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DE3826890
Method for influencing the
degree of order of an inorganic or organic system by using
the change, occurring in the area of action of a hollow
pyramid
The invention an included method to the interference of
the order measure of an inorganic or organic system by
utilization itself of the change of the there otherwise dominant
earth's magnetic field portion adjusting in the effective range
of an hollow pyramid.
The word “system” referred in this context each form of
inorganic or organic structures, begun with simple molecules up
to organisms of all type. The bottom term “order measure” is to
be understood the respective energy content of such a system.
Methods of the mentioned type are for example in the CS-PS
91,304, the EP-A 84,108 449,4, in the DE-GbmS 84 60 071,3 and in
an article of Karel Drbal “the fight and the pyramid patent” in
a book “Pyramid power” from max of Toth, Freiburg 1977,
described and will among other things used to affect on organic
or inorganic substances, in addition, small organisms in order
to affect their properties in certain sense.
With most described methods so called “Cheopspyramiden” becomes
used, i.e. Pyramids with an inclination angle of 51 DEG 51 min
51 min min. They consist either of iron sheet metal, copper
sheet, aluminium sheet, wood, plastic, cardboard or other
materials, whereby both ferromagnetic, and paramagnetic or
dia.-magnetic materials come to the application, whose volume
susceptibility is appropriate etw for range of -10, i.e.
throughout above a value is settled of -15.
In the technology one understands bottom magnetic susceptibility
(measure of the magnetizability of a cloth) the difference mu g
1, where again the mass susceptibility
EMI7.1
the magnetic permeability of a cloth related to the permeability
of the empty space is. The value mu represents the absolute
permeability of a cloth and is derived from the ratio of the
magnetic induction to the magnetic field strength, so that thus
EMI7.2
is.
For the evaluation of pyramid materials the term of the volume
susceptibility is more meaningful, which becomes general used in
the Magnetochemie. Afterwards the susceptibility is on the space
measure of 1 cm< 3> based (volume susceptibility chi v),
while in each case the susceptibility based on 1 g of the
respective cloth is chi g (= mu r) again the mass
susceptibility. Thus the designation results
EMI8.1
where D (= alpha) is the density of the respective cloth.
So for example copper has a density of 8,9, a mass
susceptibility of -1,08 and a volume susceptibility of -9,6,
urea a density of 1,3, a mass susceptibility of -7,0 and a
volume susceptibility of -9,1, bismuth a density of 9,7, a mass
susceptibility of -16 and a volume susceptibility of -155,2 etc.
The dimensions of the known pyramids with mostly square base
surface are appropriate for generally high-moderate between
approximately 20 cms and 30 cms, while the soil edge measure
lies for instance between 20 cms and 50 cms. Therefore the
pyramids are down open and have the form of an hat, which can be
inverted to light substrate which can be affected over that.
With the prior art processes will among other things desired,
the growth of small organisms, as for example worms or plant
cultures to promote and/or. to reach with these a larger
resistance against health influences. Furthermore attempted one
to improve and prevent with organic or inorganic cloths old
features the topping-up of foods by pyramid influence.
It has itself shown that become achieved with the prior art
processes only very uncertain results. Thus it turned out that
for example whole snail clutches of eggs or plant cultures died,
instead of developing. Similar experiences became also made with
embryos of other type. Whole general did not occur the desired
success and frequent became the opposite of that achieved, which
intended was.
By the invention the solve the problem are to become to avoid
those with that so far prior art processes of occurred misses
and a larger reliability with the achievement of the desired in
each case technical effect obtained.
This object becomes, on the basis of a method the interference
of the order measure of an inorganic or organic system by
utilization of the change of the there otherwise dominant
earth's magnetic field portion of the initially mentioned type,
according to the invention adjusting in the effective range of
an hollow pyramid that the earth magnet partial field by at
least one, dissolved by the fact, essentially in the local
inclination angle inclined hollow pyramid side on preferably on
the inside, bottom or in next vicinity of the pyramid, formed
aligned with the inclination-planar to the magnetic north south
direction, from dia.-magnetic material, system brought directed
will and the system becomes its natural development time of the
pyramid influence exposed essentially in the long run.
