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Overunity Machines Forum



Partnered Output Coils - Free Energy

Started by EMJunkie, January 16, 2015, 12:08:38 AM

Previous topic - Next topic

0 Members and 8 Guests are viewing this topic.

AlienGrey


AlienGrey

Quote from: AlienGrey on March 07, 2021, 03:52:46 AM
H20power I couldn't agree more !
Oh dear have you still got to translate this off-world text ?

SIL

lancaIV

https://worldwide.espacenet.com/publicationDetails/description?CC=EP&NR=3078241B1&KC=B1&FT=D&ND=5&date=20191106&DB=EPODOC&locale=en_EP#
what we can read :

related  US 2002096511

[0006]    This solution can be considered energy saving as it keeps the temperature of the heated environment constant, that is, the heating effect is reduced or terminated at certain times. The output is controlled by altering the duty factor. By this the assumed electric power is controlled as a consequence of which the heating effect is changed proportionally. It must be noted that in this solution the duty factor is controlled instead of the frequency. This document is good for controlling the output directly. However, the present invention deals with tuning or maintaining the resonance frequency applied in special environment.

0013]    It has been realized that motion of the ions in a given medium generates a significant amount of heat. It has also been realized that when the ions in the ion containing medium are excited in an at least partially closed space at a resonance frequency characteristic of the space, a stationary wave is created during the amplitude modulation of the ions set in motion. As a result of this high-efficiency collisions are induced between the ions resulting in active heat generation. To this properly formed oscillators with alternating polarity are needed to be built in the given space. This requires suitably high-efficient oscillator electronics and controller. By using electronics for monitoring and adjusting the modulating frequency the efficiency may further be enhanced as the energy required for reaching the same temperature is significantly less. The energy demand required for this type of heat generation is entirely different from an electrically powered but ohmic heat generator.
[0020]    The electrodes 5 have a polygonal cross-section or non-constant cross-section having three-dimensional curved generatrices. Their longitudinal axes 8 each shaped as an exponential curve are divergent, i.e. the distance between their longitudinal axes 8 grows exponentially. In another embodiment the electrodes 5 are formed as a section of the sheath of a body of revolution the generating lines of which is each shaped as an exponential curve diverging from their axis of rotation i.e. the distance between the generating lines grows exponentially. At most 1000 V amplitude, 1000-60 000 Hz, duty factor modulated AC voltage is connected to the electrodes 5. The value of the frequency and amplitude of the AC voltage as well as the size of the electrodes 5 for operating the housing 3 of the heating element 1 at the required resonance frequency are determined in a known manner e.g. using Helmholtz resonator calculation. Helmholtz resonator is an acoustic resonator consisting of a tube and a cavity. Practically it is the acoustic equivalent of the LC circuit. Geometric measurements are used for tuning the resonator. The resonance frequency is generated on the basis of Thomson-formula.

[0025]    During the longer and pulsating motion enhanced friction of ions is caused resulting in a greater amount of heat generation in the given medium. The tuned cavity, in this case the inner space of housing 3 is resonance tuned. The value of the resonance frequency is determined by the inner length L and inner cross-section A of housing 3 ( Figure 2 ). The resonance frequency and/or the capacitive factor Ca of the housing is determined in a known manner through relations used for acoustic systems. On the basis of these values the constant multiplier of the function defining the exponential curve of the electrodes 5 can be determined in the known manner. To this wide-ranging technical literature is available from which both Helmholtz and Thomson relations can be learned. The applicable relation: ω 0 = 1 m a C a
Image available on "Original document"
m a = 1 ω 0 2 C aImage available on "Original document"
Wherein ma is the multiplier of the exponential function, that is, in the present example the known exponential function determining the shape of the electrodes 5 is y = ma × a<x> in which y is the active length of the longitudinal axis 8 or generating line of electrode 5. The value of a<x> should be chosen in such a manner that electrode 5 does not contact with the inner wall of housing 3.

[0026]    The resonance frequency may be determined by measurement in such a manner that the frequency applied at the minimum current taken for operating the heating element 1 is the resonance frequency ω0. As heating element 1 is operated at a resonance frequency determined by the physical size of the housing 3 a stationary wave is generated. Because of this stationary wave the energy required for maintaining the process started by the motion of the ions is less than in case of conventional electric heaters. When the control frequency falls outside the range of the resonance frequency belonging to a given housing 3 the mentioned effects cannot be observed. The highest efficiency of the system can be obtained near resonance frequency ω0.


