dual frequency zapper
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Dual frequency Zapper, published in 2003 EPE magazine, supporting 2.5kHz and 20kHz.
In the issue there is a complex PIC based zapper project with sweeping function and auto-
timer also. Note on this design - by changing the resistor R1 (and removing R2), you can
make selectable many frequencies with several-step switch (for example - choosing
resistor of 12.7K to connect pin 5 with pins 6 and 2 will generate 2.128kHz, 15K =
2.5kHz, 60K = 10kHz and 180K = 30 kHz). Seems one of the best zapper designs outthere. Design by Andy Flind.
MODIFIED ZAPPERS
727Hz Zapper, published at RoyalRife.com, designed by Dr.Gary Gear. It is supposed to
have more stabilized waveform under load thanx to lower frequency (one of the universal
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Rife frequencies) and stabilization with the 10uF tantal capacitor on output.
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MZ4_TN1 :A commercial zapper
Function of each element :
= 7555 : CMOS Integrated Circuit version of the famous 555. Uses very little current for itsown needs. Recommended
= C1 : Makes input more stable and noise free. Any value from 1uF to 100uF, 25V_WV or
more. Not essential.
= C2 : Charge and discharge of this capacitor "makes" the timing of frequency.Around 100pF for 30-32kHz;Around 470pF for 5kHzAround 1000pF for 1.0/2.0/2.5kHzAround 0.1uF for 8 à 20Hz,16V or more.
= If frequency stability is a most for you, use 0.01 to 0.1uF for C3. In zapping mode, thiscapacitor is not essential. Frequency variations can make more "hits" on specific parasites.
= D1 : Protects circuit against battery inversions, but subtract 0.7V on the output voltage.1N4148 or 1N4001 to 1N4004 are good choices.
= LED1 : Use a super bright Led for a minimum consumption. Around 700mcd @ 20mA is agood choice.
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= P1 : Trimpot. Trims output frequency. Multi-turn permits good stability and precision.
= R1 : This resistor is in the path only on the capacitor charge. Any value between 47 and150k.
= R2 : When the trimPot is at its minimal value, this resistor sets the upper frequency limit.Any value between 47 and 150k.
= R3 : Limits LED supply current. This LED current is high when compared to zapperconsumption. 2.2k for a high brightness, 10k for a good compromise.
= R4 : This value gives the output impedance to the zapper. It protects the zapper in case of short circuit and protects the user against a too high current. 1.0k is an excellent value. Othervalues could be between 820 to 3300 ohms.
= R5 : This resistor pulls up the output to about 0.25V when the 555 drops to 0V.
= Copper handholds : Usually copper tube 5/8 outside diameter, 4.5 inches long. (13mm Dia
and 115mm long). Be sure there is no sharp edges or lead solder on the outside.
= Battery : As shown, this circuit can handle any battery from 9 to 12V. In this low currentuse, Super Heavy Duty batteries are good enough.
Electrical & Electronics Engineering projects on 9:34 PM |
A Recent History
By now, the Wart Zapper has quite a history behind it. Three different embodiments have
been published in three major magazines. It has gone into production in South Africa, and
(without my having read the technical details) an embodiment would seem to have gone
into production in the USA. In the latter case, it has been advertised also as a cure for cold
sores. A major company approached me with a view to manufacture. However, the
medical trials and approvals seemed to be too much of a hurdle for me to want to further
pursue that avenue.
The Wart Zapper's record has been good. I have received many letters confirming itsefficacy -- not to speak of the results that I have witnessed first hand. One writer had a
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problem getting his unit to work, and I "walked him through" the problems. He replied: "I
did another set of 'zaps', and wow!! As per the article, about 3 minutes in, a small wart on
my thumb suddenly got quite sore (which I bore with dignity). Et voila!! After about 5
minutes there was a tiny hole burnt in it. This has now formed a hard layer, and I am
confident its wave function has collapsed."
A few people had some difficulty obtaining a result at first. This was always where a wart
was both large and "dry". In one or two cases, the problem was solved by soaking the
wart in the bath, then applying the Wart Zapper. This is also covered below.
Wart Removal
As improbable as it may seem, the common wart may be destroyed with a simple circuit
that uses a small 9V PP3 battery delivering a boosted 25V to the skin. Taking into
account the resistance of the skin, this translates to just 100µA or so passing through the
wart internally, thus delivering a fraction (about one-third) of the peak power delivered by
a typical TENS unit. That is, a typical wart may be destroyed with the power that a pockettorch uses in the blink of an eye.
