Peter Davey -- Sonic Resonance Boiler


![](0logo.gif) **[rexresearch.com](../index.htm)**

---



**Peter DAVEY**

**Sonic Resonance Boiler**



---

  
![](peter-davey.jpg) 

[**http://www.merlib.org**](http://www.merlib.org)  
[**http://multimedia.stuff.co.nz/thepress/sonic/**](http://multimedia.stuff.co.nz/thepress/sonic/)  
***The Press*  ( 30 January 2008 )**

**Peter Davey, 92-Year Old Sax-Player Uses
Resonance to Boil Water Inexpensively.**

**by**   
**Yvonne Martin**

HOT PROSPECT: Peter Davey, a 92-year-old Christchurch inventor
and saxophone player, says he has used his love of music to come
up with a device that boils water rapidly, in just the amount
required.

Inventor and saxophone player Peter Davey has come up with a
device that he claims boils water in no time.

He calls it the "sonic boiler" because he claims it uses the
power of sound. How the heater actually works has confounded
experts.

The device looks oddly like a bent desk lamp, with a metallic
ball at the end instead of a lightbulb. When plugged into the
power supply, and the ball is lowered into water, it boils the
liquid within seconds -- even as little as a tablespoonful.

"Everybody boils twice the amount of water they need so I
decided I would find a way to boil water and make steam more
economically," said Davey, a former Spitfire pilot.

"This boils exactly what you want to drink."

Davey, who lives in a tumbledown two-storey historic homestead
called Locksley in Dallington, has been using the boiler to make
hot drinks for 30 years.

He said he first came up with the concept 50 years ago and it
took him half of those years to figure out how to make the
device.

"The principle is beautiful. I have cashed in on a natural
phenomenon and it's all about music," he said.

"If I hadn't been playing the saxophone, I probably wouldn't
have come up with the idea."

Davey noticed as he played the saxophone at home that
everything resonated at a different frequency.

"The glasses will tinkle on one note. Knives and forks in the
drawer will tinkle on another note and I realised that
everything has its point of vibration," he said. "In the same
way, a component in the ball is tuned to a certain frequency."

Davey said it took years of trial and error to get the device
to where it is now. He has made a number of prototypes using the
same principle, including a steamer.

Friends dropping by over the years have urged Davey to make
them a sonic boiler and that got him thinking commercially.

Davey, who turns 92 today, is now looking for a manufacturer
who will buy the technology and make the devices for the mass
market.

"Nowadays, with the economy of water and electricity, I think
it could be even more important than when I conceived the idea,"
he said. "They could sell a million of the things in China."

Davey estimated boilers could be made as cheaply as $9 each. He
could imagine cafes using them as a gimmick to make express tea
and coffee.

"I cannot wait to explain the principle to somebody who wants
to take it on," he said.

The Press invited a retired Canterbury University engineer,
Professor Arthur Williamson, to look at the boiler and he was
stumped.

He watched Davey boil various quantities of water, took notes
of the energy used and temperatures reached. He left scratching
his head.

"I don't know enough about sound to know whether you can
transfer that amount of energy via soundwaves. I doubt it," said
Williamson.

He did remember an alternative kettle years ago that had two
perforated metal plates inside. The power ran between the
plates, through the water. "The resistance through the water
provided the load. I wonder if it isn't working like that?
Without taking it to bits, you can't tell."

The kettle was specially designed to prevent people getting a
shock from touching the boiling water.

Williamson's verdict of the sonic boiler? "It is an interesting
gimmick, irrespective of how it works. I would probably buy one
as a gimmick. I think more homework needs to be done."

Also queuing up for a boiler, after first seeing one in the
1960s, is Stu Buchanan, leader of the Garden City Big Band and a
friend of Davey.

"It's rather spectacular. I don't know why it has never taken
off as a utensil for people. I think it's a class act," said
Buchanan.

Davey was born in Hamilton in 1916. During World War 2 he flew
Spitfires for the 602 City of Glasgow Squadron of the Royal
Auxiliary Air Force. The squadron operated along the south coast
of England, escorting bombers to Holland and Belgium, doing
convoy patrols and fighter sweeps into France.

After the war's end he married and had two children. He bought
Locksley in 1964. Davey shares the top storey of the homestead
with his 55-year-old son, also called Peter, and a grey tabby
cat called Santa. The ground floor is let to lodgers who help
pay the bills.

**Video:**  [**http://video.google.com/videoplay?docid=-1527526922275986120&hl=en**](http://video.google.com/videoplay?docid=-1527526922275986120&hl=en)

![](davey_2008.jpg)

---

[**http://dansdata.blogsome.com/2008/01/31/revolutionary-sonic-boiler-probably-not-a-scam/**](http://dansdata.blogsome.com/2008/01/31/revolutionary-sonic-boiler-probably-not-a-scam/)  
( January 31, 2008 )

**Revolutionary Sonic Boiler Probably Not A
Scam!**

Well, we dont really know how quickly Peter Daveys sonic
boiler is supposed to be working. The article says it boils the
water within seconds, which is a bit of a fuzzy definition.
Id like to see exactly how fast it actually does boil it.