0050]    The graphs of Figure 6 show the temperature/power consumption of an electric oil radiator provided with an ohmic heating element available at the market as compared to the temperature/power consumption of the same type of radiator but provided with the heat generator 43 according to an embodiment of the invention taken as a function of time.
In the Figure the continuous line shows the power consumption of the heat generator 43 according to the invention as a function of time to reach a surface temperature of 80°C of the oil radiator. To this 15 minutes and a power of 30 W were needed.
The dotted line shows the power consumption of the customary ohmic apparatus as a function of time to reach the surface temperature of 80°C. To this 4.5 minutes and a power of 190 W were needed.
It is clear that the solution according to the present invention used less than one sixth of the power used by the ohmic apparatus. This ratio remains the same while the temperature is maintained. The heat generator 43 according to the invention can be realized e.g. in the following manner. The heating element 1 according to the invention can be built in for example in the lower threaded joining part of an oil radiator after the original ohmic heating element is removed. Heating element 1 extends in the housing of the radiator approximately as far as one-third of it. Three-fourths of the radiator is filled with common tap water. In this case the heat transferring external medium 2 between the radiator body and the heating element 1 is common tap water. The radiator is provided with a tap for filling and draining. The air cushion above the external medium behaves as an expansion tank. The heat generation causes gravitational motion of the external medium 2 as a result of which each of the radiator elements and almost its entire surface is heated up. Control electronics 9 is accomplished and connected to the heating element 2 as it has already been described. The electric power for operating control electronics 9 is supplied by the electric network. Control electronics 9 may be placed on the wall or may be mounted on the radiator in a closed insulated box designed for this purpose. A room thermostat may be connected to the apparatus if required to further improve the efficiency of the used energy.


It is clear that the solution according to the present invention used less than one sixth of the power used by the ohmic apparatus.                                               
                                                       https://en.wikipedia.org/wiki/Power_(physics)
            Power is the rate with respect to time at which work is done; it is the time derivative of work:
     P =    d W   d t       where P is power, W is work, and t is time.
                                                                       
                                         190W/30W = 6,.....               "six times" ,reverse " one sixth "( work denomination instead power ?!) 


But :                            4,5 minutes x 190 W = 14,25 Wh           and           15 minutes x 30 W = 7,5 Wh

         
                                         14,25 Wh/7,5 Wh= 1,9     " under two times"

               [0050] ..... This ratio remains the same while the temperature is maintained. ......  : which ? W- ratio or Wh-ratio ?


This patent application became EP-patent office granted !
https://register.epo.org/application?number=EP14833591&tab=main



https://overunity.com/2903/electricity-input-saver/
#006 :   [0070] existent heater can by this device/equipment become improved by this factor



Partnered output coils :  "duty factor","resonance", et cetera related ! And right measurement and peak/average  power/work comparation


peak and average ratio comparison :
https://worldwide.espacenet.com/publicationDetails/biblio?DB=EPODOC&II=1&ND=3&adjacent=true&locale=en_EP&FT=D&date=20081128&CC=RS&NR=20070135A&KC=A#
Electric heater with magnetorestriction spends 3,04 times less energy. In longer time interval temperature is kept by means of a thermostat, at e.g. 23±10C, and the ratio of energies used is 1,82 due to the time intervals when  the air is cooled.
Because of the coefficient of magnetostriction the strip over- temperature is lower. That is how out of total electric energy a part for maintaining the strip over-temperature is decreased by magnetostriction and the part that heats the air is increased, and - subsequently - degree of thermal efficiency of the heat source is higher.

AlienGrey

 :Yeh! this is what we find and up against. ~Or is it ? :o

Yoiu do realise Te4sla showed Marconi his rubbish patent on Electro magnetic electricity.

The Point is does you hypothesis apply to longitudinal dynamic energy ?

lancaIV

Which advantage do I get practical and monetary to use such technologies ?




I give an example :


Portugal ,appartment  80 sqm area , winter minimum 0° Celsius out,wished 20°C in-room temperature : 20° K amplitude






heating with electricity : 4000 Wpeak x 1,8 Primary energy factor ( e-mix) =   90 Wpeak primary energy per sqm




target 1:                                                                                    20 Wpeak low-e primary energy per sqm


target 2:                                                                                    10 Wpeak passive house primary energy per sqm




With 6 times better power usage (30 W   instead 190 W) I would reach target 1,with only 1,9 times better REAL power use factor ( 7,5 Wh/14,25 Wh)  the target 1 NOT REACHED !






                                                                apparent power savings/ real power savings






https://worldwide.espacenet.com/publicationDetails/description?CC=US&NR=4544863A&KC=A&FT=D&ND=3&date=19851001&DB=EPODOC&locale=de_EP




Experiments have been performed in which the conventional resistor ballast of a commercially available fluorescent lamp was removed and replaced by a power supply apparatus according to the present invention.

Using the resistor ballast,an illumination level of 1000 lux at a power consumption of 36 watts was obtained.


However, using the power supply apparatus according to the present invention, an illumination level of 1200 lux was obtained, with a power consumption of 12.5 watts.