Warts are one of the most common maladies of humankind, yet are often one of the most
awkward to cure. In the past, warts were removed by means of curettage (that is, cutting
them out), or by burning them off -- sometimes with a hot coal. Often they were simply
left alone. One of the more famous quotes of Oliver Cromwell, Lord Protector of
England, was, "Paint me warts and all, or not at all!" Due to the habit of warts of suddenly
and inexplicably disappearing, it was sometimes thought that charms might effect the
cure.
Today, there are three lines of attack to remove warts:
Perhaps the most common is the dreaded liquid nitrogen treatment (also called
cryosurgery). However, not only is this messy and painful -- it may in many cases
augment the treated warts, or do permanent damage to the skin -- particularly to darker
skin.
Chemical treatment is often a long, slow, messy process which requires perseverence and
care -- and even then, success is not guaranteed. This may also be couter-productive, and
generally cannot be used on the face.
A third method, which is often used in clinics today, is electrodesiccation (or sometimes,
"radio frequency thermal ablation") -- that is, burning off warts electrically with several
Watts of power. This is tidy, quick, and effective, yet it tends to be expensive, and
requires specialist attention. Therefore it is likely to lie beyond the means of people who
live in poorer circumstances, or in more remote areas of the world.
What is significantly new about the circuit shown here is that it brings wart removal
within the scope of every amateur electronics constructor, using some one thousand times
less power than electrodesiccation. For the price of a doctor's consultation for the dreaded
liquid nitrogen treatment, or for the price of a single session of electrodesiccation, several
Wart Zappers could be built.
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The single 9V PP3 battery used by this circuit should be capable of destroying a many
warts. In trials, the Wart Zapper proved to be close to 100% effective for the so-called
common wart, on condition that this was not too large (that is, if it was less than 5mm
across it at its widest point). In particular, the Wart Zapper was very effctive with warts
on the hands, which are often the most difficult to remove by other methods. Larger warts
may by all means be treated, but these may prove to be more awkward to remove.
Medical History
During the 1950's, Dr. John Crane experimented with the treatment of harmful microbes
with electrical pulses. This followed experiments in the 1930's by Dr. Royal Raymond
Rife, who used electromagnetic pulses, which yielded some remarkable results. Dr. Rife's
original interest was in the design of microscopes, and his discovery of the effects of
electromagnetic radiation on microbes came purely by accident as he sought to illuminate
specimens under his ever more powerful microscopes.
In short, Dr. Crane claimed to have established that harmful microbes, if pulsed with asmall current at a specific frequency, will resonate, thus destroying the microbes, while
leaving healthy tissues intact.
Since warts are known to be caused by a group of common viruses, the present design
uses a frequency close to one established by Dr. Crane for the treatment of the "wart
virus" (21.27kHz). This is used here with suitable voltage and current. It has since been
questioned whether Dr. Crane's frequencies are at all significant, or whether any
frequencies within a few hundred or even thousand Hertz would work just as well.
However, Dr. Crane's original frequency it is, with the important difference that it is
applied here directly to a wart, rather than being used as a treatment for the virus.
It is interesting to note that Dr. Crane's frequencies for cancer (sarcoma and carcinoma)
lie close to those for the wart virus. This raises the possibility that the Wart Zapper might
work for certain cancers. In fact it was tested on a less aggressive form of skin cancer
under the eye of a specialist, and it successfully destroyed the cancer. However, the Wart
Zapper would not be recommended in such cases, since one cannot afford to take chances
with personal experiments on cancers.
The Wart Zapper originally came about by accident. I was experimenting with Crane
frequencies to treat a superficial infection that had eluded antibiotics. With a lot of
guesswork as to what voltage or current to apply, the treatment was surprisingly andentirely successful -- yet caused a little damage to the skin. What if, I thought, Dr. Crane's
frequencies would cause similar damage to warts?
My first prototype yielded patchy results, but these were sufficiently hopeful to know that
they were significant. Four successive prototypes were tested on several volunteers,
including medical professionals, with the final prototype achieving close to 100% success
with the common wart (a brown or skin-coloured, rough wart), as well as some success
with other types of wart, such as the plane wart. The Wart Zapper's high success rate does
not of course guarantee that it will work in every case. However, it does offer reason for
hope that the device would be effective in a great many cases.
Note that, although the Wart Zapper was developed on the theories of Dr. John Crane,
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and although I have my own "best guess theory" as to why it works, at least five different
theories have been put forward as to why it works -- see the sidebar.
Safety and Caution
Despite the very small currents used by this circuit, little is understood about the effectsof electricity on the human body, and the Wart Zapper should be used with this caution in
mind.