And if you want to transfer energy to a liquid, hitting the
resonant frequency of that amount of liquid in that container is
actually not a good way to do it. Thatll just spray water up
the walls. And talk of resonances is of course practically
diagnostic of crackpottery.

But, making the usual allowances for scientific illiteracy in
the popular press, its possible that someone could have come up
with a way to dump energy into water faster than your normal
immersed heating element can do it.

Immersed elements are already pretty darn good, though.

The 2200-2400W electric jug in my kitchen will bring half a
litre of water to a good enthusiastic boil in about eighty
seconds, and it draws as much power as you can get from the
maximum ten-amp-per-socket current rating of 220-240V countries
like Australia and New Zealand, where this inventor resides.

The sonic boiler could be running at 15 amps or more, but
thats cheating; 15-amp sockets are special equipment (used for
things like air conditioners), and anybody can boil tons of
water in half a second if theyre allowed to use as much
electricity as they like.

About 500ml is the minimum amount you can put in most electric
jugs without leaving some of the heating element hanging in the
air to overheat. Its also two mugs worth of liquid. So, as
Peter Davey says, people certainly do often boil more water than
they need. But making an electric jug of conventional design
that can heat one mug worth of liquid is not a great engineering
challenge. Lets do the sums and see how fast such a jug could
perform, in Physics Experiment Land where pulleys have no
friction and cows are spherical.

The (physics, rather than dietary) calorie is the amount of
thermal energy necessary to raise the temperature of one gram of
water by one Celsius degree. So if you start with 250
millilitres of water at 25 degC (which means almost exactly 250
grams of it) and need to raise it all to 100 degC, you need
75\*250=18,750 calories, which is 78,450 joules.

A joule is a watt-second. So if youve got a 2400-watt heater
that transfers heat with perfect efficiency to water, you must
run it for 32.7 seconds to do this job.

Taking that into account, my electric jug is, clearly, not that
far from the theoretical maximum water-heating efficiency.

Assuming its element could be fully submerged in only 250ml of
water, that water would boil in about forty seconds, which is
only 1.22 times the Physics Experiment Land time for the job.

Given that the element has to heat up from the inside out, and
that some energy is lost through the walls of the jug, and that
some more is lost to internal evaporation and sound and so on,
this electric jug is clearly working about as well as it even
theoretically could, when you take real-world limitations into
account. Some other 2400-watt heater, built in such a way as to
be less limited, could only possibly do the job in 82% of the
time, unless it was magically getting energy from nowhere. And
Peter Davey does not appear to be making any such claims.

(Im also assuming that hes not cheating by pre-heating the
boiler before its dipped in the water. Its not hard to boil
water instantly if you drop a red-hot rock in it.)

So I say good luck to this bloke. He may well have come up with
a genuinely new and interesting heater element design, which may
have advantages over existing bare immersible heaters, which are
generally rather dangerous things. And his heater may work very
nicely with even small amounts of water, which in itself is a
step forward; you can get electric kettles with the element
built into the baseplate which work with arbitrarily small
amounts of water, but they take longer to heat up in the first
place because of all the extra metal around the element. There
may indeed be a niche for this sonic heater, if it performs as
advertised.

But there aint no such thing as a free lunch. If the sonic
heater works very much faster, in seconds-per-gram terms, than
any old discount-store electric jug, then its another perpetual
motion machine, which would have a few applications beyond just
making a quick cup of tea.

**9 Comments >>**

1. Technically, you could change the pressure of the water to
make it boil at a lower temperature. Thats cheating, though.
(This actually might be how the device works; it also gives a
reason for the talk of resonance.)

Comment by evilmrhenry  January 31, 2008 @ 7:24 pm   
2. Well, the picture doesnt give any indication of a pressure
vessel, and a device that lowered the air pressure in an
unsealed container filled with water would act as a straw and
draw the water out.

The thing about resonance is that its main useful property in
an application such as this would be to transmit mechanical
energy- and given that converting electrical energy to
mechanical energy is not as efficient as converting electrical
energy to thermal energy, then even if your
mechanical->thermal conversion is 100% efficient, youve used
more energy than you would if you converted electrical energy
directly to thermal energy, which is bloody close to 100%
efficient as it is.

Unless theres something weird like sonoluminescence going on
(possible I guess) I cant see how this is more effective than
an straight resistive element job.

Comment by dabrett  January 31, 2008 @ 9:07 pm   
3.  Out of curiosity whats the energy coupling like of a
microwave oven? Does a 1000W microwave heat up water as fast as
a 1000W kettle would? Im assuming that the 1000W lable is the
power available within the cooking area, as the magnatron is
hardly 100% efficient.

Comment by jaws\_au  January 31, 2008 @ 10:46 pm   
4. About your water heating mathbeen along time since I was in
high school chemistry, but isnt getting water to the boiling
temperature the easy part of boiling? I seem to recall that
theres a transition energy you need to pump in to actually
make the transition from very hot water to steam.