The inclination angle amounts to for example in hammer-fixed 77
DEG, in Munich 67 DEG, in Rome 55 DEG, in Calcutta 30 DEG in
Ceylon 0 DEG. In each case the geographical areas located
between them the inclination angle has corresponding
intermediate values, but has itself shown the fact that the
technical success desired with the invention process occurs also
if plus or minus up to 7 DEG from in each case at the procedure
place valid inclination angle is deviated.
The invention included in addition an hollow pyramid to the
embodiment of the invention process, which by the fact
characterized is that at least one pyramid side is bottom
inclination angle inclined relevant for the application place
and that zumindestens this pyramid side consists of
dia.-magnetic material with a volume susceptibility below -15.
As material for this pyramid side and/or. for the embodiment of
the whole pyramid are suitable brass, zinc, silver, bismuth,
graphite or ytterbium with in each case a volume susceptibility
of below -15. In modification its knows the respective pyramid
side or also the whole hollow pyramid from an alloy or
composition of coppers with brass, zinc, silver, bismuth,
graphite or ytterbium and/or. of copper sheet with an oxide
layer consists, whereby the volume susceptibility of these
alloys and/or. Is appropriate for compositions below -15 in each
case.
In modification its can consist the hollow pyramid according to
invention of a composition of plastic, preferably epoxy resin,
with copper, copper sheet with oxide layer, brass, zinc, silver,
bismuth, graphite or ytterbium, whereby again the volume
susceptibility of this composition lies below -15.
The term “composition” covers copper sheet in this context for
example with bonded, galvanic applied, evaporated, up-sintered,
sprayed, applied or on other manner applied coats or several
that in each case different components.
The hollow pyramid according to invention is favourable as
straight pyramid with regular polygonal base surface formed.
Preferably the base surface of the hollow pyramid has the form
of an equilateral triangle or a square, whereby a pyramid side
exists made of graphite, bismuth or brass and the remaining
pyramid sides from preferably transparent plastic formed are.
After a modified embodiment of the hollow pyramid according to
invention a pyramid wall flat-moderate can out-seize over de
Pyramidenumriss and preferably have rectangular shape. This
applies in particular if this pyramid wall opposite the other
pyramid walls from another material formed is.
After an other embodiment of the hollow pyramid according to
invention to each other parallel intermediate walls are disposed
in the pyramid-inner, which are the bottom inclination angle
inclined. These intermediate walls can fill out either the
interior hollow pyramid whole or but have with their bottom
edges a certain distance of the pyramid lower surface, in order
to offer space for a substrate which can be brought in.
In the extreme case the pyramid base surface can as regular
infinite polygon, i.e. present themselves as circle the formed
its and thus pyramid as straight circle cones.
In development of the invention an hollow pyramid according to
invention with or several similarly shaped pyramids to a pyramid
battery a summarized can be.
This can take place according to the invention either by means
of the fact that the same at one and/or. several their basis
edges with a basis edge of one and/or. several adjacent (n)
pyramid (n) fixed or releasable connected for its part if
necessary in each case is, those in same way with one and/or.
several neighbour pyramid (n) connected is and/or. are. An
against-intimate half edge seamed joint can serve or but the
hollow pyramid is with that or the neighbour pyramids side face
against side face together resting fixed or releasable
connected, those for its part if necessary in each case in same
way with one and/or as releasable connection between the hollow
pyramids either. several neighbour pyramid (n) connected is
and/or. are. If a fixed connection exists between the neighbour
pyramids, then the same can at that and/or. the bordering side
(n) in each case a common wall with the neighbour pyramid have.
If a releasable connection is provided in the contrast for this
between the adjacent hollow pyramids, then these as multipoint
push button connection formed can be.
The hollow pyramid according to invention is at least 1 cm high
and can a maximum height of approximately 30 m have.
The wall thickness of the hollow pyramid according to invention
amounts to at the most 25% and at least 0.01% of the surface
area diagonal measure and/or. the cone base circle diameter. The
base surface of the hollow pyramid according to invention is
preferably open.