During experiments, I was surprised by the profound effect that miniscule currents may
have on the human body. When I was still seeking to establish the correct "exposure"
required to destroy a wart, I caused significant damage to a fingernail 7 cm (nearly 3")
distant. Similarly, related devices which are used to treat viral infections have been said
on occasion to cause e.g. stiffness in a finger joint.
These are rare and relatively minor side-effects, yet it should be borne in mind that the
Wart Zapper is capable of doing some damage if misused. Therefore the voltage, current,frequency, and duration of treatment described in this article should not be rashly
modified. More than a year's experimentation, and even more "field experience", lies
behind this design, and most if not all of the mistakes have hopefully been made.
The Circuit
The Wart Zapper uses a single CMOS 7555 oscillator (IC1), for dual purposes, as
follows:
First, it pumps up a standard voltage tripler circuit, represented by the capacitor-diode
network to the right of IC1 in the circuit diagram. This takes the voltage up to about 25V,
if not a little more. The purpose of increasing the voltage is to overcome the resistance of
the skin. According to the well known formula I=V/R, if V (voltage) is increased, while R
(resistance -- in this case skin resistance) remains the same, I (current) increases
proportionately.
Second, the oscillator switches power MOSFET TR1 at the required frequency, to pulse
the raised voltage through the skin by means of two electrodes. One of these electrodes is
positive (+25V -- called the dispersive electrode, and marked D. This may either be a
metal grip held in the hand, or a metal plate applied to a large(ish) area of skin near a
wart. The other electrode is negative (0V -- called the active electrode, and marked A).This is a sharp(ish) metal point which is used for direct contact with the wart. The 470k
potentiometer VR1 is inserted into the dispersive electrode's lead to prevent the
possibility of a brief electrical jolt at switch-on, or on first applying the active electrode to
a wart.
After much experimentation, I settled on a 25V 21kHz square wave (the circuit will
approach this to within about 10%), applied to a wart for five minutes. I found that pulses
of a minimum 1mW power passing through the wart internally were required to achieve
any effect, and that 3mW-6mW pulses were adequate (compare this with the
approximately 2W required to illuminate a pocket torch)!
Current across the probes is limited by R3 to less than 3mA, to protect the circuit if these
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should be short-circuited. One needs also to factor in the conductivity of the flesh, which
rarely falls below about 200k -- therefore little more than 100µA, or at most about
200µA, would course through the wart itself.
Zener diode ZD1, together with LED D1 and resistor R1, serve as a simple "battery low"
indicator. LED D1 will normally glow dimly, and this must be a green LED -- it is chosenfor its so-called forward voltage drop, which differs from that of other coloured LEDs. If
this LED goes out, then the battery is flat, and needs to be replaced. C1 serves as a supply
decoupling capacitor, and S1 as an on-off switch.
Construction
The Wart Zapper (see Fig.2) is built on a printed circuit board (PCB) measuring
approximately 60mm x 44mm (2.5" x 1.8"). The prototype used a case measuring
approximately 100mm x 60mm x 22mm (4" x 2.5" x 1") externally.
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Begin by soldering the six solder pins to the PCB. Solder the four resistors, the six
capacitors (observing the polarity of electrolytic C1), the Zener diode, the five remaining
diodes (including LED D1), and power MOSFET TR1. Then solder the battery leads as
shown. The positive lead is taken via switch S1. Be sure to connect the leads the right
way round, since a mistake here could destroy the circuit.
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Fix the PCB to the bottom of the case, perhaps with some epoxy glue. A hole is prepared
in the case for LED D1, which may be wired directly to the PCB, depending on the layout
of the case. The cathode (k) of D1 is identified with a "flat" on the side of itsencapsulation. Mount on-off switch S1 on the case.
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Attach a long, plastic sheathed wire to the dispersive electrode (a metal grip or metal
plate), and pass this wire through a hole in the case. Make sure that there is sound
electrical contact between the wire and the metal grip or plate. Take the free end of this
wire to 470k potentiometer VR1, and wire the potentiometer to the PCB as shown. If the
potentiometer is viewed from underneath with the terminal pins facing towards you, the
two terminal pins on the right need to be wired to each other.
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Then attach a long, plastic insulated wire to the active electrode (a sharp pin -- but not too
sharp -- the end may be filed flat), and pass this wire through a hole in the case, soldering
it also to the PCB as shown. The pin should be inserted in a suitable plastic shaft so that it
is not directly touched when treating a wart. Finally, insert and solder IC1 on the PCB,
observing anti-static precautions (touch your body to ground before handling, e.g. to a
metal tap).