Comment by opus7600  February 1, 2008 @ 12:31 am   
5.  I wonder if this device includes one of those
ultrasonic transducers that atomize water like those cool mist
vaporizers. You turn it on and the water immediately starts
bubbling and you get a mist out of it. The water isnt getting
any warmer, but you get the illusion of boiling. The fact that
the inventor is using his bare hands to hold the glass of
boiling water gives me pause. Even though glass is, in general,
a good insulator, it isnt that good.

So, take the ultrasonic transducer out of a vaporizer, add a
traditional resistive heating element, and you get a device that
makes water appear to boil right away, and you can stall any
skeptics until the regular heating element actually heats the
water.

One other thought came to mind: a small-scale reverse-cycle air
conditioner, which has been mentioned by Dan on several
occasions. Assuming you could get the dimensions of such a
device small enough, you could put a whole lot more power into
the water than just the energy from the wall socket.

Comment by Mohonri  February 1, 2008 @ 1:15 am   
6.  You can see in the picture that the person just out of
the shot is holding a temp probe in the water. So I doubt hed
be fooled by simulated boiling.

Comment by Jax184  February 1, 2008 @ 8:03 am   
7.  Well, he does mention sonics and heat pumps are great
for cheating thermodynamics - maybe he has built a very small
thermoacoustic heater. If you squint hard enough that bulb might
even be a Helmholtz resonator - although I am not sure that such
would be useful in this application.

 If the device is a mini-heat pump (rather than an
immersion heating element that does not need to be fully
submerged) then that is a terrific achievement - whatever the
technology.

 Comment by aLUNZ  February 1, 2008 @ 1:16 pm   
  8.  Actually, no this is not really that new. This
technology and immersion ultrasound horns/plates/cups are
already used by many researchers in the fields of
chemistry/physics/health. However, it will never be used for
this reason, there is no way. Look up Sonochemistry in google.
Back to the drawingboard or your day job. Interesting but bad
idea.

 Comment by Sonochemist  February 2, 2008 @ 12:07 pm   
  9.  Oh I forgot to add.Depending on the frequency
the temperature of the bulk solution and the temperature of the
solution during ultrasound could be different. Also, it doesnt
take much energy to get the boiling effect you see when
ultrasound is induced on an aqueous medium. Less than 10W.

---



![](14_k08_3.gif)

[**http://www.keelynet.com**](http://www.keelynet.com)  
Esa Ruoho ( February 3, 2008 )

**More on the Sonic Boiler**

The photos shown to date reminded me of a website I found a
couple of years ago describing a similar thing. Here are my
notes from that find;

"As a sensitive musician Mr Davey noticed, that there was such
a frequency of the motor and propeller buzzing, when the
aeroplane cabin and his body were getting into a resonance. At
this unique resonance frequency he always was experiencing an
influx of heat in his aeroplane cabin. He did not know yet, that
in future this phenomenon will be utilised in ultrasonic weapon
systems for effective and undetected killing of people. But he
decided to test whether the same phenomenon is to appear, if a
metal hemisphere which simulates his pilot cabin is submerged in
water and is excited into a resonance frequency. So he found two
tops from old bicycle bells, joined them together, tuned one of
them to 50 Hz frequency, attached electricity wire to each one
of them, and thrown them into water. Surprisingly, water started
to boil extremely fast. So he made his first heater patent based
on this observation. This patent was already registered in 1944.
After a hero return from the war, he had a device, which
repetitively proved to everyone who measured it, that it has the
efficiency decisively exceeding 100%. Realising this, he
believed that the world is going to pounce on the opportunity of
production and use of this technical miracle. After all, people
are full of declarations about apparent saving on energy,
resources, about protection of our natural environment, etc.
However, the reality turned out to be completely opposite.
Immediately after it was experimentally confirmed that the
device has unexplainably high efficiency, the heater and the
inventor fell into disfavour of various institutions that are
interested in selling electricity and that protect the monopoly
on electrical power. In the result, this extraordinary invention
received an extraordinary treatment! Namely authorities were
doing everything in their powers to disallow the production and
sale of this heater in New Zealand. One of legal tricks that
were used against this heater, was that it was declared
officially to be "unsafe to health and life of users". (Please
notice that practically every electrical device working on 220
Volts can be declared unsafe, if someone in the position of
authority wishes to put it down.) In turn in New Zealand it is
impossible to undertake the production and sale of anything,
that is not officially approved by the government. In the
result, Mr Davey was fighting for almost 50 years to receive a
permit for the industrial production of this heater. And during
these almost 50 years, the permission was continually refused to
him, no matter what research outcomes he submitted to please
authorities, and no matter how hard he tried. But it is
interesting, that in Australia an electric jug with a heating
element of the design very similar to the Daveys heater was put
in mass production (this Australian jug most probably is
produced in there still even today). This Australian jug is
working on the principle of electrical resistance of water (i.e.
not telekinesis as the heater of Mr Davey does). Water that it
heats is a resistor, in which heat is generated because of the
electric current flows through this water. This Australian jug
is exactly the same "dangerous to the health and lives", like
the telekinetic heater of Mr Davey. Only that it did not
encountered in Australia similar bureaucratic resistance because
the energy efficiency of it is "normal". When I met Mr Davey for
the first time in 1990, he still was appealing to authorities,
and still had a hope to receive a permit for the production of
his heater - in spite of these almost 50 years of lost battles
with bureaucrats. He was even showing to me a large stock of
components he gathered to start a production immediately after
the permit is granted to him. However, he gave up the
experimental production of research copies of his heater.

