1. ElectricsPacecraft
A jOu^MAl Or INT£A*CTIVE « i £ A A C H
73 Strrçfct & ? «
lr<*tter Q »:?*3
T<l 7G« 633-0]i 3
August 20. 1997
f i x 704 UJ+JJII John Hutchison
Apt. 305
727 5th Avenue
New Westminster. BC
Canada V3M 1X8
Dear John:
I would like to inform you lhat the Huichison
effect was mentioned in a poster presentation
recently delivered to NASA's Breakthrough Physics
Propulsion Workshop. The poster was designed to
communicate come of the ¡dtdS submitted to ESJ
through the years that might have the most potential
for applications in the future of space travel. Copies
of the poster and the accompanying paper, which
were made available to many prominent space
scientists and engineers, arc enclosed. Thank you for
your contributions to this poster and ESJ.
Sincerely,
Chartes A Yost
2. 930727/12
The Hutchison Effect Apparatus
By John Hutchison and ESJ staff
There have been some serious investigations Into the HutcNson Effect In
Canada, the United States, and Germany. ($ee articles ¡n ESJ #4. J The reality
of objects being moved, levitated, or restructured by magnetic and electric
Held effects does not seem to be In question. Just
how or why the events happen Is the questionable
part. John Hutchison has been providing ESJ with
details on his work, as have a few others who have
worked with Nm over the years. The picture consis-
tently described is that of numerous experimental
apparatus being operated simultaneously and In-
teractively. 'Events' occur, somewhat unpre-
dictably. 77i(s is a format of accidental discovery
through undeflnedmixture. Itlsexcltlng to Ihe expert*
menter, yet frustrating tothe scientist trying to sort
out the interaction of the variables. Although recol-
lection and details am difficult Mr. Hutchison de*
scrlbessomeofhlsapparatusfathtsattempttoshafe
wilh other experimenters.
I will attempt to explain details of the apparatus up to fourteen transformers. These included
used in my experiments and will start wilh the twclvc*volt transformers for vacuum tubes,
input power used to trigger the host of Tesla 400,000-voIt AC transformers, a Siemens
coils, static generators, transformers, interferom- 250,000-voIt DC X-ray transformer, and other
eters, magnetics, metal masses, and nuclear items. Regeneration equipment of 450 kHz up
sources, etc. The source power was 110 volts to 2500 MHz was also operatedr
AC operated at 400 watts to 4000 watts. One
side of the AC line had a power factor capacitor The general power circuit 15 shown in Figure 1.
(60 cycles, 250 voh), and a 100-amp current A and B are current limiters which ranged from
limiter The magnetics of the current limiter two to seven amps. By this means some trans-
were also used in the experiment interactions. formers were limited to this amperage instead
of the fifty amps that might otherwise be drawn.
This power source was divided up in a function The current limiters were adjustable and the
box and, through switching, went to variacs. magnetics from them were used in close prox-
The variac outputs were monitored by wattme- imity to the spark gaps and an alpha-beta
ters, ampmeters, and voltmeters, and supplied emission unit, I had bypass switches on each
Warning: The re-creation of certain aspects 0/ iJicsc experiments is extremely dangerous and
should not be attempted urffhouf proper rrafnfng or guidance.
u l*BMtHNCll744U$A
3. «HV
cppariror
iï "1 r
m
tOO A
eurrgnl timiur
IIûVACîOift
function box 2ílnirtcvi
wtth pilot tighit
Figure 1. Electrical Power Control
current limiter which I used often. Unfortu- primary and 1 0 , 0 0 0 turns of number 3 2 wire
nately there was a n inddertt o n e time in which on an 8-inch diameter secondaiy tube* A n o t h e r
Ihe outside p o l e transformer blew u p w h e n coil used twelve-gauge wire o n a 24-inch diarrr
using t h e bypass switch. eter tube, mounted horizontally- These a r e not
shown.
T h e symbol fx) is used t o represent the high
pctential leads in Figures J, 5~7% and 17. These
¿f dia copper batt
figures are rough schematics of some circuits.
3*<ta eopf*r ball
My favorite Tesla atfls are $hown in Figures 2
a n d J . O t h e r Tesla coils I bad w e r e of t h e flat <- a t r o l t tntulator
pancake-type with 1-inch copper tube in the
6 tuTftK *pat*d *WP
— icttfld coil *# *****
¡jta&s or citar urir* tpQClng — J * tito
inntr coit *28c*0ih cattf'*rf
4**.
ViAércoi!*32wir*
multiple prtmary
on* turn. J -rffa.ioppc* ruW
lanud cnit
iatoid cot! &>nn*emt SO |umi> *ff&pp+r m*
tocanttnuou* tvm
*$2 udtet 4 • duvneier ffi
Figure 2 Dumbbell Tesla Coll, 3 » 1 tong-
¡Design of this coit latks details, for instance: 1) Figure 3- Seuen'foot-toll Tesla Coit ¡Design of
primary coil /oajffon and drive. 2} secondary thlscoit lacksdetflïh, for instance: Ildlmen&lorts
ends connection toceramtc terminal, 3)whether of coiis, 2) connection* of coils, 3) power Input
torolds ore actively wired to something or notJ to primary.
15 EUcfrf- 3p+c+ermtt
L«tfîï«f.NC2nï-tdUSA
4. 2J t ÜOOV*C
H
choké coik
W MWl_
FlgureS TejfoCol/A
wrfe¿í* (nAjffor
M
M
OtofSftOOOVff
^F^-hfc
KFchoU
Figure 4. Vacuum Tube Tesla Coil Drive Figure 6 T « t o Coll B
2 1 5 omp
-irtabl*
CU/rrnl Oto2S0,<*WVDC
tow JnJjciO'ic* pi'jiTVJ ¿ o p *
ftmlti ¿60 Mt lo/iJTJ
WW
nojtiïfi
;J «I
100 mff
p*aifif p/p* and
W;u
n fijiMH
(s**Fiff. a
fordntotlj
ut+1 to (ÇÎIi^ï NùW to toffi 5uE 5,000 J
o r. J inwi (n 2S0 + 000 V DC cet srai^ /»f Ut
front/armar
R g u r e 7* Hfgh-Volrco^ D C Insertion P u l s e U n i r
The electronics of a
í—. vacuum tube Tcsla coil
]™r I3*'rf*omílrrc(i/o<iú r/nj<
rjpportírf by 3*ffq urbf are shown in Figure 4.
