Selfrunning Free Energy devices up to 5 KW from Tariel Kapanadze

[bringdownthezog]

http://www.youtube.com/watch?v=KQtRz0CbJmE

[zcsaba77]

The electronics of flyback driving circuit was powered by 220V / 300mA. If flyback was connected to capacitors with spark gap only they was drawing up to 340mA.
The additional 14mA was consumed when coil-capacitor with load was attached to it.

So now you can calculate yourself

Hi T-1000

If I good understood initial power was (free run) 220 x 0.34 = cca 75W, and if loaded add 220 x 0.014 = cca 3W, you try loaded by more bulb see the effect?

regards zcsaba77

[00]

hello Grum! and all!

tunning  setup for chubindze coil

image below

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hello Grum! and all!

non oxydized copper!

Things You'll Need
Baking soda
Lemon juice
Salt
Vinegar
Flour
Soft bristled toothbrush
Show More Instructions

1
Make a paste of 1/2 cup vinegar, 1/2 cup of salt and 1/2 cup of flour. Apply the paste to tarnished copper, being sure to get into all crevices and allow to sit for 15 minutes. Use a damp soft bristled toothbrush, a discarded electric toothbrush works great, to gently scrub the surface. Rinse the object with clean cool water and polish dry with a soft dry cloth.

2
Moisten salt with lemon juice to create a cleaning solution for oxidized copper. The salt will work as a gentle abrasive and the acid in the lemon juice will cut through oxidation. Scrub the tarnished object with a soft cloth to remove tarnish. Use an old soft bristled toothbrush to get into decorative scrolls or crevices. Rinse with cool water and buff to a shine.


3
Try lemon juice and cream of tartar for cleaning copper. Mix a paste and apply to the copper object using a soft bristled toothbrush. Be sure to give the entire piece a good scrub and allow to set for 15 minutes. Rinse clean with clear water and buff to a shine.

4
Clean small objects by adding 2 tbsp. of salt and a cup of vinegar to a pot of water. Boil the object in this solution for 20 minutes. Remove and rinse clean with cool water. If residue remains in crevices or small parts, use a soft bristled brush to clean. Dry thoroughly and buff to a shine with a clean soft cloth.

5
Clean large objects with lemon juice and salt. Try sprinkling salt onto a lemon half and polishing with the lemon. Add more salt whenever needed. Remove stubborn areas with a soft bristled brush saturated with lemon juice. Rinse and polish with a soft clean cloth.

6
Coat clean and dry copper objects with a clear lacquer to seal in shine and seal out tarnish.

Tips & Warnings
Many copper objects are already sealed with a lacquer finish to prevent oxidation. To maintain the appearance of these objects, simply dust or wash with a mild detergent and water. Using harsh chemicals may remove the protective coating and cause your copper to oxidize.

00

[00]

hello Grum! and all!

non oxydized copper!

Things You'll Need
Baking soda
Lemon juice
Salt
Vinegar
Flour
Soft bristled toothbrush
Show More Instructions

1
Make a paste of 1/2 cup vinegar, 1/2 cup of salt and 1/2 cup of flour. Apply the paste to tarnished copper, being sure to get into all crevices and allow to sit for 15 minutes. Use a damp soft bristled toothbrush, a discarded electric toothbrush works great, to gently scrub the surface. Rinse the object with clean cool water and polish dry with a soft dry cloth.

2
Moisten salt with lemon juice to create a cleaning solution for oxidized copper. The salt will work as a gentle abrasive and the acid in the lemon juice will cut through oxidation. Scrub the tarnished object with a soft cloth to remove tarnish. Use an old soft bristled toothbrush to get into decorative scrolls or crevices. Rinse with cool water and buff to a shine.


3
Try lemon juice and cream of tartar for cleaning copper. Mix a paste and apply to the copper object using a soft bristled toothbrush. Be sure to give the entire piece a good scrub and allow to set for 15 minutes. Rinse clean with clear water and buff to a shine.