The finally included invention an application of the invention
process and/or. the hollow pyramid according to invention on the
development improvement the subsequent inorganic organic
systems:
a) Formation of crystals in solutions, for example copper
sulfate or Kaliumchromat;
b) Breeding of Kleinstlebewesen such as bacteria or funguses,
for example Proteus mirabilis or yeast, outside of or within
nutrient solutions;
c) Improvement of the development of seed, for example bean,
flax or poppy seed, seed grain;
d) Improvement of the development of embryos like e.g.
Froschlaich, Forellen or Hechteier;
e) Taste improvement of life or luxuries;
f) Durability improvement of life or luxuries.
Experiments of the inventor with the invention process have
shown that contrary to the prior art processes with the
invention process the desired in each case effect with large
safety occurs and misses practical did not arise at all. These
experiments shown in addition that the application of the
invention process is larger substantial, than one had suspected
in connection with prior art processes.
In a brochure “Pyron force from the cosmos”, published in Pisa,
describes professor Erich Mueller, Castelnuovo, Versuche, whom
it has with known pyramids on in aquariums living person,
particularly joyful, flat-shelled worms of the genus
Isognostaoma performed, at whose Laich the development
particularly good to be observed is. The clutch of eggs of such
worms usually covers between eight and twelve eggs.
With simultaneous control snails of this species examined
without pyramid effect the development normal ran, i.e. all eggs
grew up up to hatching coordinated to each other. In the same
clutch of eggs the same development step resulted in each case
in the case of all eggs.
With the worms, which had been already spent before the
Laichablage a bottom known Cheopspyramide, shown itself that the
eggs, although they were all of the same age exhibited in each
case various development steps. So eggs could be found after
approximately three to four weeks after Laichablage in in and to
the same Laichpaket, which were still in one much early stage,
while other eggs had already its Schneckenhaus formed and almost
slip-mature were. After approximately the same time however the
entire clutch of eggs died and it came never more to leaving the
Eihäute as well as the Gallerthülle. Initial one was to be
observed also with these worms a significant acceleration of
their embryonic development opposite the control snails. The
inventor of the invention process has these experiments likewise
with Cheopspyramiden repeated and the same negative result
achieved.
It was from the beginning the conviction of the inventor of the
invention process that would have to succeed with this to obtain
and make this in any form uniform and reliable results of the
pyramid effect more measurable.
The inventor repeated Mueller min snail attempts with the
invention process schen. The result was surprising: It shown
itself that the examined eggs were almost without exception
slip-mature after approximately three weeks and that also in the
future essentially the whole clutch of eggs viable remained.
Encouraged by this favorable experimental result the inventor
expanded its experiments since Froschlaich, Fischlaich and yeast
cultures (Bierhefe and red increasing yeast). Also here shown
itself that with application of prior art processes, which
became performed by means of Cheopspyramiden in particular
primarily with Froschlaich a very high number of deaths ratio
occurred, while observed with application of the invention
process almost no negative effects could become on the examined
cultures. With experiments with algae in the water and with
moistened Kressensamen again the observation became confirmed
that the prior art processes affect themselves whole general
growth-retarding, while with application of the invention
process prospering the organisms substantial runs more
favorable.
With the treatment of inorganic substrates the shown invention
process opposite the prior art processes of substantial more
favorable results. While for example became achieved with
application of prior art processes on the crystallization of
copper sulfate or Kaliumdichromat essentially only normal
crystals, the crystallization of copper sulfate resulted in
partly even only anomalous stunted crystals in the case of
application of the invention process beautiful, deep-blue,
parallelogram-like crystals up to 5 cms edge length. In the case
of the formation of Kaliumdichromatkristallen arose rectangular
to square, orange boards from 1 cm to 2 cms edge length.
With the fact is detected that become promoted by application of
the invention process both organic and inorganic life
procedures. This finding might open a very substantial technical
importance for the invention.