Figures 5 and 6 show
¡. rough schematics of the
i ' d i o m r t f f pfoitfc t u b *
.J ._*
/
bmdt otecitrottd
Tesla coil circuits*
The schematic of Fig*
¡aluminum utaron
Sop tttcirode*}
ure 7. powered by a high-
f d t m ü t r toJini voltage transformer,
copp+r Int
generated slrong elec-
1 * tric field pulses for a
2"<tktmtt*r Van tie Graff in clout p^otrlmity
topp+r bolt 1
4- charo** rnrrtrtrt r m ^
number of uses, includ-
hand u***h ; ingtficprojectk*iof bead
odJuK tungtítn gap* ffcetd ilflrrfrtinj option to ffc 7/ lightning, as illustrated
Figure 8. BotlEftghtning Projector in Figure 8,
n * c r r f a SpfBGtmtt JtHint*! H U B • 1903
U £ * i r a v t f*C 287** USA
5. One set-up, illustrated in figure 9 , seemed to Some years ago, Drs. Lakken and Wilson ar-
produce changes In the cosmic background gued over whether a "ball" of alph£*beta flux
radiation. formed and deposited on the test samples. I
personally don't believe so. I befieve the alpha*
If I increased the variac output to the Semens beta flux was guided to the masses by being
transformer to increase the high-voltage DC on connected to high-voltage DC levels, by mag-
the large toroki. while keeping the rest of the netic pulse fields, and excited by my mechani-
laboratory system running, the Geiger counter cally-pulsed magnetron which excited the geo-
would drop to near zero counts per minute metric metal. The idea is to excite the surface
within a 75-foot diameter zone* Yet t the reverse ¿kin of the masses and their atoms to create an
was possible (to Increase counts) if I dropped the unstable space-time situation. This might allow
toroid voltage and increased all DC voltages to the fields from the Tesla coils and RF genera-
the laboratory system of Tesla coils (via tank tion equipment to lock up in a local $pace-üme
circuits), RFcolIs, spark gaps, toroidal coils, and situation. My thought Is that nowa small amount
tension on the nuclear unit The AC part of the of energy is released from the vast reservoir in
laboratory system would be maintained at the space-time at the sub-atomic level to create a
same level. Figure 10 shows a schematic of disnjptive or movement effect,
pulsing to the large main torokf.
r-Tinfl
J' rfixvf*r tomtit
-» Jala moa **«Hi
A/itf H u d e v unit
:.™
Figure 9. The Large Moin Toroid—'/$" thick Aluminum
toroid
f*J"
ÍO'dta.i«tfon
0 to 250.000 VDC
nmn tmbm aUirntruim
M -K >» terminal
Figure JO. Main Toroid
<7 í I M m - J 3 p M « c r * f f J o w r w f Jnuo ft. 1993
L*C*tt*r. WC :^74d USA
I
6. Figure 11 Is a cutaway showing the nuclear gigahertz magnetron pulsed by an old rotary
section in the center of a Tesla colL Note how spark gap system sent microwaves by the win-
1 have the feed hom close to the window area. dow exit section. Small masses were placed
Thisareaw a s also bathed lna30 ( 000-volt staticclose to the Influence of t h e alpha-beta flux. The
electric field plus a weak magnetic field of onlyradioactive source was also under high-voltage
7 0 0 gauss which was variable* A two-spiral DC and pulsed coils (50,000 to 100,000 turns)
spark g a p unit Is also shown In Figure 11, to produce traveling wave type magnetics and
electrostatics to assist alpha-beta flux bunching
« The radioactive material to provide alpha-beta &nd guidance. This all interacted with other
emissions was contained m a stainless steel ball surrounding equipment. Some additional ar-
which had a thin window section. A four* rangement is shown in Figure 12.
¡0iaJOûmùOQVDC
wild (ron W U
cûucovbltétottQV
pufs* ¿¡tntratot
¡ht uif/e —
'ni'' "riîf homing)
uairtttAt boll A iMndauf
tlt<ontaci
Í it ipirat O*
ttotiroà MOT UiA flux «drvtoo
firtji
~*tt~t¿¿rynüp
700 ¿a»"
Jacob's ladder nuclear unit magnetron
2* talK iusr&pbüt emission ball
spark gop pulse generator
-FigutcJl, Alpha Beta Ru< Homing
afumi'Uftt b¿ock
copç^r bWA
ms>¡n*ll¡*
nttcttcs
contain**
IffCIUf
fUx output
(fable top] mouron
Figure I?. Alpha-Beta Fiux Setup
18 £|*crrfo
LflfcUPt NC 7 f l " 9 USA
:J
7. Magnetics owita/'ii 'puny l u m i of
XKctia 'PC*AC
A current limiter was used on "Big Red/' a fifty*
kVA, 89,00frvolt transformer. Afive-Hzspark-
gap discharge went amply to a copper ground
plate. The platewasmovable andplacement of the
plate proved successful to later ocperimcnts.
My current limiter was made from 4" by 4"
laminations stacked fifteen-Inches high and
number-eight wire wound soc layers thick. The
pulsing of the iron core proved Its worth In tests.
Its location was near the heart of my apparatus.
Because it was a heavy unitf casters were
needed to move It. The units pulse affected Ihe
electrostatics and Alpha flux, when close. The Figure 13, Modifiai Doublc-toop Bro« Ship
Alpha flux dropped off at two feet. Two other Antenna
units in the set-up were double-loop brass ship
antennas five-feet high, as shown in Figure 13. and electromagnets of the traveling wave tube
(TWT) barret types. Thus, perhaps a transform
These are some basics of my laboratory. I mation takes place on the subatomic level in all
excluded RFgeneration and coupling and all the of this» and a conversion zone takes form from
radar-jamming devices 1 used later. I could the surrounding equipment, This zone seems to
precisely set up a pattern at 2Q00 mHz at 100 transform again to zones beyond the lab, up to
milliwatts. I could give or take [±) 1000 mHzt 500 feet away, in the form of a cylinder. There
add pulse rate, CW or modulation of any form. appeared to be a zone at a distance of fifteen
feet. Samples placed in « sometimes levitated or
Placement geometry is of great importance to broke apart.
key units of the electro-
staticfieldand spark gaps.
The electrostatic field
~muâ cover all" compo-"
nents. Helping to do this
are copper balls mounted
on insulators. The large
ball keeps its charge
longer while small ones
discharge faster. In a way,
you have a pulse network
working along with dy-
namic electricity* and the
small influence ofthc250-
milfiwatt magnetron dose
to the alpha-beta flux. In
the zone is weak magnet- ' 1 aSB5p:.-v- •
• l - . - r . - A - - - •*''. •
ics, permanent magnets. Figure 1 4 . Hutchison'. I Set-up of Rectttvers and Monitor*
1
19
L«»ï*st*it HC 287*8 USA
8. Sample Reactions
(Extracted from Reports)
The effects of unexpected fieU interactions are
shown in figures 35 and 16. One sample, a
piece of aluminum fouHnches long by Vz-lnch
square, had been shattered In the center. It
would be expected that only a few watts were in
this zone, compared to the 400Owatt input
feeding all the equipment. Our sample had
exploded from inskleout. torn into thousands of
filaments. The filaments measured .010" to
0.50" long and .008" to .012" thick. The event
volume expanded outward from the mass cen- Flourel6. So"rf Metal Bars Split and Frayed by
ter in seaming reaction to a force of mutual fhç Hutchison Effect
repulsion between filaments.
ture, while having none of the characteristics
The field lines picturesquely frozen in the alumi- associated with plastic deformation or melting.
num filaments are functionally identical to (hose Physical characteristics were typical of ciystalline
we observad at a point offractureof a permanent materials sheared along bonding planes. The
bar magnet of the same geomeby. The force number of filaments probably exceeded
exerted on the aluminumfilamentswas sifident 100.000. effectively Increasing the surface area
to sp lit abrgenumber of the outermost strandsand within the event by tens of thousands of times.
fold them back along the "field lines" to such a
degree, that layers of them arc compacted Another sample showed inexplicable material
together, against the solid surfaces of Ihe sample. mixtures; wood was found in an aluminum block
tested by Siemens Laboratory, Germany. Also,
The material within the event vokime was much dense, impossible alloys of elements forming
harder aiyl quite brittle compared to the original unknown materials were found by work of Max
extrusion alky* which was quite soft. A surfaces Planck Institute, Germany. Because so many
D
evidenced a mottksd appearance and regular struc- different effects happen, including lévitation,
we can speculate the RF and support field
operators are working in a narrow region
of the "zone of effects." These random
events sometimes happened at about
fivc-pcr-hour in 1987, '88. and '89,
It is an unpredictable probability for all
operators to synchronously combine to
cause an effect. For events like slow lift
and slow disruption, the operators com-
bine under simple stable outputs, ampli-
tudes, and frequency. Our space-time
window would have to be described on
the subatomic level for the understanding
Figure J 5. Aluminum and Brass Bars After the Effectof the Hutchison Effects.