4
Clean small objects by adding 2 tbsp. of salt and a cup of vinegar to a pot of water. Boil the object in this solution for 20 minutes. Remove and rinse clean with cool water. If residue remains in crevices or small parts, use a soft bristled brush to clean. Dry thoroughly and buff to a shine with a clean soft cloth.

5
Clean large objects with lemon juice and salt. Try sprinkling salt onto a lemon half and polishing with the lemon. Add more salt whenever needed. Remove stubborn areas with a soft bristled brush saturated with lemon juice. Rinse and polish with a soft clean cloth.

6
Coat clean and dry copper objects with a clear lacquer to seal in shine and seal out tarnish.

Tips & Warnings
Many copper objects are already sealed with a lacquer finish to prevent oxidation. To maintain the appearance of these objects, simply dust or wash with a mild detergent and water. Using harsh chemicals may remove the protective coating and cause your copper to oxidize.

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hi Grum! and all!

AVIATION ALLUMINIUM

2xxx, 3xxx, 5xxx, 6xxx, and 7xxx series alloys are widely used in aviation. The 2xxx series is recommended for operation at high working temperatures and with high destruction viscosity rates. 7xxx series alloys – for operation at lower temperatures of highly-loaded parts and for parts with high resistance to corrosion under stress

GENERAL ALUMINUM INFORMATION1100
This grade is commercially pure aluminum. It is soft and ductile and has excellent workability. It is ideal for applications involving intricate forming because it work hardens more slowly than other alloys. It is the most weldable of aluminum alloys, by any method. It is non heat-treatable. It has excellent resistance to corrosion and is widely used in the chemical and food processing industries. It responds well to decorative finishes which make it suitable for giftware.
2011
This is the most free-machining of the common aluminum alloys. It also has excellent mechanical properties. Thus, it is widely used for automatic screw machine products in parts requiring extensive machining.

2014 & 2017
The 2017 alloy combines excellent machinability and high strength with the result that it is one of the most widely used alloys for automatic screw machine work. It is a tough, ductile alloy suitable for heavy-duty structural parts. Its strength is slightly less than that of 2014.

2024
This is one of the best known of the high strength aluminum alloys. With its high strength and excellent fatigue resistance, it is used to advantage on structures and parts where good strength-to-weight ratio is desired. It is readily machined to a high finish. It is readily formed in the annealed condition and may be subsequently heat treated. Arc or gas welding is generally not recommended, although this alloy may be spot, seam or flash welded. Since corrosion resistance is relatively low, 2024 is commonly used with an anodized finish or in clad form ("Alclad") with a thin surface layer of high purity aluminum. Applications: aircraft structural components, aircraft fittings, hardware, truck wheels and parts for the transportation industry.

3003
This is the most widely used of all aluminum alloys. It is essentially commercially pure aluminum with the addition of manganese which increases the strength some 20% over the 1100 grade. Thus, it has all the excellent characteristics of 1100 with higher strength. It has excellent corrosion resistance. It has excellent workability and it may be deep drawn or spun, welded or brazed. It is non heat treatable. Applications: cooking utensils, decorative trim, awnings, siding, storage tanks, chemical equipment.

5005
This alloy is generally considered to be an improved version of 3003. It has the same general mechanical properties as 3003 but appears to stand up better in actual service. It is readily workable. It can be deep drawn or spun, welded or brazed. It has excellent corrosion resistance. It is non heat-treatable. It is well suited for anodizing and has less tendency to streak or discolor. Applications same as 3003.

5052
This is the highest strength alloy of the more common non heat-treatable grades. Fatigue strength is higher than most aluminum alloys.In addition this grade has particularly good resistance to marine atmosphere and salt water corrosion. It has excellent workability. It may be drawn or formed into intricate shapes and its slightly greater strength in the annealed condition minimizes tearing that occurs in 1100 and 3003. Applications: Used in a wide variety of applications from aircraft components to home appliances, marine and transportation industry parts, heavy duty cooking utensils and equipment for bulk processing of food.