The invention process and some embodiments of the hollow pyramid
according to invention become now for example in detail
described on the basis the lying close schematic designs. In the
designs represent:
Fig. 1 a scheme for an
embodiment of the invention process,
Fig. 2 a scheme for an
other embodiment of the invention process,
Fig. 3 a diagram of an
hollow pyramid according to invention to the embodiment of the
invention process, which should find for instance in the space
Munich application, approximate on a scale 1: 3,
Fig. 4 on supervision on
in Fig. 3 hollow pyramid shown,
Fig. 5 a diagram in the Fig. 3 and 4 hollow pyramid
shown, toward the arrow V in Fig. 4 seen,
Fig. 6 a section by in the Fig. 3 to 5 pyramid shown
along the plane VI-VI in Fig. 4,
Fig. 7, like it for
instance in the space hammer-fixed to the application to come,
approximate on a scale 1 could do 7 a diagram of an hollow
pyramid according to invention: 150,
Fig. 8, like it into for
instance in the space Rome to the application to come,
approximate on a scale 1 could do 8 a diagram of a pyramid
according to invention: 150,
Fig. 9 a supervision on
another embodiment of an hollow pyramid according to invention,
approximately on a scale 1: 10,
Fig. 10 a supervision on
an other modified embodiment of an hollow pyramid according to
invention, approximately on a scale 1: 10,
Fig. 11, like it for
instance in the space Munich to the application to come, again
approximate on a scale 1 could do 11 a diagram of a still other
embodiment of an hollow pyramid according to invention: 10,
Fig. 12 a supervision on
in Fig. 11 hollow pyramid shown,
Fig. 13 a diagram of one
again modified embodiment of an hollow pyramid according to
invention as cones, like it for instance in the space Munich use
to find could do, again on a scale of approximate 1: 10,
Fig. 14 an overview of
Fig. 13 hollow pyramid is shown
Fig. 15 a diagram of a
pyramid arrangement according to invention, like it for instance
in the space Munich application to find could do, again on a
scale of approximate 1: 10,
Fig. 16 a plan view on
in Fig. 15 pyramid arrangement shown,
Fig. 17 a section by in
the Fig. 15 and 16 pyramid arrangement shown along the plane
XVII XVII in Fig. 16,
Fig. 18 a section
similar Fig. 17 by a modified embodiment of a pyramid
arrangement the similar Fig. 15 to 17,
Fig. 19 a cross section
by the touching pyramid-flat of a detachable hollow pyramid
arrangement essentially in accordance with the Fig. 15 to 17,
Fig. 20 a diagram of
another embodiment of an hollow pyramid arrangement according to
invention approximately on a scale 1: 30,
Fig. 21 a supervision on
in Fig. 20 pyramid arrangement shown,
Fig. 22 a fragmentary
view of a single pyramid in the Fig. 20 and 21 represented
pyramid arrangement according to invention and however
detachable,
Fig. 23 an oblique view
of an other embodiment of an hollow pyramid according to
invention, and
Fig. 24 a section by an
again other embodiment of an hollow pyramid after the invention.
The dimensions, yardsticks and in particular wall thicknesses of
the various represented hollow pyramids indicated in the designs
are not for the practical embodiment the same by any means
binding. Considerably for this rather the material, is
manufactured made of which the respective hollow pyramid, is
naturally also their respective kind of manufacture. Same
numerals designate same in each case or equivalent acting parts
and are if necessary provided with subscripts.
With in Fig. 1 represented scheme of an embodiment of a method
to the interference of substrates the referred reference letter
A an oblique hollow pyramid with oblique-winkelig--triangular
plan view, whose is a pyramid wall Aa a bottom angle beta
against the horizontal inclined, which inclination angle
relevant for the application place corresponds. The
inclination-planar is by the dash-dotted registered trace lines
off and AC indicated. Like apparent, the pyramid A with their
inclination-planar is accurate aligned on the magnetic north
south direction.
The down open pyramid A is inverted over a substrate B, which in
a receptacle C is. If it concerns with the substrate for example
seed, then the same remains to its natural Keimzeit the bottom
pyramid at least in the long run, so that at the execution place
of the method and by their pyramid side Aa can affect dominant,
by the pyramid A at least in particular on the substrate B
concentrated earth magnet partial field on the period of the
natural germination the seed. As result it shows up that the
percentage of begun to germinate seed amounted to with
application of the just described method about 70% of the
treated good one, while the same constituted 42% during
non-application of the method only.