LflCMier. UC 2H7&Q USA
9. r^Li iiuuiarp*i
htgtehokmtell
M
0 to 400,000 V ^ _ 0 tnferfcromrtfr
4ÍWLO0O V
M
o.
40 G? mto cep
0t000Voùch opto air ttbocUon
00ÛJ^*ft0Û0lcK* tcWlAifJtastfio/unlt
fnritalktolkrtten 4'faiff
Usure 17. Interferometer
Acknowledgments
I would like to thank those Individuals
associated with Pharos Technology,
/far ùhtmtnum >u. ji
the Max Planck Institute. Los Alamos.
41
u^ti» ruh&tf' È*Jndi McDonnel Douglas, BAM Labs Ger-
many, Fraunhofer. the Austrian and
J0* d ^ m d r German groups, the DOD groups,
PMtW pip* and individual input from Japan,
Greece, England , Canada, USA, Swit-
LU ofamtnum
ihrfl zerland, France and the Yin Gazda
International Filmmaker, for the In-
mtlk
^ outer forold terest and support they all have shown.
írQírt
•
About t h e Author
John Hutchison is the classic inde-
Van d c Crooff *í Van rfr Groa// #2 pendent individual experimenter—the
-_.-. _ „ _ _ bulk In. 19S4 *Sorcerer's Apprentice." Mr. Hutchi-
Figure Î8 son can be reached by mail at 9 1 1
Dublin Street, New Westminster, Brit-
Figure 1 7 is another pulsing rirait dévies I call Kh Columbia. Can-xla, V3M 2Y5 »
the interferometer. Electrostatics were produced
with two Van de Graaff generators. When
arranged as shown in Figure 18, cool wind
effects could be produced. These machines
were used to impose an electrostatic field in the
test ^rea.
21 £ï*crr|o , ,ft Jo+tm*t Issue % 1333
Laceen*. NC 3S74Û U $ *
10. ElectricsPacecraft
A jOu^MAl Or INT£A*CTIVE «S£AACH
73 Strrçfct & ? «
lr<*tter Q »:?*3
T<l 7G« 633-0]i 3
August 20. 1997
fix 704 UJ+JJII John Hutchison
Apt. 305
727 5th Avenue
New Westminster. BC
Canada V3M 1X8
Dear John:
I would like lo inform you lhat the Huichison
effect was mentioned in a poster presentation
recently delivered to NASA's Breakthrough Physics
Propulsion Workshop. The poster was designed to
communicate come of the ideas submitted to ESJ
through the years that might have the most potential
for applications in the luture of space travel. Copies
of the poster and the accompanying paper, which
were made available to many prominent space
scientists and engineers, arc enclosed. Thank you for
your contributions to this poster and ESJ.
Sincerely.
Charles A Yost
11. 930727/12
The Hutchison Effect Apparatus
By John Hutchison and ESJ staff
There have been some serious investigations Into the HutcNson Effect In
Canada, the United States, and Germany. ($ee articles In ESJ #4. J The reality
of objects being moved, levitated, or restructured by magnetic and electric
Held effects does not seem to be In question. Just
how or why the events happen is the questionable
part, John Hutchison has been providing ESJ with
details on his work, as have a few others who have
worked with Nm over the years. The picture consis-
tently described is that of numerous experimental
apparatus being operated simultaneously and in-
teractively. 'Events' occur, somewhat unpre-
dictably. Tills is a format of accidental discovery
through undefined mixture. Itisexcitlng to the expert*
menter, yet frustrating tothe scientist trying to sort
out the interaction of the variables. Although recol-
lection and details am difficult Mr. Hutchison de*
scrlbessomeofhisapparatusfathlsattempttoshw
with other experimenters.
1 will attempt to explain details of the apparatus up to fourteen transformers. These included
used in my experiments and will start with the twclve*volt transformers for vacuum tubes,
input power used to trigger the host of Tesla 400,000-voIt AC transformers, a Siemens
coils, static generators, transformers, interferom- 250,000-voIt DC X-ray transformer, and other
eters, magnetics, metal masses, and nuclear Items, Regeneration equipment of 450 kHz up
sources, etc. The source power was 110 volts to 2500 MHz was also operatedr
AC operated at 400 watts to 4000 watts. One
side of the AC line had a power factor capacitor The general power circuit 15 shown in Figure 1.
(60 cycles, 250 voh), and a 100-amp current A and B are current limiters which ranged from
limiter The magnetics of the current limiter two to seven amps. By this means some trans-
were also used in the experiment interactions. formers were limited to this amperage instead
of the fifty amps that might otherwise be drawn.
This power source was divided up in a function The current limiters were adjustable and the
box and, through switching, went to variacs. magnetics from them were used in close prox-
The variac outputs were monitored by wattme- imity to the spark gaps and an alpha-beta
ters, ampmeters, and voltmeters, and supplied emission unit, I had bypass switches on each
tVnrnlng: The re-creation of certain aspects of these experiments is extremely dangerous and
should not be attempted without proper rrafnfng or guidance.
u l*BMtHNCll744U$A
12. to RF Qenrrntlon
tQ¿**P*Ttnt A J:.' ; i-I :
Mm
"1 r
po*p*rJact&r
copadlo*
iï E4
100 A
eurrgnl Hmitrr
11ÙUAC60H*
function box 2*t**tUK%
with P*lot tiçhU
WW
Figure h Electrical Power Control
current limiter which I used often. Unfortu- primary a n d 1 0 , 0 0 0 turns of number 3 2 wire
nately there was a n incident o n e time in which on an 8-inch diameter secondaiy tube* A n o t h e r
t h e outside p o l e transformer blew u p w h e n coil used twelve-gauge wire o n a 24-inch dlarrr
using t h e bypass switch. cter tube, mounted horizontally- These a r e not
shown.
T h e symbol fx) is used t o represent the high
pctentia! leads in Figures J , 5~7% and 17. These
¿f dia cop?** aatt
figures are rough schematics of some circuits.
