coefficients as he allowed more off axis inductance to creep into his system. Fully, as much as 40% of his energy was lost in some experiments due to this one factor. Tesla commented that the system ran best with all turns "out" in the regulated coil. I don't doubt it one bit either.
The capacitors used for this work must be pulse types and have the lowest possible internal inductances so as not to rob system energies by creating off axis inductance or dissipating energy in the dielectric. We have termed Tesla's tank circuit "the Tesla equidrive circuit". One must be capacitor rich in order to tune the circuit over a broad range with capacitance. Telsa was able to do this over a limited range in 1899 by adjusting the number of bottles in one tank on each side of his capacitor bank. The modern amateur is best advised to to tap the primary coil directly. Naturally, all of the classic primary tank circuits will work but the equidrive circuit seems to yield the most power.
There is grave danger in this circuit! The series capacitors pose a life threatening hazard after power shutdown. There is a good chance, depending upon the point during the AC cycle when power was removed, that the capacitors will retain a dangerous charge. If this circuit is used, do not tune or thouch the primary circuit until both capacitors have been discharged!


下面是我粘贴的一个非常技术的正文：
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....

谐振参数？

这个假如换成半桥，没有问题吧？

电弧的长度令人难以置信，这个有多大功率啊？

引用第10楼joyeep于2010-03-11 23:39发表的 来自日本的推挽式特斯拉线圈（小体积，大输出） :
电路和效果图均有，效果不说了，肯定是看的大伙口水流。

电源是110V，功率管用MOS 比较好。

电路简单，555驱动。
.......

好多参数都没告诉啊..比如那个驱动IGBT的变压器、IGBT型号、初次级的匝数等..

發現..10L的圖和电路不對...圖是6P45S 1kW VTTC..

引用第10楼joyeep于2010-03-11 23:39发表的 来自日本的推挽式特斯拉线圈（小体积，大输出） :
电路和效果图均有，效果不说了，肯定是看的大伙口水流。

电源是110V，功率管用MOS 比较好。

电路简单，555驱动。
.......

这个是VTTC..
XXXXXXXXXXXXXX/e107_plugins/forum/forum_XXXXXXXXXXXXp?61788

引用第23楼小特斯拉圈圈于2010-04-15 21:26发表的 Re:来自日本的推挽式特斯拉线圈（小体积，大输出） :

这个是VTTC..
XXXXXXXXXXXXXX/e107_plugins/forum/forum_XXXXXXXXXXXXp?61788

感谢你给出了原帖地址，之前我也是觉得郁闷，怎么有那么长的效果，
我被小日本的网站骗了!

爆炸磁压缩发生器



里面有发生器的模型，可以参考一下
爆炸磁通量压缩发生器金属管爆炸试验研究.pdf 276.42KB PDF 101次下载 预览

螺旋形爆炸磁压缩发生器.pdf 198.96KB PDF 166次下载 预览

恩…看来是有人看的…就是没人回而已…以后继续上

发个高压包驱动电路图，要是电路图有问题请帮助指出来，顺便问一下，这电路的震荡频率是多少？

这个电流和电子变压器的电路差不多,是靠触发二极管来完成开关的,这个电路有几个不太好的地方
1.工作频率不高,而且可调范围不大
2.输出如果开路有可能会烧驱动管
3.输出如果短路,一定会烧驱动管
4.会产生很大的全波段频率的干扰,要放在铁盒子里面,这样可以减少点干扰
5.虽然这个功率可以轻轻松松做到100W-200W,但是驱动高压包的效率不高(至少我试验的结果是这样的),击穿
空气达不到2cm,一般就1cm左右,而且拉狐也很短,同样的高压包,只能555或者3525全效果一半都不到.
6.这个是直接接220的,安全上存在风险

建议改用其他的开关电源电路,或者还是老老实实的555或者494或者3525

好好的他激不用,偏要用自激....

半桥自激，效率很高的。

节能灯，莹红灯电子变压器，高压卤素灯（部分）
超高频无极灯电子变压器 等


甚至液晶的背光也是自激推挽。

谁说自激效率就低？只是功率做不大而已。
半桥自激的最大可以做到几百W。

TL494+全桥再谐振、、很霸气的。
12V开关电源输入下拉弧可以达到7cm。
但是谐振回路电流巨大。
我的两个全桥就是这么被烧糊的、、、 [s:261]

弄了4颗G80N60，准备搞个全桥的IGBT驱动器。。

还是在没有追频的情况下、、
加上自动追频效果可能更明显。

这点路为什么一拉弧，管子就容易发热啊？

这是我手上的一个120W的，输出12V，可以直接接高压包，但是驱动效果不好。
从波形上来看，都不知道算什么波了。所以，这个电路应该不能获得很好的效果。
  

另外，你可以串个灯泡在你的220，你拉狐的时候就可以看到灯泡慢慢的亮起来，所以，输出效率
还是很高的，空载的时候基本上不怎么消耗功率（可以空载的电路），但是这样的电路没用什么保护
措施，你拉狐不小心很容易就烧驱动管子的。切忌！！！

https://www.kechuang.org/t/25883
这是我这电路做出来的效果。
下面有倍压后的效果、

谁有二手的频率计或示波器啊？俺想搞一个。

你在哪里的啊,这个东西比较重运输也不太方便哦.

俺在宁波，一直渴望有个示波器，可是被它价格吓到

二手的不贵也就200-300,但是运费就贵了,而且还容易搞坏,宁波的可以去上海或者杭州看看,应该很多的了.
我的就是二手的200多一个.20M的,用起来还不错.

引用第2楼nhlijiaming于2010-06-04 14:08发表的  :
好好的他激不用,偏要用自激....

自激多有爱……

名字超酷啊！！

强放电路，可用于驱动特斯拉线圈，，，，，，，用处多多，不要胡乱实验哦，干扰附近所有电器，造成火灾，呵呵........................................................................

这个不是无线输电的电路么？

电压电容电阻电流所有参数都没有啊

.....自激?

没一点参数，有能力的自己慢慢计算吧。

看起来和ZVS差不多啊。

电压电容电阻电流所有参数都没有啊 以知 IRF540 SK104 [s:245]

引用楼主a13894945099于2010-06-19 20:15发表的 发个强放电路，可用于驱动特斯拉线圈， :
强放电路，可用于驱动特斯拉线圈，，，，，，，用处多多，不要胡乱实验哦，干扰附近所有电器，造成火灾，呵呵........................................................................

使用较小的工作电压，必须增加R2和R3。振荡开始上的压降R2的响应。 R3的达到了MOSFET的thresold电压，约。 4 ..至6V

电容器，特别是C1应低ESR ，不然他们将会升温很快，

R1 ，R4 100,000

R2， R3-27K

C4，C5100u 高频电容

C1选择您想要的频率

C2 ，C3-10 ％的C1

D1 ， D2-15V Z型二极管


PushPull振荡器需要一个线圈的中心抽头。对于我的测试中我用12打开1毫米铜线，直径约40毫米频率范围从200kHz至10MHz时生成使用此线圈,

高频变压器的不良分析.pdf 376.26KB PDF 629次下载 预览
高频逆变器中高频变压器的绕制方法.doc 29.50KB DOC 93次下载   XXXXXXXXXXXXXXXXXXXXXXXX/XXXXXXXXXml



还有很多NB资料自个去看！