The design of the Davey's sonic heater is extremely simple. It
actually is composed of two major parts only - see Figure K8 (3)
from monograph [1/4]. The most important out of these two parts
is a resonating hemispherical bowl (1) made of a sound inducing
metal plate. The second part is a buffering hemispherical bowl
(2) almost identical in shape to the bowl (1). This second bowl
has the radius around 4 mm larger than the resonating
hemispherical bowl (1). Both bowls are assembled symmetrically
one around the other, means the hemispherical bowl (1) is placed
inside of the hemispherical bowl (2). Coin is 32 mm wide =
1.25984 inches / Big bowl approximately 1.75 inches wide and .75
inches thick / Small bowl approximately 1 3/8 inches wide. Of
course, apart from these two bowls, the heater also includes a
long rod, nuts, washers, and electrical wires. These are to hold
it together, to supply electricity to both bowls, and to allow
the heater to be submerged into water that it heats. But these
other parts are marginal additions only. The major parts are the
bowls. During experimental production of this heater, the
resonating hemispherical bowl (1) usually is made from an old
cover for a bicycle bell. The dimensions of this hemispherical
bowl are not important. It is only vital that it falls into a
sonic resonance at the frequency of 50 Hertz, and that it has
the outer surface which is parallel and equidistant from the
external buffering hemispherical bowl (2). To each of these two
bowls a different wire of the household electricity supply (i.e.
220 V, 50 Hz) is connected. The heater must be submerged in
water that it heat. It brings water to the boiling point
extremely fast. More details about the design and operation of
this sonic heater is provided in subsection K3.3 from volume 10
of monograph [1/4]. After being constructed, the Davey's
telekinetic heater must be "tuned" in two different manners. The
first tuning depends on providing the hemispherical bowl (1)
with such frequency of the own oscillations, that makes this
bowl to resonate acoustically when a sound of the frequency 50
Hertz is emitted nearby. The second tuning of the heater depends
on appropriate selecting the distance "L" between both bowls (1)
and (2). On this distance depends the formation of the standing
wave between both bowls. Thus it decides about the energy
efficiency of the entire heater. From the information that the
inventor repeated to me, I gather that the measurements carried
out by New Zealand scientists suggested that this heater may
consume even less than the equivalent for around 5% of the
energy that it generates in form of heat. This would indicate,
that the electrical efficiency of this heater is around 2000%.

---



![](boilingwaterwithsound.jpg)  
![](boiling.jpg)![](welding.jpg)![](boilingwaterwithsound_54.jpg)![](sonic_boiler_232_300108.jpg)

---

[**http://www.totalizm.nazwa.pl/boiler.htm**](http://www.totalizm.nazwa.pl/boiler.htm)

**Shocking History of Revolutionary
Boilers...**

The design of the Davey's telekinetic heater is extremely
simple. It actually is composed of only two major parts - see
"Fig. #B2" below, or see "Fig. K8 (3)" from monograph [1/4]. The
most important out of these two parts is a resonating
hemispherical bowl (1) made of a sound inducing metal plate -
the inventor always uses stainless steel bowl. The second part
is a buffering hemispherical bowl (2) - almost identical in
shape to the bowl (1). This second bawl has the radius around 4
mm larger than the resonating hemispherical bowl (1). Both bowls
are assembled symmetrically one around the other, means the
hemispherical bowl (1) is placed inside of the hemispherical
bowl (2). Of course, apart from these two bowls, the heater also
includes a long pipe (8) which holds remaining parts together,
two nuts (5) and (3) which fix both bowls in their proper
locations, a washer (4) which allows to regulate the mutual
distance "L" between both bowls, and electrical wires (6) and
(7) which supply electricity to both bowls and allow the heater
to be submerged into water that it heats. But these other parts
are marginal additions only. The major parts are the bowls.
During experimental production of this heater, the resonating
hemispherical bowl (1) usually is made from an old cover for a
bicycle bell. The dimensions of this hemispherical bowl are not
important. It is only vital that it falls into a sonic resonance
at the frequency of 50 Hertz, and that it has the outer surface
which is parallel and equidistant from the external buffering
hemispherical bowl (2). To each of these two bowls a different
wire of the household electricity supply (i.e. 220 V, 50 Hz) is
connected. The heater must be submerged in water that it heats.
It brings water to the boiling point extremely fast. More
details about the design and operation of this telekinetic
heater is provided in subsection K3.3 from volume 10 of
monograph [1/4].

**Tuning of the heater:**

       After being constructed,
the Davey's telekinetic heater must be "tuned" in two different
manners. The first tuning depends on providing the hemispherical
bowl (1) with such frequency of the own oscillations, that makes
this bowl to resonate acoustically when a sound of the frequency
50 Hertz is emitted nearby. The second tuning of the heater
depends on appropriate selecting the distance "L" between both
bowls (1) and (2). On this distance depends the formation of the
standing wave between both bowls. Thus it decides about the
energy efficiency of the entire heater.