$*dia. copper MI
My favorite Tesla coils are $hown in Figures 2
a n d J . O t h e r Tesla coils I bad w e r e of t h e flat <- «trole tntulator
pancake-type with 1-inch copper tube in the rzuhrrpiatt urtr*
6 tuTftK ipocaü *WP
— icttfld coil *# *lre
¡jta&s or citar urirt tpactng —i'dto
ptosis gjphtf
inntr coit *28c*Olh cat*'**
4**.
outer coil *32*ir*
multiple primary
ioroid cotl tonn*cittt on* turn. J -rffa.eopprr ruW
lanud catt SO |umi> *8c?QP*t wire
tocanttrtuou* turn
*$2 udtet 4 • diamcier fiï
Figure 2 Dumbbell Tesla Coll, 3 » 1 tong-
¡Design of this colt latks details, for Instance*. 1) figure 3- Seuen'foot-toll Tesla Coit ¡Design of
primary coil /oajffon and drive. 2} secondary thlscoil lacksdetûlh, for instance: lldlmenslorts
ends connection toceramic terminal, 3)whether of coiis, 2) connection* of coils, 3) power Input
toro ids are actively wired to something or notJ to primary.
15 EUcfrf- 3p+c+ermtt
L«tfîï«f.NC2nï-tdUSA
13. 2JtÜOÜV*C
H
choké coik
W MWl_
FlgureS TejfoCol/A
uartobl* Inductor
M
M
0*>?StXOMVrx
^F^-hfc
KFchoU
Figure 4. Vacuum Tube Tesla Coil Drive Figure 6 Tesh Coil B
215 omp
mnabU
CurrrnJ Oto 25O.0OQ VDC tou» JnJjciO'ic* p , ' . w v j ¿op*
ftmlti ¿60 M t lo/iJTJ
(Ê/fjf
pçrrrïjntrxt
• nojtiïfi
;J «I
100 mff
p*aifif pipe and
W;u
n fijiMH
pukrt«d.¿aOCÚVDC'
coro*"*) rtfb^i
(S**Fla. 3
fordttatlj
ut+1 to pillen NùW t o toffi
5uE 5ÉtXÜ J
o r. J inwi (n 2S0 + 000 V DC K Í sraifc? /If i¿*
front/armar
Rgure 7* Hfgb-Volrcc^ DC Insertion Pulse Unir
The electronics of a
£-, vacuum tube Tcsla coil
J " r I3*'rf*omílrrc(i/o<iú r/nj<
are shown in Figure 4.
Figures 5 and 6 show
¡.
<i"diameter pttttic tub* rough schematics of the
.J ._*
/
btodt occe!*mlt>d
Tesla coil circuits*
The schematic of Fig*
¡aluminum u t a r o n
Sop tttcirode*} ure 7. powered by a high-
f d t m ü t r toJini voltage transformer,
copp+r Int
generated slrong elec-
1 * tric field pulses for a
2"dktmtt*f Van tie Graff in clout p^otrlmity
topp+r bait 1
4- Charon enmnn rrnçt
number of uses, includ-
l a n d uJutfli ; ingtficprojecuOTof bead
o d > u U t i i n j i r / r t OOP* ¡hood H$hirtn3 option t o Tfc 7/ lightning, as illustrated
Figure K BatlEftghtning Projector in Figure 8,
n * c r r f a Sp+cTtmtt JtHint*! HUB • 1903
L4£*irar t f*C 287** U&A
14. One set-up, illustrated in Figure 9 , seemed to Some years ago, Drs. Lakken and Wilson ar-
produce changes In the cosmic background gued over whether a "ball1' of alph£*beta flux
radiation. formed and deposited on the test samples. I
personally don't believe so. I befieve the alpha*
If I increased the variac output to the Semens beta flux was guided to the masses by being
transformer to increase the high-voltage DC on connected to high-voltage DC levels, by mag-
the large toroid. while keeping the rest of the netic pulse fields, and excited by my mechani-
laboratory system running, the Geiger counter cally-pulsed magnetron which excited the geo-
would drop to near zero counts per minute metric metal. The idea is to excite the surface
within a 75-foot diameter zone* Yet t the reverse ¿kin of the masses and their atoms to create an
was possible (to Increase counts) if I dropped the unstable space-time situation. This might allow
toroid voltage and increased all DC voltages to the fields from the Tesla coils and RF genera-
the laboratory system of Tesla coils (via tank tion equipment to lock up In a local $pace-üme
circuits), RFcolIs, spark gaps, toroidal coils, and situation. My thought Is that nowa small amount
tension on the nuclear unit The AC part of the of energy is released from the vast reservoir in
laboratory system would be maintained at the space-time at the sub-atomic level to create a
same level. Figure 10 shows a schematic of disruptive or movement effect,
pulsing to the large main toroki.
r-Tinfl
J' rfixvf*r tomtit
-» Jala moa unid
e/id H u d e v u n ft
itooa e*.t ïotxùoô vrxr
:.™
Figure 9. The Large Moin Toroid—'/$" thick Aluminum
taroto
f*J"
010 250.000 VDÇ ÍO'dta*i«tfon
nmn tmbm QÏuminum
M -K >» terminal
Figure 10. Main Toroid
<7 Ornctri^ 3PM«cr*ff J.U.Î.JÎ J n u o tt. 1 9 9 3
L*C*tt*r. W 387*8 USA
C
I
15. Figure 11 is a cutaway showing the nuclear gigahertz magnetron pulsed by a n old rotary
section in the center of a Tesla colL Note how spark g a p system sent microwaves by t h e win-
dow exit section. Small masses were placed
1 h a v e t h e feed h o m close t o the window area.
close t o the influence of t h e alpha-beta flux. T h e
T h i s a r e a w a s also bathed l n a 3 0 ( 0 0 0 - v o l t static
electric field plus a weak magnetic field of only radioactive source was also under high-voltage
7 0 0 gauss which was variable* A two-spiral DC and pulsed coils ( 5 0 , 0 0 0 t o 1 0 0 , 0 0 0 turns)
t o p r o d u c e traveling w a v e type magnetics and
s p a r k g a p unit is also shown i n F i g u r e 11,
electrostatics t o assist alpha-beta flux bunching
« T h e radioactive material to provide alpha-beta &nd guidance. This all interacted with other
emissions was contained In a stainless steel ball surrounding equipment. S o m e additional ar-
which had a thin window section. A four* rangement is shown in Figure 12.
¡0 to J0Ûmùù0V DC
wild (ron Wl<
«u celled to 250 V
pufs* ¿¡tntratot
¡tot uif/e —
nux "ri3f homing)
uairtttAi boll A Utlrtdaüt
tlt<ontaci
Í it spiral cm
ticflrod MOT UiA fluK udrvtoo
firtji
pu IK tmmfatm+r
rm§mtSA
700 pun "*f*~rc¿Ji'y flap
Jacob's ladder nuclear unit
2* talK ru<o-$pttaf magnetron
emission ball
spark gap pulse generator
-FigureJJ, AlphoBcta Ru< Homing
afumi'Uftt b¿ock
copper bW*
|TCSTI*I1¡>
nttcttof
contain**
ictctu
fUx output
¡table topi
Figure I ? . Alpha-Beta Fiux Setup
18 £|*crrfo
LflfcUPt NC W*% USA
:J
16. Magnetics •vmM'-rii fnorty lum« of
3fc3K
A current limiter was used on "Big Red/' a fifty*
kVA, 89,00frvolt transformer. Afive-Hzspark-
gap discharge went amply to a copper ground
plate. The platewasmovable andplacement of the
plate proved successful to later ocperimcnts.
My current limiter was made from 4" by 4"
laminations stacked fifteen-inches high and
number-eight wire wound soc layers thick. The
pulsing of the iron core proved its worth In tests.