5083 & 5086
For many years there has been a need for aluminum sheet and plate alloys that would offer, for high strength welded applications, several distinct benefits over such alloys as 5052 and 6061. Some of the benefits fabricators have been seeking are greater design efficiency, better welding characteristics, good forming properties, excellent resistance to corrosion and the same economy as in other non heat-treatable alloys. Metallurgical research has developed 5083 and 5086 as superior weldable alloys which fill these needs. Both alloys have virtually the same characteristics with 5083 having slightly higher mechanical properties due to the increased manganese content over 5086. Applications: unfired pressure vessels, missile containers, heavy-duty truck and trailer assemblies, boat hulls and superstructures.

6061
This is the least expensive and most versatile of the heat-treatable aluminum alloys. It has most of the good qualities of aluminum. It offers a range of good mechanical properties and good corrosion resistance. It can be fabricated by most of the commonly used techniques. In the annealed condition it has good workability. In the T4 condition fairly severe forming operations may be accomplished. The full T6 properties may be obtained by artificial aging. It is welded by all methods and can be furnace brazed. It is available in the clad form ("Alclad") with a thin surface layer of high purity aluminum to improve both appearance and corrosion resistance. Applications: This grade is used for a wide variety of products and applications from truck bodies and frames to screw machine parts and structural components. 6061 is used where appearance and better corrosion resistance with good strength are required.

6063
This grade is commonly referred to as the architectural alloy. It was developed as an extrusion alloy with relatively high tensile properties, excellent finishing characteristics and a high degree of resistance to corrosion. This alloy is most often found in various interior and exterior architectural applications, such as windows, doors, store fronts and assorted trim items. It is the alloy best suited for anodizing applications - either plain or in a variety of colors.

7075
This is one of the highest strength aluminum alloys available. Its strength-to weight ratio is excellent and it is ideally used for highly stressed parts. It may be formed in the annealed condition and subsequently heat treated. Spot or flash welding can be used, although arc and gas welding are not recommended. It is available in the clad ("Alclad") form to improve the corrosion resistance with the over-all high strength being only moderately affected. Applications: Used where highest strength is needed.

ALUMINUM ALLOY DESIGNATIONS
The aluminum industry uses a four-digit index system for the designation of its wrought aluminum alloys.

As outlined below, the first digit indicates the alloy group according to the major alloying elements.

1xxx Series

In this group. minimum aluminum content is 99%. and there is no major alloying element.

The second digit indicates modifications in impurity limits. If the second digit is zero, there is no special control on individual impurities. Digits 1 through 9, which are assigned consecutively as needed, indicate special control of one or more individual impurities.

The last two digits indicate specific minimum aluminum content. Although the absolute minimum aluminum content in this group is 99% the minimum for certain grades is higher than 99%, and the last two digits represent the hundredths of a per cent over 99.

Thus, 1030 would indicate 99.30% minimum aluminum. without special control on individual impurities. The designations 1130, 1230, 1330, etc.. indicate the same purity with special control on one or more impurities. Likewise. 1100 indicates minimum aluminum content of 99.00% with individual impurity control.

2xxx through 9xxx Series

The major alloying elements are indicated by the first digit, as follows:

2xxx Copper

3xxx Manganese

4xxx Silicon

5xxx Magnesium

6xxx Magnesium and silicon

7xxx Zinc

8xxx Other element

9xxx Unused series


The second digit indicates alloy modification. If the second digit is zero. it indicates the original alloy: digits 1 through 9, which are assigned consecutively, indicate alloy modifications. The last two digits have no special significance, serving only to identify the different alloys in the group.

Experimental Alloys
Experimental alloys are designated according to the four digit system, but they are prefixed by the letter X. The prefix is dropped when the alloy becomes standard. During development, and before they are designated as experimental, new alloys are identified by serial numbers assigned by their originators. Use of the serial number is discontinued when the X number is assigned.