---

  

**George Wiseman re : Dumas Effect**

  
**From: Jerry Decker <jdecker@keelynet.com>**   
To: Interact <keelynet\_interact@yahoogroups.com>  
Subject: George Wiseman on the Dumas Effect  
Date: Mar 10, 2015  
  
Hola Folks!  
  
George Wiseman is an expert on HHO and has done many
fascinating  experiments, many documented at his
www.eagle-research.com website. I sent him the DUMAS info and he
shares this;  
  
Jerry,  
  
I independently discovered what you are calling the Dumas Effect
(I'm calling it the Wise Heater) in the early 1990's when I was
trying to find a method to split water without using electrolyte
(using pure water).  
  
I danced for joy when I started making copious volumes of gas
with little electricity... But I noticed that the little jar I
was experimenting with was getting really hot; so I thought some
of the gas might be steam...  
  
So I dutifully put a condenser on the gas output, which would
condense any steam and allow it to drip back into the jar.  
  
I was really sad (happy dance stopped) when I concluded that the
gas was 99.99% steam. Not one bit of Brown's Gas was generated
by this method.  
  
But I found the effect interesting, because the jar did heat up
twice as fast as I would expect for the energy
consumption.  And MOST of my money making innovations come
from side effects of my main research...  
  
So I dutifully made measurements and compared the Wise Heater to
a heating element that used a similar amount of wattage (my
soldering iron).  I used a wattmeter to measure the energy
input (calculated to joules) and a thermometer on the jars.  
  
I report this experiment in my Brown's Gas, Book 1, written in
the early 1990's see excerpt below:  
  
Experiment One  
I placed two copper plates .0625 inch (1/16) from each other in
about 276 ml (just over a cup) of de-ionized water.  
  
Note: the water used in this experiment must be as pure as
possible. ANY impurity will cause electrical consumption to
rise.  
  
The plates were about .5 inch high by 1.5 inches long. They were
held together by plastic bolts and apart by plastic washers. I
soldered #14 solid copper leads to the plates.  
  
I plugged this directly into 120 VAC, as I had been assured (by
MAXA) that Browns Gas could be produced by AC current.  
  
My electrolyzer as described in Experiment 1, drew only .5 Amp
of current but went from 20 degC (68 degF) to 50 degC (122 degF) in ten
minutes and to 94 degC (201.2 degF) in 25 minutes from the start of
the experiment.  
  
I got all excited because there was a lot of gas. But I thought
some of it must be steam, because of the high temperature. So I
sealed my electrolyzer, assembled a condenser to separate the
steam from the Browns Gas and directed all the vapors through
the condenser, and then to a displacement container.  
  
I figured the steam would condense (turn back to liquid) and
drain back to the electrolyzer. I figured the Browns Gas (being
oxygen and hydrogen) would remain in a vapor state when cooled
and would displace water in my displacement container.  
  
By condensing the steam, I found that the vapors being produced
by the electrolyzer were nearly all steam (99.99%).  
  
So much for copious Browns Gas.  
  
So much for a simple AC application with no electrolyte and no
transformer.  
  
I did discover that the plates allowed the most current flow
when they were in a horizontal position (plate surfaces vertical
but depth shallow), so that the bubbles could remove themselves
from between the plates quickly, allowing more liquid to come in
from underneath.  
  
Bubbles between the plates impedes the electrical flow that
produces more gas.  
  
I also discovered that the electrical forces involved were
powerfulenough to rip the molecules right out of the copper
plates.  
  
When operating this experiment for a period of time the water
becomes cloudy with copper.  When examined, the plates show
obvious loss of copper.  
  
A side effect of this experiment seems to be over-unity heat.
Over-unity means that more energy is produced by a device than
is supplied to it. To take 276 ml from 20 degC to 50 degC in ten
minutes  
indicates 34,643.52 joules. The electrical power used was about
36,000 joules.  
  
This may not seem to be over unity on the face but you must
remember that this was an open container at 3000 ft elevation
with no insulation to prevent radiation, conduction and
convection losses.  
  
I ran a side experiment with electric resistance heaters drawing
the same amperage at the same voltage in the same container with
the same volume of water and it took twenty minutes to go from
20 degC to 50 degC and almost an hour to reach 85 degC (185 degF). The
electric element was never able to bring the water to a full
boil.  
  
Note, electric elements are supposed to be 98% efficient, so the
above experiment 'indicates' that the Wise Heater is more than
twice as efficient at heating water as an electric element.  
  
I also discovered that DC current flow (with set-up as per
Experiment1, but with a bridge rectifier installed) at this high
voltage still produced the over-unity heat.  
  
I duplicated this experiment several times and have had friends
duplicate it.  
  
However, getting back to the original experiment, high voltage
(AC or DC) and no electrolyte did not produce significant
amounts of H2 and O2, and what was produced was certainly not
Browns Gas.  
  
The high voltage seemed to cause the H and O to reduce directly
back to water as soon as it formed in the electrolyzer; with the
net result of simply converting electricity into heat...  
  