Its location was near the heart of my apparatus.
Because it was a heavy unitf casters were
needed to move it. The units pulse affected Ihe
electrostatics and Alpha flux, when close. The Figure 13, Modifiai Double-toop Brass Ship
Alpha flux dropped off at two feet. Two other Antenna
units in the set-up were double-loop brass ship
antennas five-feet high, as shown In Figure 13. and electromagnets of the traveling wave tube
(TWT) barret types. Thus, perhaps a transform
These are some basics of my laboratory. I mation takes place on the subatomic level in all
excluded RFgeneration and coupling and all the of this» and a conversion zone lakes form from
radar-jamming devices I used later. I could the surrounding equipment, This zone seems to
precisely set up a pattern at 2Q00 mHz at 100 transform again to zones beyond the lab, up to
milliwatts. I could give or take [±) 1000 mHzt 500 feet away, in the form of a cylinder. There
add pulse rate, CW or modulation of any form. appeared to be a zone at a distance of fifteen
feet. Samples placed in it sometimes levitated or
Placement geometry is of great importance to broke apart.
key units of the electro-
static field and spark gaps.
The electrostatic field
~muâ cover all" compo-"
nents. Helping to do this
are copper balls mounted
on insulators. The large
ball keeps Its charge
longer while small ones
discharge faster. In a way,
you have a pulse network
working along with dy-
namic electricity* and the
small influence ofthc250-
milliwatt magnetron dose
to the alpha-beta flux. In
the zone is weak magnet- ' 1 aSB5p:.-v- •
• l - . - r . - A - - - •*''. •
ics, permanent magnets. FtqurcM. Hutchison'.I Set-up of Recovers and Monitor*
1
19
L«»ï*st*i t HC 287*8 USA
17. Sample Reactions
(Extracted from Reports)
The effects of unexpected fteH interactions are
shown in figures 35 and 16. One sample, a
piece of aluminum fouHnches long by Vz-inch
square, had been shattered In the center. It
would be expected that only a few watts were in
this zone, compared to the 4000-watt input
feeding all the equipment. Our sample had
exploded from insideout, torn into thousands of
filaments. The filaments measured .010" to
0 5 0 " long and .008" to .012" thick. The event
volume expanded outward from the mass cen- Flgurelâ. Solid Metal Bars Split and Frayed by
ter in seaming reaction to a force of mutual fhç Hutchison Effect
repulsion between filaments.
ture, while having none of the characteristics
The field lines picturesquely frozen in the alumi- associated with plastic deformation or melting.
num filaments are functionally identical to those Physical characteristics were typical of ciystalline
we observad at a point offractureof a permanent materials sheared along bonding planes. The
bar magnet of the same geomeby. The force number of filaments probably exceeded
exerted on the aluminumfilamentswas sifident 100.000. effectively Increasing the surface area
to sp lit abrgenumber of the outermost strandsand wiihin Ihe event by tens of thousands of times.
fold them back along the "field lines" to such a
degree, that layers of them arc compacted Another sample showed inexplicable material
together, against the solid surfaces of the sample. mixtures; wood was found in an aluminum block
tested by Siemens Laboratory, Germany. Also,
The material within the event vokime was much dense, impossible alloys of elements forming
harder aiyi quite brittle compared to the original unknown materials were found by work of Max
extrusion alky* which was quite soft. A surfaces Planck Institute, Germany. Because so many
D
evidenced a moltksd appearance and regular struc- different effects happen, including lévitation,
we can speculate the RF and support field
operators are working in a narrow region
of the "zone of effects." These random
events sometimes happened at about
fivc-pcr-hour in 1987, '88. and '89,
It is an unpredictable probability for all
operators to synchronously combine to
cause an effect. For events like slow lift
and slow disruption, the operators com-
bine under simple stable outputs, ampli-
tudes, and frequency. Our space-time
window would have to be described on
the subatomic level for the understanding
Figure J 5, Aluminum and Brass Bars After the Effectof the Hutchison Effects.
LttC«3ltfi KC 2H7&Q USA
18. r^Li iiuuiarp*i
htgtehokmtell
M
0 to 400,000 V ^ _ 0 tnferfcromrtfr
4ÍWLO0O V
M
o.
40 G? fflfea rap
J0t000VMch
opto air catvtcUon
00ÛJ^*ft0Û0lcK* toll fait len&ho! unit
fnrtialktolkrton 4'k>tyo
Usure 17. Interferometer
Acknowledgments
I would like to thank those Individuals
associated with Pharos Technology,
/far ùhtmtnum rings
the Max Planck Institute. Los Alamos,
1
tdff» ruh&tf' È*Jndi McDonnel Douglas, BAM Labs Ger-
many, Fraunhofer. the Austrian and
J0* dizmeic German groups, the DOD groups,
PMtW pip* and individual input from Japan,
Greece, England , Canada, USA, Swit-
LU ofamtnum
ihrfl zerland, France and the Yin Gazda
International Filmmaker, for the In-
mtlk
^ outer forold terest and support they all have shown.
írQírt
•
About t h e Author
John Hutchison is the classic inde-
Van d c firoo// *I Van rfr Groa// *2 pendent individual experimenter—the
-_.-. _ „ _ _ bullí IR.19S4 *Sorcerer's Apprentice," Mr. Hutchi-
Fïgur* Î8 son can be reached by mail at 9 1 1
Dublin Street, New Westminster, Brit-
Figure 1 7 is another pulsing rirait dévies 1 call Kh Columbia. Can-xla, V3M 2Y5 »
the interferometer. Electrostatics were produced
with two Van de Graaff generators. When
arranged as shown in Figure 18, cool wind
effects could be produced. These machines
were used to impose an electrostatic field in the
test ^rea.
21 £ï*crr|o , ,ft Jo+tm*t Issue % 1333
Laceen*. NC 3S74Û U $ *
19. The Hutchison Fil*
The Hutchison effect - a lift and disruption system
George D. Halhaway
«limed Ifcm: New Etwgy TediiK>*ugy. (xiMshed bfV* Pkmetir? Atocriaücn foi Ck* Efwgy, l»0. p 77*103
The following may shed light on a most unusual phenomenon which we have
c a l l e d t h e "Hutchison E f f e c t " , I t is a very s t r a n g e a r r a n g e m e n t of
t e c h n o l o g i e s Including t h o s e of Nikola T e s l a a n d R o b e r t Van d e C r a a f .
This is a topic t h a t is v e r y conducive t o wandering b e c a u s e it brings Id
all of the most a m a z i n g kinds of effects t h a t one would love t o have In
t h e i r b a s e m e n t , such as m a t e r i a l levitating and floating around* being
a b l e t o b r e a k s t e e l b a r s without t h e u s e of your b a r e hands» and alt
s o r t s of o t h e r weird and wonderful things.