Fig. 2,a procedure arrangement shows 2, with which a straight
pyramid A min square in the plan view, whose is all four pyramid
sides against the horizontal in the angle beta inclined, is
inverted over an aquarium D likewise square in the plan view, in
which Hechteier E are. It became the time measured, until all
young fish had slipped. The experiment became then shown with a
Cheopspyramide repeated and it that during the same time
interval still none of the young fish had slipped.
The Fig. 3 to 6 represents an hollow pyramid with square base
and an inclination angle beta 1 of 67 DEG, how it corresponds to
Munich in for instance the earthmagnetic inclination angle for
the space. The wall thickness D of the hollow pyramid is
exaggerated strong shown and might with an height dimension of
the pyramid between approximately 15 cms and 30 cms with
fabrication of the hollow pyramid from copper sheet
approximately between 0.5 mm and 1.5 mm amount to. If such a
pyramid becomes from other material manufactured, then or must
its wall thickness can become naturally also corresponding large
selected.
The height dimension between 15 cms and 30 cms is in particular
appropriate for lab uses of the hollow pyramid. For industrial
applications substantial larger dimensions are more conceivable
and therefore naturally also larger wall thicknesses.
Such a hollow pyramid of larger dimension is for example in Fig.
7 in the diagram shown. The pyramid basis is again square. The
pyramid-high can amount to in this case up to 30 m, the wall
thickness of the pyramid calculated itself from used in each
case the material for their fabrication after static aspects.
The pyramid inclination angle beta 2 amounts to in this cases 77
DEG, which equals an use of the pyramid in the space
hammer-fixed, where the inclination angle of the earth's
magnetic field in approximately this amount corresponds.
In Fig. 8 is an hollow pyramid again with square pyramid basis
in the diagram shown, whose pyramid inclination angle beta 3
corresponds to a value of 55 DEG, which equals again the
inclination angle of the earth's magnetic field for the space
Rome. The height dimension of this pyramid can amount to for
example 7.5 m. The pyramid wall thickness depends also here
again on the used building material.
Fig. an hollow pyramid shows 9 in plan view, whose pyramid basis
is an equilateral triangle. Such a hollow pyramid could be for
example again from copper sheet manufactured and have depending
upon its geographical use area and the pyramid inclination angle
conditional thereby an height of v about 80 cms until 1.50 m.
In Fig. a regular five-angular pyramid basis has 10 hollow
pyramid shown. Their dimensions depend again on its use, its
place of use and the material, from which them are to be
manufactured.
The base in the Fig. the form of a regular Achtecks has 11 and
12 represented hollow pyramid. Its inclination angle beta 4
amounts to, if it is to find in the space Munich use, again
about 67 DEG.
The Fig. 13 and 14 shows an hollow pyramid, whose base
infinite-hit a corner, i.e. a circle is and their form
consequently that of a cone assumes. The cone angle b 5 amounts
to, if this Sonderbauart of an hollow pyramid is to the use in
the space Munich certain, again 67 DEG.
The Fig. 15 to 17 shows a combination of three hollow pyramids
1, 2 and 3 in each case a type in accordance with the Fig. 3 to
6 to a multiple pyramid, whereby the adjacent pyramid walls 1a
and 2a and/or. 2b and 3a depending upon the material, made from
which the pyramids are 1, 2 and 3, with one another soldered,
bonded or welded to be can. A sectional view of such an hollow
pyramid arrangement is from Fig. 17 apparent.
Fig. a modified spatial form of such an hollow pyramid
arrangement shows 18, with which the adjacent walls of the
affecting pyramids 1, 2 and 3 in each case to a common wall 2C
and/or. 2d summarized are. The hollow pyramid arrangement in
accordance with Fig. 18 represents thus an integral body,
depending upon the material used to his fabrication either by
soldering together or welding together and/or. Stick single
triangular tiles or in addition, by pouring, syringes or presses
from a piece manufactured to be can.