So I suggest to you, as I did to Sterling during the Brown's Gas
on Catalyst experiments, That the Wise Heater experiment be
repeated, but use stainless steel plates (to increase
electrodeposition voltage; so the plates won't degrade).  
  
The idea is to use plates like they are capacitor plates and
'vibrate' the water to heat it up.  
  
There is a magnetic field between capacitor plates (I've proven
that by putting a flat coil between pates and putting AC onto
the plates; the coil output electricity like a transformer.)  
  
Water is polarized by magnetic fields, so when you put AC to the
plates, it causes the water to be polarized one direction and
then the other as the AC reverses voltage.  Pulsing DC acts
similarly.  The 'flipping' of the water molecules back and
forth heats up the water.  
  
Obviously, 50 or 60 Hz may not be the optimum, and both the
plate spacing and plate height need to be experimented with, but
the technology is valid and works as is.  No need to be
complicated, it's very simple.  BTW, a glass jar prevents
electrical shock, yet allows the heat to be gathered.  
  
You want to use pure water because any ions that cross the
'capacitor' gap 'bleed' electricity.  You want any
electrical charge that's built up on a plate to return to the
Grid on the opposite cycle, thus 'conserving' electricity. 
The Wise Heater technology could be considered a spinoff of my
'Energy Conserver Theory" and my "Capacitive Power Supply"
projects.  
  
Thus I can confirm that the Dumas Effect is likely REAL because
of my own independent experiments.  
  
May the blessings be  
  
George Wiseman  
  
Peter Daysh Davey believed it to be a sonic effect more than
just electricity, that you had to 'tune' the gap to make it
produce large volumes of steam quickly and cheaply.  
  
Peter Davey water heater using cones instead of hemispheres;  
  
https://www.youtube.com/watch?v=e6tWLB\_t5zI  
  
"Well as it uses from 100% to around 20% of a normal forced
current heater like a commercial waterboiler. The consumption
depends on factors I have not investigated yet.  
  
By the way - there are no splitting water into H/O2 or forming
of gasses whatsoever. So no electrolysis here!  
  
But something even more interesting is the viscosity of the
water once resonated. It gets much thicker than tap water. And
it seems to get rid of all the impurities in the water - laying
at the bottom in a brownish colour.  
  
When resonating salt water the same thing happens. Only now
there is a much thicker layer at the bottom - now including the
salt.  
  
This could be a starters point for understanding Keely resonance
technology, as water is a miracle learning tool. In my view
mainly because of it's willingness to form any crystal bundles
whatsoever - the incredible water memory capacity.  
  
Keely also noted water is as made for frequency manipulation.
The Oxygen atom weighing exactly 16 times that of the hydrogen
atom also makes it perfect for frequency disassociation.?"  
---  
But he decided to test whether the same phenomenon is to appear,
if a metal hemisphere which simulates his pilot cabin is
submerged in water and is excited into a resonance frequency.  
  
So he found two tops from old bicycle bells, joined them
together, tuned one of them to 50 Hz frequency, attached
electricity wire to each one of them, and thrown them into
water.  
  
Surprisingly, water started to boil extremely fast. So he made
his first heater patent based on this observation. This patent
was already registered in 1944.  
  
(New Zealand patent number 92.428 dated on 12 December 1944 - I
have attached a pdf of if - JWD)  
  
After a hero return from the war, he had a device, which
repetitively proved to everyone who measured it, that it has the
efficiency decisively exceeding 100%.  
---  
https://web.archive.org/web/20100613205426/http://totalizm.nazwa.pl/boiler.htm  
  
Mr Davey was a musician who volunteered to defend freedom and
his country as a fighter pilot during the World War Two. He took
part in the Battle for Britain. Fighter aeroplanes of that time
had propellers and engines, which during acrobatics of aerial
battles were making the pilots cabin to vibrate at various
frequencies.  
  
As a sensitive musician Mr Davey noticed, that there was such a
frequency of the motor and propeller buzzing, when the aeroplane
cabin and his body were getting into a resonance.  
  
At this unique resonance frequency he always was experiencing an
influx of heat in his aeroplane cabin.  
  
He did not know yet, that in future this phenomenon will be
utilised in ultrasonic weapon systems for effective and
undetected killing of people. But he decided to test whether the
same phenomenon is to appear, if a metal hemisphere which
simulates his pilot cabin is submerged in water and is excited
into a resonance frequency of an AC current.  
  
So he found two tops from old bicycle bells, joined them
together, tuned one of them to 50 Hz frequency, attached
electricity wire to each one of them, and thrown them into
water.  
  
Surprisingly, water started to boil extremely fast. So he made
his first heater patent based on this observation. This patent
was already registered in 1944.  
  
In times when I kept in touch with Mr Davey he explained to me
that the fine tuning of the bowl (1) to the frequency of the
current he carried out with the saxophone.  
  
Namely, holding the heater in his fingers he played on the
saxophone the tune "low B" - which (the tune) is harmonic to the
frequency of 50 Hz. (Other easily accessible sources of sounds
having frequency 50 Hz include: piano - "low D", tuning fork -
"50 Hz", buzzing electrical transformer, modern oscilloscope
with a speaker.)  
  