Pharos Technologies Ltd. was a company formed by myself and a g e n t l e m a n
by the n a m e of Alex P e z a r r o * who you may r e c a l l m a d e a p r e s e n t a t i o n a t
the 1983 2nd I n t e r n a t i o n a l Symposium on Non-Conventional E n e r g y Technology
in A t l a n t a - Alex talked about one of his pet p r o j e c t s , which was oil and
g a s discovery by novel means* In 1980» w e formed this small company t o try
t o p r o m o t e w h a t we then c a l l e d the Hutchison Effect* We also t e r m e d It In
our e a r l y p r e s e n t a t i o n s : LADS o r t h e Lift a n d Disruption S y s t e m . T h e
following s e r i e s of graphs w e r e c r e a t e d In 1984 t o present t o various p a r t i e s
I n t e r e s t e d in funding t h i s technology- The first graph i n d i c a t e s the topics
c o v e r e d in t h e s e p r e s e n t a t i o n s .
i 1 1
i i u rj ton » 11 T O I T
- W W Un tm IfWUtM « K5iU ff • • ittlfflA muiinc
• satiaTaiiwTiicKutiuiicms iiJWMitftiii
«SUT» U CAUSrffntC IttUffUt 'MCIWIIS
- uismt cmtnxiis ruuic BOMUM» IR K I « J
• «¿tut mvstK Aum-un UUTU* una* u IUMH POETIC
- U I U * r « i r L/Jtt-SUI MttCiKTORUSH <"U
DC C
• cjtfim cMvut ut c o t o i cavo&itroi if mMi
- IIHÍ* LM*U« tiftni
m M toi F*** mu * ffiiuaa
t)
21. Thv Hutchison Fito
The earliest explanation was given by Mel Winfield of Vancouver, whose name
may be familiar from Dr. Nleper's 1988 Congress in Germany. He suggested
that the explanation for the phenomena was due to a method of making the
electro-magnetic fields spin or swirl in some unknown way*
Pharos Technologies was involved In three phases of development, the first
phase of which was In the basement of a house In Vancouver. This is where
John Hutchison's original work was done. The collection of apparatus which
will boggle the mind can be seen on the video (shown during the lecture
and available from the publisher) and replicated In Figures II and 12.
That was the Phase 0 development. Phase 1 was when we stepped in with some
money and took the equipment from the original location and put It in a
more reasonable setting. Phase II was a third location prior to its being
dismantled and put Into storage by John.
The main thing about this technology, apart from Its unusual phenomenology.
Is that it is highly transitory. The phenomena come and go virtually as they
please. One has to sit with this apparatus from between six hours and six
days before one actually sees something occurring. This makes It virtually
impossible to interest someone who would like to try to develop it, to assist
In funding, for Instance. You can't assume that someone will sit there who
is ready to help develop a technology, and have him wait and wait, and perhaps
nothing will happen. It's unusual to ask someone to wait six days for a
phenomena that they're Interested in developing commercially. So one can
imagine that we've had some difficulty in the past in financing this program.
Note In Figure II one of the Tesla coils in the foreground. The main coll is
4 1/2 feet (1,4 m) high. It was extremely difficult to get around in the first
lab (Phase 0). The first laboratory in Vancouver was so densely packed with
equipment that you could not find a place to put your foot down. You had to step
around all sorts of objects that were put on the floor.
Disruptive phenomena
In the video a bushing Is shown breaking up. It was a steel bushing about
2 inches (5 cm) in diameter by 3 to 4 inches (9 cm) long. John still has that
In his lab and I have some to show as well (Figures 1 and 2) .
The next part of the video is well known. I will try to explain some of Its
phenomenology. It starts with John warming up the system. To determine where
the optimum place for positioning the test objects, which will either take off
or burst, he put coins and bits of styrofoam where he believes is going to be
the active zone. The first thing that happens is a quarter ($ .25 coin)" starts
to flip and vibrate. Now he knows he should concentrate putting specimens in
that zone and he does so. We « e some water In a coffee cup that appears
15
22. flW Hutchison FtlQ
to" be swirling, although it's not. ¡T is merely the surface rippling by some electro-
magnetic means and the coffee cup is dancing around the top o f a yellow milk carton.
It's another way for him t o determine where the zone Is, Then we see a flat file
8 inches (20 cm) long breaking apart* This file broke Into four more or less equal-
length sections. Normally, if you break a bar magnet, you know that you break it
north-south, north-south, north-south, e t c . So the parts tend t o stick back together
again. In this case the segments were magnetized the wrong way by some phenomena
not know and they repel each other when they're put together at the breaks. This ma)
be indicative of the development o f large-scale monopolar regions that are of such
Intensity that they disrupt the material Itself. I t ' s as reasonable an explanation as
I've been able to come up w i t h , or anyone else.
L i f t i n g phenomena
We then proceed t o document some l i f t i n g phenomena. The objects that are lifted In t
first part of this section are on the order of a few pounds. A l l of them l i f t off
with a twist. They spiral as they l i f t o f f . There has t o be a particular geometry
w i t h respect t o down (gravity) for them t o take o f f . Some objects, i f you He them
on their sides, won't take off. I f you turn them on their ends, they w i l l take off.
Th£ geometrical form of the objects, their composition and their relationship t o their
environment, the field structure around them that is being created by the device,
all play a part In how these things take off.
There are four main modes of trajectory that these objects can follow If they do
choose t o take off. There's a slow looping arc where the objects w i l l basically take
o f f very slowly in a matter of a couple of seconds and loop and fall back somewhere
It Is almost as if the Earth moves underneath them while they are in f l i g h t , and they
fall back In different locations. The second type of trajectory Is a ballistic
take-off. In other words, there's an Impulse of energy at the beginning of the
trajectory with no further power applied t o the l i f t i n g thereafter, and the object
h i t * the ceiling and comes back down. A third type o f trajectory Is a powered one
where there appears t o be continuous application of l i f t i n g force. I have some
evidence taken from the video. The fourth trajectory Is hovering - where objects
just rise up and sit there. The objects can be o f any material whatsoever: sheet
metal, wood, styrofoam, lead, .copper» zinc, amalgams and they all either take off
or they burst apart, or they do nothing — that's 99% of the t i m e .
Lighting phenomena
Following that Is a strange lighting phenomenon. This only occurred once but
fortunately, while John was f i l m i n g . Incidentally, this early f i l m , with the most
spectacular results observed, was taken by John himself. It was taken in 1981 and
all o f a sudden a sheet of iridescence descended between the camera and some o f the
apparat! and one sees that sheet of light. It has a strange pinkish centre t o i t and
hovered there for a while, and then disappeared. John thought he was hallucinating,
Í6
23. The Hutchison Fito
but when we developed the film It turned out something was definitely there.
.::,
In this same video, we observe heavier objects taking off. including a
19-pound (8.6 kg) bronze bushing and water In a cup that's dancing around»
the surface of which is vibrating. There are no ultrasonic or sonic devices
in this particular series of experiments. There are no magnetic components
lui underneath or over top. There a r e no field colls underneath or over top or
anywhere within 6 feet (i fi m). These images were taken while t h e apparatus
was performing at peak, and shows best results for the earlist experiments.
Sometimes, Instead of lifting objects, John will purposely try to destroy
them. In one case, a l / 4 n round rattail file rests on a plywood base and is
held dom from taking off by two plywood pieces. Beside it are some quarter
and penny coins. The file is glowing white hot and yet there Is no scorching
of the wooden plywood pieces which are holding it down. Neither are any of
the coins affected. This Is explainable In terms of RF heating theory because
yew can have eddy current heating on the surface and It's almost cool to the
touch very shortly thereafter. It's still unusual that there Is no conductive
heat transferred to the wood.
|J
V From time to time there are scorch marks on the boards from other experiments.
