# Andrei_62

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1. ## magnetic Self-propulsion

That's right, it will move.
2. ## magnetic Self-propulsion

Directional movement. The property of the magnetic field of the permanent magnet the neutral zone is the presence of force directed motion (self-motion magnetic) with a strong attraction towards any main pole of the other magnet (magnetized ferromagnetic primary pole permanent magnet). When connecting opposite poles get motion the chain in two directions (Figure 1), The series connection in the circuit connection has limited the length corresponding to the mechanism of the magnetic self-propulsion. The chain length distributes without limitation magnetic properties as follows: at the beginning and at the end of the magnetic circuit self-movement mechanism, the center of the chain - attraction. Magnetic self-movement interacts well with the effect (dipole) repulsion (get directions repulsion effect) (Figure 2). Interaction with magnetized iron. By setting the magnetic washer with axial magnetization is free to rotate on a circular convex platform, at the edge of the main pole magnetic disk at a minimum distance from each other semicircle magnetize the iron rods. Acting on the half-ring chain with a magnetic self-movement - get directed motion (rotation) from the beginning to the end of the half-ring. The appearance of an electric current. Exposure to the magnetic field of the neutral zone of a permanent magnet - The occurrence of an electric current in a conducting circuit moving in a magnetic field of the neutral zone. Insert a sharp iron core into the center of the copper coil. Perpendicular to the iron core, touch the center of the plane with the neutral zone (hereinafter referred to as magnetic self-movement) of the magnetic cube with axial magnetization and perform reciprocating motion without air gap, parallel to the axis of magnetization of the permanent magnet, approximately 1/10 part along the plane with magnetic self-movement - an electric current. We will insert an iron core in the center of the copper coil and with a plane with a neutral zone of a magnetic cube with axial magnetization perpendicular to the iron core of the copper coil with a fixed air gap, make a linear movement parallel to the axis of magnetization of the magnetic cube, with the approach and removal of the magnetic cube with respect to the iron core of the copper coil . Consider the picture of the occurrence of current, with permeability of iron: We get the end approximation and removal of the main opposite poles (arriving and decreasing magnetic field) - currents of the same direction, approximately 30% for electromagnetic induction, with a cos angle of 10-45 degrees. When moving in the field of magnetic self-propulsion - 100% current in the opposite direction. The same actions without an iron core - the picture of the physical properties of the magnetic field is the same. (fig. 3). Interaction with alternating current. At the center of the copper coil we insert an iron core, we pass through the coil an alternating electric current, we act on the core of the center of the chain with magnetic self-motion - there is no directional motion (the electromagnetic field does not interact with the magnetic self-motion). To obtain the effect of directional motion, the iron core is magnetized by the main pole of the permanent magnet, we act on the core by a chain with a magnetic self-motion-a directional motion has arisen. Let's increase the air gap between the chain with the magnetic self-motion and the magnetized magnetic field of the iron core of the copper coil - until the interaction of the directed motion ceases. Let's pass through the coil an alternating electric current - a directional motion appeared between the magnetic self-motion, the iron core, the magnetized magnetic field of the permanent magnet, and the electromagnetic field of the current coil. (When the iron core is magnetized by a magnetic field, the electromagnetic field of the coil with current increases the interaction of the magnetic field with the magnetic self-propulsion, the increased traction force of the directed motion, while the direction of the current in the coil does not play an important role). Interaction with direct current At the center of the copper coil we insert the iron core, let us pass through the coil a constant electric current, we act on the core of the center of the chain with magnetic self-motion - there is a directional movement. Connect the voltmeter to the copper coil and the magnetic circuit, we repeat the direction of motion that occurred when the electric current passes through the coil - a current of the same direction appears in the coil. Based on the interaction of magnetic self-current with a constant electric current, the simplest electromagnetic motor was created (with electricity consumption); and the simplest electromagnetic generator (with the consumption of mechanical energy) (fig.4). fig.4 Released into the public domain world 03.05.2001.
3. ## Calculation of the pyramid (Sequence of numerical progressions).