In Use
Removing warts has never been much fun, and the use of the Wart Zapper is likely to be
painful -- but only briefly, and not too much (as hinted at in the constructor's letter
above).Considerable experimentation preceded the development of this circuit, and, as
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mentioned, the results gave me a new respect for the potential risks of electricity, however
small the voltages and currents that are applied. Skin resistance can vary between about
100k and 10M, depending on the day and the situation. Therefore, to ensure consistency
of results, skin resistance needs to be kept relatively low. Use a little skin moisturiser
where the skin makes contact with the dispersive electrode, as well as a little moisturiser
on the wart itself.Constructors are advised not to use the circuit where current would flow across the head
or the heart, and never during pregnancy, or where a person uses a pacemaker, or has any
history of epilepsy. These are standard safety recommendations for TENS devices, which
incidentally use some three times the peak power of the Wart Zapper.
If treating a wart e.g. on the lower or upper arm, hold a metal grip (the dispersive
electrode) in the same hand. If it is not convenient to use a grip, rest the limb to be treated
(e.g. a foot) on a metal plate instead, which is again connected as the dispersive electrode.
The active electrode -- that is, the sharp(ish) metal point -- is rested directly and gently on
the top of the wart. If treating a slightly larger wart (say more than 4mm at its widest
point), it might be an idea to tackle one or the other side of it first, since the Wart Zapper
is unlikely to kill it all at once.Switch on, apply the Wart Zapper to a wart for up to five minutes (see above), then switch
off. Potentiometer VR1 is used to turn up the power slowly to full after switching on --
however, for the brave, it may be turned up full immediately. Be prepared suddenly to
experience perhaps half a minute of sharp pain. If you do not see this through until the
pain subsides (which it will), the wart may not be destroyed.
Experience and Qualifications
Although most common warts were ultimately removed by the Wart Zapper, it was found
that there were some differences in the effect that the device had.
In several cases, a wart was obliterated first time, never to return. These were usually
small common warts about 2mm to 4mm at their widest point. However, with close
constellations of warts (at first glance looking like a single wart), or with larger warts, the
wart was sometimes destroyed in part, but needed follow-up treatments to destroy it all.
In most cases, little or no pain was experienced when the Wart Zapper was first applied,
although one subject jumped when the device was first switched on, and another -- a
dentist -- suggested a means of controlling the power at switch-on. This is taken care of in
the present design with a potentiometer which the patient may slowly turn up once the so-
called active electrode is resting on the wart. In most cases, however, this potentiometer
would not be missed.
After a certain period of painlessness, which varied from about half a minute to three-and-
a-half minutes, subjects suddenly felt a burning or even a "spine-chilling" pain, inside and
under the wart. This pain only lasts about half a minute, then subsides. However, it isnecessary for the removal of the wart, and needs to be "stuck out". When the pain has
subsided (or after five minutes, whichever may come first), the probe is removed.
Be more careful with facial warts, since facial skin is delicate. Rather under-treat such a
wart than over-treat it. You may always return to it again later.
Once a wart has been treated, it should immediately be apparent that it is "just not the
same". In fact in many cases, the wart melted with a fizzle even before the treatment was
over. The skin immediately surrounding the wart may be irritated for a few hours, and
there may be a slight swelling close to the wart. Ultimately a scab may form. Don't ever
remove a wart too soon, or break its surface, or even agitate it, since this could leave a
deep wound, and there could be infection. If it is left alone, there should be no infection.
If a treatment should have little or no effect, it would be sensible to consult a doctor.While this circuit comes with no guarantees, it is no doubt a case nothing ventured,
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nothing gained! With the help of several willing "guinea-pigs", and further volunteers
queuing up, I found that the Wart Zapper was entirely successful most of the time.
Alternate PCB View
Theory and Practise
According to the original theory of Dr. John Crane, alien cells (such as viruses) begin to
resonate when bombarded with a specific electrical frequency. Normal chemical
processes at the cell boundary are thereby disrupted, or the cell ruptures, thus killing the
cell. Healthy tissues are left almost entirely unscathed.
However, this is not the only theory in the running. By way of a process of elimination, I
followed up further suggestions put to me by researcher Aubrey Scoon:
1. Electrolysis (a "flat" DC voltage). This also did significant damage to warts - however,
it also did immediate, superficial damage to healthy tissues, and the experiment was not
repeated. The conclusion is that electrolysis may contribute to the destruction of warts,
but it does not offer an adequate explanation for the Wart Remover's success.