The apparatus makes fire spontaneously In parts of the lab if you're not
careful*
J The original (Phase 0) lab set-up was primitive, crowded, had poor connections,
' end had hand-wound coils- However, the films that have most of the best lift
1
episodes were (tone In this early sQt-up» drawing a maximum of 1.5 kilowatts
'¿'continuously from house-mains.
Disruption effects • -
> cr rmicn . OEMCA «* ooftm uyina
n
• à «*n a a n n u m «mut ivntî * U . mniniE m MowoMt •
l^XJilJti t »TU -«mm
MMlsm - IUTTUJUS t ntUUTT
* oniv% rwuoari
Mb not
-I.C* xtm m» UBtMvr ¡
marmttm - %rjmi% Lu;:Kr r : B g p -
- wifii itsfusitt mrsis
o>ra. nota
• I . : - TVOttO tDtfVOT CF KlALUK* i
• CMlPUTittS tf Itttf
- tumi* men» «oûsctrt
* AI wro, sim. *o «ton * a w n a m muim U-ÍATI
- amu *mws s u n T g u u i
O LVUCKB «UWIUHLI TIS1Ï
m HÂ
17
24. Tha Hutchison Fito
The disruption part of this L i f t and Disruption System has produced confirmatory
physical samples that include water, aluminum, Iron, steel, molybdenum, wood, copper,
bronze, etc., with many shapes, sizes and masses. Certain materials are subject t o
certain Influences depending on shape, composition and other factors.
We have tested various pieces that have broken apart for hardness, ductility, e t c .
We have used optical and electron microscopes. We have taken SEM r s w i t h EDA's (Energy
Dispersive Analysis) t o determine the composition at various points.
Two samples of aluminum are shown, one of which Is in the centre of Figure 1, which is
twisted up In a left-handed spiral, and in Figure 2 on the left which was blown into
l i t t l e fibers. Lying on the ruler In Figure I to the left of centre is a molybdenum
rod used In nuclear reactors. These things are supposed to withstand temperatures of
about 5,000 ° F . We watched these things wiggle back and f o r t h , and stopped the
apparatus halfway through a wiggle and that's the result. Figure 2 (left) shows the
piece of cast aluminum that burst apart.
In general. Figure I shows a collection of pieces of metal that have been blasted
apart or twisted. The largest piece (in the background) is about 12 t o 13 Indies
long. I t ' s two inches in diameter, of regular mild steel, and a 3/8 of an Inch long
part was blasted off the end and crumbled like a cookie. Fragments have been analyzed
to have anomalously high silicon content although the original material was not a
silicon steel. The standing piece on the left is 5 - 6 inches t a l l , I and 1/4 Inches
In diameter. It is a piece of case-hardened steel. The case-hardening has been blown
off at the top and about 3/4" o f It vapourized during an experiment. Then there are
various pieces of aluminum and steel. On the right of Figure 2 is a boring bar. You
can s t i l l see the old tool bit that John was using through i t . It was on a shelf about
10 feet away from the centre o f the apparatus and he did not see i t happen. It Just
bent up into a tight U and deposited a quantity of copper at the bend. The copper
seemed t o somehow magically come out of the solid solution. If It was ever in solution
in the first place, and agglomerate as globs at the break. As far as the aluminum is
concerned, i t ' s a volume e f f e c t , not merely an eddy-current surface e f f e c t .
The whole thing is blasted right through.
Figures 3 t o 6 show some of the scanning electron microscope photos taken by the
University o f Toronto. Figure 3 shows an aluminum specimen at about 70 times magni-
fication and the whole surface Is torn apart, as If i t was gouged randomly by some
mechanical means. It has not been smoothed and polished and subject t o x-ray or
dispersion analysis yet. A piece o f iron Is shown In Figure 4 , and was analysed for
composition which showed anomalously high amounts o f copper.
With a l i t t l e higher magnification for Figures 7 and 8, we see what happens in a
polished aluminum sample under the SEM. Figure 7 shows two main horizontal fracture
zones.
is
25. Th* Hutchison Fito
This Is a polished sample, that is why it looks nice and clean. Notice the
unusual globules forming (positions B & CI. We examined these particular
globules and they're virtually pure elements. One is copper, another Is
manganese and others are different elements. These globules seem to arrange
themselves along planes and these piares are no doubt the ones that split
apart and delaminate Into fibers.
Figures 9 and 10 show the relative elemental abundances of locations H and D
of Figures 7 and 8. Normally, the aluminum comes out looking like Figure 9.
The average Is mostly aluminum, of course, but with a bit of copper in it.
And yet (Figure 10) shows an area around where the fractures occur and we see
we have actually located one of the copper blobs, plus some chlorine from our
fingers. Usually you see some chlorine and sodium from salt in your hands If
you're touching samples. It's certainly telling us that something unusual Is
happening. I have not seen another apparatus which makes the alloying material
In an alloy come out of the solid solution. Usually it's totally dispersed
in the melt but In this case we're "undisperslng" it somehow.
The Pharos experimental set-up for the Hutclilson effect
f MS t 1 PIT S i C á t t ftTtf I
This plan view shows the first (1983) set-up under Pharos' control.
I
V
26. Th* Hutchison Fito
Increasing propulsive power is being applied t o this as witnessed by this increasing
acceleration curve. These are the actual measurements t o about 0.16 seconds and beyond,
is an extrapolation. The -9.1 In the acceleration equation Is merely an artifact of my
measuring problem, analyzing that film strip. Keep in mind, this means that when i t
hits the ceiling, this 19 lb. bushing is traveling at 20 m/sec. (45 mph, 72 kmh)
and increasing!
I am at sea In trying t o determine how the device can provide a l i f t . In this
T h e o r e t i c a l background" listing, I mention a few names that might have something t o
do with an explanation of I I
DISCUSSION OF ÜJBRENT t EARLY THEORIES IN
CLASSICAL I OUWIUn PHÏSICS
ENERGETIC EFFECTS PROPULSIVE EFFECTS
6 . UBOH . - HOOPER
VALLEE - HOLT
BUYER - GRAHW1 t LAHDZ
PRIGQG1HE - 2INSSER/PESCHW
P U K K O H R SOI [BIT I MED
L S AY TES mi
Finally here Is a listing of a few potential applications of this e f f e c t i f i t can be
produced In such a format that i t l£ repeatable and controllable: rocket payload assist,
materials handling and warehousing, floating things i n t o position, materials handling
of hot objects, objects that are highly radioactive or dangerous, forging and casting,
extruding of metals, alloying, power production, conversion, etc., and
defence applications.
In conclusion, this is an extremely d i f f i c u l t technology t o wrap one's mind around.
1 have had a great deal o f d i f f i c u l t y In convincing scientists t o think about this
possibility, let alone t r y t o provide some mechanisms for understanding its operation.
24
27. A P P L I C A T I O N S
PROPULSIVE i - HICRO-SRAYirr EHV1ROHCHTS OH EARTH
- R0CŒT PAYLOAD BOOST ASSIST
- MATERIALS HANDLING S VHAREH0US1NG
ENERGETIC FORGING, CASTING, EXTRUDING o r fETALS
ALLOYING
P O O PRODUCTION, CONVERSION t TRAHSfllSSICH
OTKER - DEFENSE APPLICATIONS
ETC, ETC, ETC,
i hope I'll be able t o engender some interest so that people w i l l think
¿bout It. Perhaps some w i l l , if they have some equipment, do some experiments
is well.