If the bowl (1) of the heater would NOT fall into a resonance
(i.e. would NOT vibrate noticeably) during this playing, then he
slightly grinded (on a fast grinder) the front face of this bowl
and then tried again. These repetitions he carried out as long
as required for the bowl (1) always fall in the resonance
(vibrations) when he played this tune.  
  
In turn the fine tuning of the distance "L" the inventor carried
out by measuring the electricity consumption by the heater
(means measuring the value of Amperes that flow through the
heater). Namely he measured this power consumption for several
different distances "L" and then set on a given heater the
distance "L" for which this power consumption was the lowest.  
  
(1) The "sonic boiler" boils water immediately after it is
submerged in this water.  
  
(2) The "sonic boiler" boils water simultaneously in the entire
volume of this water.  
  
(3) Practically all phenomena which we get to know during the
use of classical electrical heaters of water, for the "sonic
boiler" have a completely different course.  
  
(4) The "sonic boiler" is exceptionally safe in use.  
  
(5) The "sonic boiler" boils any amount of any liquid that is
based on water.  
  
(6) The "sonic boiler" changes physical attributes of water that
it boils.  the sound of water boiled with this boiler is
completely different than in boiling with normal methods.  
  
(7) The "sonic boiler" in the technical version shown here has a
similar consumption of energy as every other heater of water (in
spite that in the version shown in "Fig. #B1" it apparently
consumed almost zero electricity).  
  
That idea of tuning to water is pure Keely who claimed 42.8khz
would dissociate water in an explosion instantaneously
generating upwards of  29,000psi...imagine that force to
drive engines!  
  
Seeya!  
  
Jerry @ Keelynet y mas (and more)  
  


---

  

**An Improved Electrical Immersion
Heater**  
  
**NZ92428   
  
( 1950 )**  
  
**Peter Daysh DAVEY**

  
This invention relates to electrical immersion heaters and more
particularly to electrical immersion heaters which utilize the
conductivity of liquid for their operation.  
  
It is well known that co-axial electrodes in water heaters and
particularly for use with such a heater for immersion in a
vessel of liquid including a system through which water flows
are common to the art in connection with electric immersion
heaters.  
  
The objects of this invention are to provide an improved
electrical immersion heater which is very rapid in raising
liquid temperatures when in use and which will not when in use
undergo any ill effects if the liquid in which it is placed
should evaporate entirely or the liquid supply is cut off; but
will operate again immediately further liquid is provided for
the heater.  
  
According to this invention the improved heater comprises a
central electrode, circular electrodes arranged concentrically
about the central electrode, means for holding the circular
electrodes so that they vibrate and an electrical connection
from one side of a source of alternating current to the central
electrode and to electrodes alternate from the central
electrode, and an electrical connection from the other side of a
source of alternating current to the circular electrode adjacent
he central electrode and to circular electrodes alternate from
the circular electrode adjacent the central electrode.  
  
Further the invention comprises a casing having holed ends and a
side or sides separating the ends, a central electrode holding
the ends and sides together, grooves in the inner surfaces of
the ends loosely retaining electrodes therein an electrical
connection from one side of a source of alternating current to
the central electrode and to circular electrodes alternate from
the central electrode, and an electrical connection from the
others side of a source of alternating current to the circular
electrode adjacent the central electrode and to circular
electrodes alternate from the circular electrode adjacent the
central electrode.  
  
The invention will now be further described with reference to
the accompanying drawings, in which :  
  
**Figure 1 is a schematical representation of the circuit
arrangement used in all forms of the invention;****Figure 2 is a side elevational view of one form of the
invention adapted for use as a portable immersion heater,****Figure 3 is a plan view of Figure 1,****Figure 4 is a cross section on line A-A of Figure 3,
while****Figure 5 is a diagrammatical view in longitudinal section
of the immersion heater affixed in a water heating system.**  
![](fig1.jpg) ![](fig2.jpg) ![](fig3.jpg) ![](fig4.jpg)  
  
In accordance with the present invention the improved heater as
schematically represented in Figure 1 has a central electrode 1
surrounded by a second electrode 2 spaced therefrom and which,
in turn, is surrounded by a third electrode 3 spaced therefrom,
the space 4 between the second electrode 2 and central electrode
1 and the space 5 between the second electrode 2 and third
electrode 3 are equal, and the first and third electrodes 1, 3
are in electrical connection with one another. When a heater
having such circuit arrangement is immersed in a liquid and the
second electrode 2 is connected with a terminal 6 of a source of
alternating current and the first and third electrodes 1, 3 are
connected with a terminal 7 to said source, the current passing
through the electrodes 2, 1, and 3 and the liquid heats the
liquid very rapidly.  
  
As illustrated any desired number of electrodes, concentric with
the electrode 1 can be used and spaced apart, provided an
earthed electrode 8 as a safety factor.  
  
The heater may be used by mere immersion in a bulk of liquid,
see Figures 2, 3, and 4, or it may be interposed in a conduit
through which liquid flows, e.g., a water pipe, see Figure 5.  
  