ALUMINUM TEMPER DESIGNATIONS
Temper designations of wrought aluminum alloys consist of suffixes to the numeric alloy designations. For example, in 3003-H14, 3003 denotes the alloy and "H14" denotes the temper, or degree of hardness. The temper designation also reveals the method by which the hardness was obtained. Temper designations differ between non heat-treatable alloys and heat-treatable alloys. and their meanings are given below:

Non Heat-Treatable Alloys

The letter "H" is always followed by 2 or 3 digits. The first digit indicates the particular method used to obtain the temper. as follows:

— Hl means strain hardened only.

— H2 means strain hardened, then partially annealed.

— H3 means strain hardened, then stabilized.

The temper is indicated by the second digit as follows:

2 1/4 hard

4 I/2 hard

6 3/4 hard

8 full hard

9 extra hard

Added digits indicate modification of standard practice.

Heat-Treatable Alloys

-F As fabricated

-O Annealed

-T Heat treated

The letter "T" is always followed by one or more digits. These digits indicate the method used to produce the stable tempers, as follows:

-T3 Solution heat treated, then cold worked.

-T351 Solution heat treated, stress-relieved stretched, then cold worked.

-T36 Solution heat treated, then cold worked (controlled).

-T4 Solution heat treated, then naturally aged.

-T451 Solution heat treated, then stress relieved stretched.

-T5 Artificially aged only.

-T6 Solution heat treated, then artificially aged.

-T61 Solution heat treated (boiling water quench), then artificially aged.

-T651 Solution heat treated, stress-relieved stretched, then artificially aged (precipitation heat treatment).

-T652 Solution heat treated, stress relieved by compression. then artificially aged.

-T7 Solution heat treated, then stabilized.

-T8 Solution heat treated, cold worked, then artificially aged.


-T81 Solution heat treated, cold worked (controlled), then artificially aged.

-T851 Solution heat treated, cold worked, stress-relieved stretched, then artificially aged.

-T9 Solution heat treated, artificially aged, then cold worked.

-T10 Artificially aged, then cold worked.

Added digits indicate modification of standard practice.


COMPARISON OF MODERN &
OLD SYSTEMS OF ALUMINUM ALLOY DESIGNATION
Although the old system of aluminum identification has been obsolete for many years, stock with the old markings is still occasionally found. The following comparison is presented as an aid in identifying such materials in terms of the modern system.

In the old system, alloy composition was indicated by a one- or two-digit number followed by the letter "S" to indicate that it was a wrought alloy, i.e., an alloy that could be shaped by rolling, drawing or forging. Any variation in the basic composition was indicated by a letter preceding the numerical alloy designation. For example, A17S was a modification of the basic alloy 17S. In modern terminology these two alloys are designated 2117S and 2017S, respectively. Temper was designated by a second letter: "O" for soft (annealed), "H"for strain hardness of non heat-treatable alloys, and "T"for hardness of heat-treatable alloys. Degree of hardness of non heat-treatable alloys was indicated by a fraction preceding the letter "H". For example, 3S1/4H would be quarter-hard 3S alloy.

The following Table gives examples of the old and modern designations of some common aluminum alloys.


Modern System

1100

3003

3003-0

2014

2017

2117

2018

2218

2024T

5052

7075T6
  Old System

2S

3S

3SO

14S

17S

A17S

18S

B18S

24ST

52S

75ST6


ALUMINUM INFORMATION
To view the files below you'll need the Adobe Acrobat reader. If you don't have the Adobe reader, you can download it ahead of time from the Adobe Web site.
   
Click here to download the
Aluminum Alloy Characteristics &
Approximate Minumum RADII for 90 Degrees Cold Bend.
 
   
Click here to download the Aluminum Sheet

http://www.aircraftspruce.com/catalog/mepages/aluminfo.php

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[magpwr]

Hi Grumage,

Here is the 5min long video base on my Avramenko plug ver 2.0 experiment charging flash capacitor using 1 wire only.

Finding from experiment using low power HV-
Battery to Mini HV generator no load condition current consumption:89mA
Current consumption while charging flash cap from below 1volt:96mA
The load on battery is only 96mA-89mA=7mA   (To charge flash cap)

This is the longest boring video i have created to date running time 6min.It was challenging.
https://www.youtube.com/watch?v=Tg9kuSdEaAE