One wants an hollow pyramid arrangement in accordance with the
Fig. 15 to 17 makes auseinandernehmbar, then the adjacent
pyramid walls 1a and 2a can and/or. 2b and 3a in in Fig. 19
manner shown by pushbutton connections releasable connected with
one another its, those, as in Fig. 19 shown, in simple manner by
pins with ball head formed to be can, which are put to pyramid
wall an attached and through a bore of the other pyramid wall in
each case.
The Fig. 20 and 21 shows an hollow pyramid battery, which is
formed from 64 single pyramids with square in each case base.
The pyramids can be depending upon used material their
together-pushing basis edges soldered with one another, welded
or bonded in each case and are for better stability convenient
on a corresponding square lattice framework fitted. In Fig. 20
is with 4 in chain lines an placed underneath trough indicated,
in which the substrate which can be affected with the pyramid
battery is.
One wants that the single hollow pyramids in the Fig. 20 and 21
hollow pyramid battery shown single from each other more
separable is, then the basis edges of these single pyramids with
an against-intimate half edge seamed joint equipped can be, like
them Fig. 22 shows. The half edge seamed joint exists in each
case at each edge of over the half edge length an extending,
downward open rebate ä and itself over the remainder of the edge
extending, upward open rebate 5b. The rebates are so in each
case against-intimate mounted at the pyramid base edges that
they complement each other with Aneinanderstossen of two pyramid
edges mutual and so a releasable clutch zwische form for the
adjacent pyramid base edges.
In Fig. 23 represented skew hollow pyramid 6 exhibits a plan
view in form of a skew triangle. One of the pyramid walls 6a,
6b, 6c, i.e. the pyramid wall 6a, is opposite that horizontal
around the local inclination angle beta inclined. The trace of
the inclination-planar is in the drawing 2 indicated by the
chain lines s 1 and s. The pyramid wall 6a seizes in addition,
as from the drawing apparent, over pyramid-outlined outside and
has with the illustrated embodiment the form of a rectangle.
Preferably the pyramid wall 6a consists of graphite, while the
two other pyramid walls 6b and 6c can consist in each case of
preferably transparent plastic. In the use the pyramid becomes 6
again so established that the inclination-planar s 1, s 2 cuts
the pyramid wall 6a vertical, which in the drawing by the right
angle gamma indicated is. The pyramid wall 6a and/or. the
pyramid walls 6b and 6c can be naturally also from other
materials made. The limitation did not pyramid-outline spreading
part of the pyramid wall 6a needs rectangular to be, but can
also different form have, for example thus triangular or
parabolic and/or. semicircular its.
In Fig. 24 is an other embodiment of an hollow pyramid to the
embodiment of the conscious method shown. This hollow pyramid 7
is preferably a straight pyramid with square or
equilateral-triangular plan view. The pyramid sides 7a are the
preferably bottom local inclination angle against the horizontal
inclined. With this embodiment of the pyramid represented in the
vertical agent profile to each other paralle intermediate walls
are 7b disposed in the pyramid-inner, which for its part again
to one that the bottom inclination angle beta inclined pyramid
outer walls 7a parallel runs. These parallel intermediate walls
7b can fill out the pyramid up to the base, leave however, as
preferably in the drawing shown, above the pyramid basis a
clearance open, in which a that can become substrate contained
vessel 8 housed which can be treated.
Like already multiple mentioned, the mode of production of the
single hollow pyramid arranges itself and/or. the described
multiple pyramids or hollow pyramid batteries in each case after
the dimensions the same, the used material and the place of use
and/or. - purpose of the respective arrangement. Case of sheets
or plastic boards used will, can the single boards through in
each case solders, welding or sticking connected with one
another be and/or. with large sizes naturally also different
connecting kinds can find such as rivets or mutual bolting
application. Substantial one for the function of the respective
hollow pyramid and/or. Hollow pyramid arrangement in the sense
of the feedthrough of the described method is the adherence to
the material regulation and the adherence to the inclination
angle relevant for the respective place of work as inclination
angle for the respective pyramid wall (EN) as well as the
alignment of the pyramid on the earthmagnetic north south
direction.