The size of the gaps or spaces such as 4, 5 between the
electrodes 1, 2, or 3 controls the speed of heating, the smaller
the gap or spaces such as 4, 5, the greater is the speed f
heating, hence, if the heater be interposed in a water pipe or
the like, see Figure 5, the gap or space such as 4, 5 must be
determined according to the desired temperature and flow-volume.  
  
In the simplest form of the invention, the central electrode 1
is  a brass rod of circular cross section and the second
and third electrodes 2, 3 are also of brass and are tubular and
co-axial with said rod 1, the third electrode 3 is electrically
connected with the first electrode 1 by a brass strip or wire 9
integral with, or secured to, the third electrode 3, and the
second electrode 2 has a brass strip or wire 10a spaced from
said strip or wire 9 sufficiently to prevent sparking if the
circuit remains closed after all the liquid has evaporated, or
said strips or wires 9, 10a can be electrically insulated from
each other. The electrodes may be plated brass.  
  
As an example suitable sizes of the parts may be a brass rod for
central electrode 1 of 1/4" diameter with tubular brass second
and third electrodes 2, 3  1/32" thick and spaced 1/4" from
each other, the gap or space 4 between the second and first
electrode also being 1/4". The assemblage may be 1-1/2" in
height and the second electrode 2 may be spaced from the strip
or wire 9 which connects the third electrodes 1, 3 about 1/8".  
  
As applied to a portable immersion heater for a bulk of liquid,
the form of the invention as illustrated in Figure 5, 2, 3 and a
casing made up of ends 10, 11 which have holes 12, 13 , 14 
having ingress and egress for liquid being treated, and thus to
provide for the convective movement of liquid as it is heated,
and also made up of sides 14 which separate the ends 10, 11. The
central electrode 1 such as a brass rod is utilized to hold the
casing together by screws 15, 16 countersunk into the ends 10,
11, see Figure 4. The ends 10, 11, and side 14 are made of
electrical insulating material such as porcelain. The inner
surfaces of the ends 10, 11 have oppositely positioned grooves
18 and the grooves 17 are concentrically spaced on said
surfaces. The spacings of the grooves 17 are arranged to give
desired spacing to electrodes such as 1, 2, 3 as set forth
above. The grooves 17 are also arranged to accommodate the ends
of the electrodes such as 2, 3 so that the latter are loosely
retained in the grooves 17 and are free to move from side to
side therein as electric current passes from liquid in the
spaces between the electrodes. In this form of the invention an
earthed electrode 8 is fastened round the outside of the side 14
as a safety means in the event of an electrical fault developing
in the heater. Various methods can be employed satisfactorily in
effecting and maintaining an electrical connection and in one
example the electrodes may be separated and retained in place
with rubber blocks, the resiliency of rubber allowing a small
movement of oscillation to take place. In this case contact may
be maintained by brass strips clamped between the rubber blocks
and the electrodes. Flexible retaining grooves may be used where
connections may be made with stranded copper wire crimped and/or
soldered to the rims of the electrodes.  
  
As indicated in Fiure 3 the electrical connections as described
above are incorporated in the end 10, the earth connection 8
being illustrated in Figures 2 and 4. When a heater made
according to this form of the invention is immersed in liquid in
a vessel it will be found that the liquid in its immediate
neighborhood boils very rapidly and convection currents are set
up through the concentric electrodes and through the holes 12
and 13, thus enabling the whole bulk of the liquid to be heated
speedily.  
  
In another form of the invention as illustrated in Figure 5, the
immersion heater is interposed axially in the length of a water
pipe and will be found to heat adequately a sufficient flow of
water passing through the water pipe. In this form of the
invention, as referenced in Figure 5, a conduit 18 leading from
a controlled source of water supply is widened to form a casing
19 which contains the end plates 10, 11 with holes 12, 13 and
the electrodes 1, 2, 3 or a multiple thereof as previously
described. The electrical connections may be from terminals 6, 7
in the casing 19 and electrically wired to the respective
electrodes as described before herein. After passing through the
holes 12, 13 heated water emerges into a narrow conduit again
and passes through the conduit to a faucet.  
  
In as much as there is no flow of electric current when there is
no liquid to complete the circuit it follows that the heater
cannot burn out if, through negligence, all the liquid is
allowed to evaporate, or the source of liquid supply to a
conduit in which the immersion heater is affixed is cut off.  
  


---

   
Wiracocha <WiracochaPachayachachic@protonmail.com> says :  
  
On the pict is a Davey boiler like device using 220 V / 50 or 60
Hz domestic current.  
  
![](daveyboiler2.jpg) 
![](daveyboilercopper.jpg)  
When you put two plates or half balls of silver or copper and
use distiled or rain water the device produces nano silver or
nano copper particles and oxides like tetrasilvertetroxide or
both if you use silver/copper metal.  
  
After at least two hours boiling one liter water with reflux
condenser the water will contain a huge amount of monoatoms,
nanoparticles and nano oxides.  
  
Such harmless waters can cure all viruses and all cancers.

---