Front side: Progress Sums:-1,-2,-3,-4,-5... 1,2,3,4,5... We express the formulas:Sn= (a₁n2+n)/2, ; Sn-1=(a₁n2-n)/2,. (n - Number of summing members, a₁ - first member of the progression. With a negative or positive value n. Expressions Sn-1, Sn-2 should be understood: subtraction from the number of the member taken). First option: Example: Sn= (a₁n2+n)/2. For n = -5 we have: (-1*(-5)2+(-5))/2=-15; For n = 5 we have: (1*(5)2+5)/2=15. Example: Sn-1=(a₁n2-n)/2 For n = -5 we have: (-1*(-5)2-(-5))/2=-10 For n = 5 we have: (1*(5)2-5)/2=10. Triangular: Progress Sums:-1,-3,-6,-10,-15....1,3,6,10,15.... We express the formulas:Sn= ((n+a₁)3-(n+a₁))/6, Sn= (n3-n)/6+(a₁n2+n)/2; Sn-1=(n3-n)/6; Sn-2=((n-a₁)3-(n-a₁))/6, Sn-2=(n3-n)/6-(a₁n2-n)/2. First option: Example: Sn= ((n+a₁)3-(n+a₁))/6. For n = -5 we have: ((-5+(-1))3-(-5+(-1)))/6=-35; For n = 5 we have: ((5+1)3-(5+1))/6=35. Example: Sn-2=((n-a₁)3-(n-a₁))/6. For n = -5 we have:((-5-(-1))3-(-5-(-1)))/6=-10; For n = 5 we have: ((5-1)3-(5-1))/6=10. Second option: Example: Sn= (n3-n)/6+(a₁n2+n)/2. For n = -5 we have: ((-5)3-(-5))/6+(-1*(-5)2+(-5))/2= -35; For n = 5 we have: (( 5)3-5)/6+(1*(5)2+5)/2= 35. Example: Sn-1=(n3-n)/6. For n = -5 we have: ((-5)3-(-5))/6= -20; For n = 5 we have: (( 5)3-5)/6=20. Example: Sn-2=(n3-n)/6-(a₁n2-n)/2. For n = -5 we have:((-5)3-(-5))/6 -(-1*(-5)2-(-5))/2= -10; For n = 5 we have: (( 5)3-5)/6-(1*(5)2-5)/2= 10. Quadrilateral: Progress Sums: -1,-4,-9,-16,-25....1,4,9,16,25.... We express the formulas:Sn= a₁(n+a₁)(a₁n2+0,5n)/3, Sn= (n3-n)/3 + (a₁n2+n)/2; Sn-1= a₁(n-a₁)(a₁n2-0,5n)/3, Sn-1=(n3-n)/3 - (a₁n2-n)/2. First option: Example: Sn=a₁(n+a₁)(a₁n2+0,5n)/3. For n = -5 we have: -1(-5+(-1))*(-1*(-5)2+(-2,5))/3=-55; For n = 5 we have: 1(5+1)(1*(5)2+2,5)/3=55. Example: Sn-1= a₁(n-a₁)(a₁n2-0,5n)/3. For n = -5 we have: -1(-5-(-1))*(-1*(-5)2-(-2,5))/3=-30; For n = 5 we have:1(5-1)(1*(5)2-2,5)/3=30. Second option: Example: Sn= (n3-n)/3 + (a₁n2+n)/2. For n = -5 we have: ((-5)3-(-5))/3 + (-1*(-5)2+(-5))/2= -55; For n = 5 we have:((5)3-5)/3 + (1*(5)2+5)/2= 55. Example: Sn-1= (n3-n)/3 -(a₁n2-n)/2. For n = -5 we have: ((-5)3-(-5))/3 -(-1*(-5)2-(-5))/2= -30; For n = 5 we have: ((5)3-5)/3 -(1*(5)2-5)/2= 30.
4. ## Source of energy