1 must caution anyone who is pursuing this t h a t It Is an extremely dangerous
apparatus. It has never knocked any of my fillings out, but it certainly
has a potential for doing so. It has smashed mirrors, in one of its incarnations»
30 feet away. It has overturned a large metal object about 50 or 60 pounds
about 100 feet away. And its effects can't be pinpointed unless we Ye lucky.
We t r y t o find the active area and then we hope that something w i l l happen
but perhaps something very far away w i l l happen. The apparatus is capable oí
starting fires anywhere. It w i l l start fires in concrete, l i t t l e bursts of flame
here and there and i t w i l l cause your main circuits t o have problems. We've blown
fuses out as well as circuit-breakers and large lights.
25
28. ThQ Hutchison Fito
Figure 1- Examples of disruptive phenomena» including a broken bushing.
Figure 2. Two samples of disruptive phenomena: contorsion and segmental isation.
30
29. The Hutchison Fiia
Figure 3. Aluminium specimen from one of John Hutchison's experiments
October 1984 (70x magnification)
Figure 4, Fractured iron rod/bar which Includes regions which were
mapped by x - r a y : see also figures 9 and 10
31
30. The Hutchison File
***•
**•
i*.
' - i •
—-
r
tí jo
10 ir
âr
Figure 14. Field strength measurements during Hutchison e f f e c t
experiments a t about 350KHz, showing strength versus distance
f r o m source
37
31. T7íO Hutchison Filo
L
*»—r- ^¡-TlHiJJad^r;Tt-; r-t^-r -TÍ _ "
i LL_...
Figure 16. Plot of linearly-rising powered take-off of a 19 pound bushing
calculated on an acceleration / t i m e graph.
vt
32. The Hutchison Fito
Letter from Jack Houck
February 28. IBM.
Your recent lener to me suggests you are experiencing more paranormal phenomena than me "normal*
people do. Of course you know thisteof groat interés* to me. 1 meet a tot of people in paranormal re-
search activities wtw describe similar experiences. In general, you are having your mind to out and ao
cess (connect) with remote people and things. I am enclosing my original model paper which provides a
way of thinking about how the mind can go out and access remote information, I know I sent this paper to
you years ago. but it may have been misplaced with all the International traveling you have been doing.
The key point is thai you can leam to control when and where you want your mind lo go. Similarly, you
can bo open lo another (e.g.. Larry or Yin) accessing your thoughts or you can block that by simply
mentally putting those thoughts you do not want others to access in a safe, and dose the door.
I think that It is good to have the capability to sense things, like electromagnetic fields, when you want to.
This can be controlled by setting a goal, making a mental connection to that goal, commanding it to hap-
pen, and than letting go (allowing it to happen). These ere the same basic Instructions I use to leach
people to bend m£tal with their minds. The instructions work reliably when you understand how this can
work, and practice* Tho same applies lo creating additional energy in a generator. In many of your ex-
periments there Is a tot of "normal* energy around (e.g., your microwave mtJor)-1 think you want some*
thing to happen —'thogoalll Your mind goes out and coheres the local available energy which then
creates a force which attempts to achieve the goal The lettlng-go step seems lo be the most important
from all my research and you seem lo do that very well Improving your reliability requires a lot of prac-
tice, a good model, and not thinking about il too much. Further, by making your goals very preciso and
specific, this process can be perfected. Creating a peak emotional event at the time you want the
phenomena event to happen also seems to be an important ingredient.
I have always said that is woi. " . be nice to have a temperature sensing device on a woman who sees her
1
child under a car. As she lifts ihe car off tho child. I think there will be a 20 degrees drop in Ihe local air
temperature, Clejtrty. she has a goal ~ get the car off Ihe child. Thistea peak emotional eveni. She
does not think about not being able to lift a car. The thermal energy in the airteextracted and a force is
cohered which helps her lift the car.
John. I hope this information is useful and good luck In your continued research. Say "Hello* to Yin for
me.
M
Vancouver experimental observation &A+*¿*f *
by Jack Houck fcus ¿^Artfùv&X
August 1685
Section 1 : Summary find Conclusions
During the year 1971, John Hutchison set out to build some Tesla coils. He also is a
collector of old high voltage and static electricity generating equipment, as well as a
gun collector One evening while tinkering with this equipment, creating large sparts
and high voltage effects, he was struck on the shoulder by a piece of metal. He threw it
back toward where it came form and it struck him again. He had accidentally created
what we will call the Hutchison Effect During the ensuing years, he found that by
47
33. ^HutchisonFits ^ ^ t f ^ c ^ / /P&tS&X&J
adjusting the settings on the equipment, things would levitate, move horizontally, bend,
break and explode.
Hutchison met Alexis Pezarro and George Hathaway who had formed Pharos
Technologies Ltd, in search for new innovative technologies. Pezarro and Hathaway
worked with Hutchison, conducting many experiments In attempting to replicate and
understand the phenomena. They also were looking for funds to perform the research
necessary to apply this knowledge. The equipment belongs to Hutchison and is in his
residence. The area in which Ihe majority of the effects occur is determined empirically.
Often major events occur outside the intended "target area" where test objects were
place. In the early days of their experimentation, many hovering and apparently
antigravity-type events occurred.
Hutchison and the equipment have moved twice in last few years, requiring many
months to again obtain effects. During this time, more power and equipment have been
added to the "system". Lately, most of the observed effects have been metal exploding
or bending, and objects moving horizontally or expanding and contracting. A group of
scientists from Los Alamos had witnesses and experiment last year with no results.
On August 13 and 14,1985, this author had the opportunity to witness two evenings of
experiments. I had taken a number of samples to put in the vicinity of the equipment at
the intended target area. Most of the samples and controls left in Southern California, I
took 35 mm pictures, and rented a 1/2-inch home video recording system for documen-
tation and assistance in observation. There were some very interesting events captured
on the video tape, and some of those were observed when they happened. Aluminum
foil pieces and some other samples (including plastic) were observed to slide or fall
over, as if hit by an impulse at apparently random intervals throughout both evenings.
At one point, one of the aluminum foil pieces appeared to move up and down, with a 1-
3 second period,
I was satisfied that no fraudulence was occurring, and was impressed by the fact that
most of the events were covered by the video camera. However, some of the biggest
events occurred outside the intended target area. The first evening, a gun barrel and a
very heavy (60 lbs) brass cylinder were hurled from a shelf in the back comer of the
room onto the floor. Simultaneously, on the opposite side of the room toward the back,
three other objects were hurled to the ground. One was a heavy aluminum bar ( 3/4" by
2-1/2" by 12"). It was bent 30 degrees. Hutchison said that it was straight at the begin-
ning of the evening. Another object was a 15-lb brass bushing. These objects can be
seen falling in the video record, but their initial location is not recorded. I am quite sure
that no one was hiding in that part of the room throwing these objects. I was with both
Hutchison and Pezarro during the entire experiment.
None of samples I had were affected. There was a 4 by 4 array of small magnets set up
in the target area. The first evening these magnets were spread all over because a big
brass cylinder fetl on the board supporting them. It actually fell onto the calculator, but
the calculator continued to function. However, during the second day, no objects fell
48