2. Iontophoresis. This is the leaching of ions into a wart, which effectively kills the wart
by poisoning. However, after experimenting with a variety of conductive electrodes, as
well as graphite (all the electrodes were tried with success), this theory was safely ruled
out.
3. The stimulation of immunomodulatory chemicals. The theory is that these chemicals,
when stimulated by an electrical frequency, attack the wart and destroy it. However, thiswould be hard to explain in light of the spectacular destruction of some warts. In some
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cases, the Wart Eliminator appeared to explode wart cells, and this could on occasion
even be heard! Finally,
4. Frictional heating. Ionic agitation may raise the temperature within a wart, causing
tissue coagulation. While I had no way of testing this theory, I thought it unlikely.
Electrodesiccation typically raises the temperature within a wart above 47°C, and this
requires a few Watts of power. Since the Wart Remover pulses just one-thousandth asmuch power through a wart, this possibility would seem less probable.
Parts List
Qty Part
1 Copper clad board 60mm x 44mm (2.5" x 1.8")
1 9V PP3 "matchbox" battery
1 Battery clip for battery - or suitable case with internal battery terminals
1 Panel mounting on-off switch
1 Suitable ABS plastic case approx. 100mm x 60mm x 22mm (4" x 2.5" x 1") external
1 1 metre (1 yard) plastic shielded wire for the electrodes
1 15 cm (6") long brass tube for the dispersive electrode1 Needle sharp tip filed off - for the active electrode
1 8-pin dual-in-line (DIL) socket (not required for experienced constructors)
6 Solder pins
1 Etchant if a PCB needs to be etched
1 Solder
Semiconductors
1 6.8V Zener diode (¼-Watt is adequate)
1 Green LED (no other colour)
4 1N4148 signal diodes
1 IRF610 power "logic" MOSFET (alternatively IRF510, BUZ11, BUZ22)
1 7555 CMOS timer IC
Resistors
2 1k ¼-Watt carbon or metal film
1 47k ¼-Watt carbon or metal film
1 10k ¼-Watt crbon or metal film
1 470k or 500k potentiometer, carbon track or conductive plastic
1 Knob for potentiometer
Capacitors1 680pF polyester or ceramic
2 100nF polyester or ceramic
2 220nF polyester or ceramic
1 100µF electrolytic 16V or higher
POLICE SIRENThe Police Siren circuit uses two 555's to produce an up-down wailing sound. The first 555 iswired as a low-frequency oscillator to control the VOLTAGE CONTROL pin 5 of the second 555.
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The voltage shift on pin 5 causes the frequency of the second oscillator to rise and
fall.
HEE HAW SIRENBuild the circuit and listen. Change the resistors and capacitors to get all sorts of different results.
Sirena electrónica
Al ensamblar este kit , se obtiene un circuito que produce una señal muy real de sirena
electrónica con un sonido similar al de los automóviles de policía o de las ambulancias.
Esta señal se puede amplificar por medio de una etapa de audio de potencia y así se
logrará una sirena de gran volumen para todo tipo de alarmas.
Teoría de funcionamiento y operación.-
Este circuito tiene como elemento principal un circuito integrado LM556 o 556
simplemente, que internamente está formado por dos 555.
Cada mitad del 556 está conectada como un circuito oscilador o multivibrador astable. El
primer oscilador produce pulsos de muy baja frecuencia, mas o menos 15 por segundo,
debido al alto valor del condensador formado por C2 y C3 en paralelo, 1500 µF en total y
a las resistencias R1 y 12. El segundo oscilador, trabaja a una frecuencia mucho más alta,
mas o menos a 2000 ciclos por segundo, debido a los valores de R3, R4 y al condensador
C5 de 0.01 uF.
La señal de salida del primer oscilador se utiliza para variar la frecuencia del segundo
oscilador produciendo así el efecto de sirena.Este tipo de circuito se denomina Oscilador controlado por voltaje o VCO.
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La salida de este circuito se puede conectar a la entrada de un circuito amplificador de
potencia para lograr un alto volumen.
Lista de materiales1 Circuito integrado LM556
1 Transistor NPN 2N3904 o similar
2 Condensadores cerámicos de 0.01 uf
1 Cond. electrolítico de 470 uf / 16v
1 Cond. electrolítico de 100 uf / 16v
1Cond. electrolítico de.1000 uF / 16v
1 Resistencia de 220 ohm 1/4 w
1 Resistencia de 4.7 Kohm 1/4 w
1 Resistencia de 2.2 Kohm 1/4 w
1 Resistencia de 10 Kohm 1/4 w
1 Resistencia de 100 Kohm 1/4 w
PCB del circuito
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