That is to say, it was definitely proven that the the efficiency of operation of this fluorescent lamp was improved by 3.5 times, through use of the power supply apparatus according to the present invention.

applying :

https://worldwide.espacenet.com/publicationDetails/biblio?DB=EPODOC&II=0&ND=3&adjacent=true&locale=de_EP&FT=D&date=19900201&CC=DE&NR=3817730A1&KC=A1


Effect ?






other example :


https://worldwide.espacenet.com/publicationDetails/description?CC=US&NR=5130608A&KC=A&FT=D&ND=3&date=19920714&DB=EPODOC&locale=de_EP




In one example, the module circuit is adjusted to produce 4,000 pulses per second with a pulse width of about 10 microseconds (with an average resting interval of about 240 microseconds), a load of 100 ohms, and a charging potential of 100 volts.


Using Ohm's Law, these conditions would produce 100 watts of peak power.


Using Equation I, the average power in the Example 1 can thus be calculated, i.e., about 4 watts.


Assuming that the power dissipated in the module itself is approximately 8 watts, the total average energy consumed is the sum of energy expenditure due to load and energy dissipated in the working module, namely a grand total of about 12 watts.


Clearly, the average power consumed in the pulsed incandescence of a light bulb under the control of the inventive module of this example is as low as almost one-tenth the amount consumed in a conventional AC power supply for an incandescent light bulb.


Applying :


https://worldwide.espacenet.com/publicationDetails/biblio?DB=EPODOC&II=7&ND=3&adjacent=true&locale=de_EP&FT=D&date=20110518&CC=CN&NR=201836980U&KC=U


The utility model has the significant effects that: the thermal conductivity is high, and the heat transfer speed is also high; the high-efficiency energy-saving heater is easy to manufacture; the operating cost is low, and only 100W power is needs for heating within 20 square meters due to the infrared heater; and the high-efficiency energy-saving heater can be conveniently moved, and can be widely applied for heating in households, schools, shopping malls, offices, factories, farms, bath centers and other places.




Effect ?


Reaching target 1 ? 2 ?


IR heating  + PV 


https://www.google.com/search?rlz=1C1AVFC_enPT930PT930&ei=bSFFYKHwIYGflwTwwb_gBg&q=infrared+heating+and+pv&oq=infrared+heating+and+pv&gs_lcp=Cgdnd3Mtd2l6EAwyCAghEBYQHRAeMggIIRAWEB0QHjIICCEQFhAdEB4yCAghEBYQHRAeMggIIRAWEB0QHjoJCAAQsAMQBxAeOgcIABCwAxAeOgQIABATOggIABAWEB4QEzoKCAAQFhAKEB4QEzoICAAQxwEQowI6AggAOggIABDHARCvAToECAAQQzoECAAQCjoGCAAQFhAeUJ87WISSAWDFoQFoAnAAeAKAAcsBiAGYGZIBBzEzLjE2LjGYAQCgAQGqAQdnd3Mtd2l6sAEAyAEKwAEB&sclient=gws-wiz&ved=0ahUKEwjh2sfK7Z7vAhWBz4UKHfDgD2wQ4dUDCA0


The IR heater and "artificial PV" combination ?!


Artificial PV-chamber with          C.O.P. 10   in design        as   PRIMAERENERGIEFAKTOR fP-Divisor               


https://translate.google.com/translate?sl=de&tl=en&u=https://de.wikipedia.org/wiki/Prim%25C3%25A4renergiebedarf








Without doubts only spending 100 W electricity as body heating/cooling would be very ecologic




Daimler Benz R&D

https://worldwide.espacenet.com/publicationDetails/biblio?DB=EPODOC&II=12&ND=3&adjacent=true&locale=en_EP&FT=D&date=19910620&CC=DE&NR=4038167A1&KC=A1


Heatable clothing or heated beds can represent a considerable potential for savings, because with heated suits (150 days a year, 100 W, 24 hours for 62 million German citizens) just 2% of the energy of 1015 kcal used today in Germany for heating. Making air-permeable padded clothing is not a problem.[/font][/size]


similar eco-idea :


https://spectrum.ieee.org/energywise/energy/environment/wristify-thermoelectric-bracelet-would-reduce-energy-consumption
https://embrlabs.com/pages/research   https://escholarship.org/uc/item/5f2876gr




but our houses need in average minimum 15°C in-room temperature cause humidity and condensation ; fungi,textiles  and health riscs

Beside the minimum temperature demanded by law :


https://translate.google.com/translate?sl=de&tl=en&u=https://www.mieterbund.de/index.php?id%3D442%23:~:text%3D%28dmb%29%2520W%25C3%25A4hrend%2520der%2520Heizperiode%252C,Deutsche%2520Mieterbundes%2520%28DMB%29%2520mit.




                                                             ecology versus reality
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The Point is does you hypothesis apply to longitudinal dynamic energy ? 


Could you explain me "longitudinal dynamic energy" ?