Putting a simple electrochemical cell, except for the introduction of the depolarizer. The NaCl solution is placed two electrode potential difference. For a fixed load of the external circuit of the discharge element approximately 10-15%. After discharge element, without opening an external circuit element will cover a glass bulb and increase the percentage of carbon dioxide up to 3% in the composition of air under the bulb - we can fix the charge element Keeping a stable amount of carbon dioxide under the bulb - can maintain the health of the element.
5. ## The magnetic field of the neutral zone

The magnetic field of the neutral zone - The emergence of electric current in the conducting loop, moving in a magnetic field of the neutral zone. In the center of the copper coil inserting a sharp iron core. Touching the tip of the core center of the neutral zone of the magnetic cubes bipolar magnet with axial magnetization and reciprocating motion without air gap parallel to the internal lines of force of the magnet, about 1/10 of the area of ​​the neutral zone - an electric current. (The physical picture of the current occurrence is not defined). When you zoom in and out of the neutral zone of the permanent magnet to the iron core copper coil - current appears negligible. In the center of the copper coil insert an iron core and a neutral zone cube perpendicular to the magnetic iron core with a fixed air gap commit linear motion to zoom in and out of the magnetic cubes. (Consider the picture of the appearance of the current at constant iron). Obtain a mechanical approach and removal of the main opposite poles - one current direction in the plane of the neutral zone - current in the opposite direction that occurs relatively evenly over the entire length of the neutral zone parallel to the internal lines of force of the magnet. The same actions without the iron core - a picture of the physical properties of the magnet is the same. (Figure 3). Getting an electric current. For comparison of electrical current to the copper coil with an iron core will establish a rotating circular platform with electric drive, and alternately compare the impact of the main pole and the neutral zone, setting the magnetic cube on a platform with a fixed air gap between the magnet and the iron core copper coil. In the neutral zone is slightly higher voltage slightly lower current.
6. ## magnetic Self-propulsion

Magnetic Self-Motion The main property of a permanent magnet is the presence of directed force with the effect of attracting objects that are situated perpendicular to the main poles in relationship to any main pole of other magnet Directional movement. The main property of the neutral zone is the presence of a permanent magnet force directed movement with a strong attraction towards any main pole of the other magnet (main pole of the permanent magnet magnetized iron main pole of the permanent magnet.) In series of opposite poles get chain movement in two directions having a limited length corresponding to the mechanism of the magnetic self-motion. The chain length distributes without limitation magnetic properties as follows: at the beginning and end of the chain mechanism of the magnetic self-movement, the center of a chain - attraction. The magnetic self-motion interacts well with the effect (dipole) repulsion (get directions repulsion effect) Multi-level sequential circuits with magnetic self-movement and the main pole of the permanent magnet can perform actions ( directional movement ) overcomes resistance effect of repulsion and attraction of the main poles. If further isolation of the main poles apply a magnetic circuit and isolation of multilevel sequences magnetic circuits , where each magnetic circuit and the main pole permanent magnets can perform the work in its isolated level - it is possible to assume the possibility of creating a circular rotation technology based on magnetic self-motion. Translated into public dostoyanie.03.05.2001.Bishkek . Interaction with a magnetized iron. If you install a magnetic puck on a round convex freely rotating the platform and the edge of the main pole magnetic disk at a minimum distance from each other semicircle sterzhni.To magnetize the iron when exposed to semi-ring chain with a magnetic self-movement - get driving directions ( vrashenie ) from start to finish half rings. Interaction with electric . In the center of a copper coil insert the iron core coil is connected to a power source, working on the core center of the chain with the magnetic self-movement - no directional movement . To obtain the effect of the magnetic self-movement opposite to the magnetic circuit for the iron core , attach the main pole permanent magnet. The coil is connected to a power source, working on the core center of the chain with the magnetic self-movement - appeared aimed interaction between the iron core magnetized main pole permanent magnet and a magnetic circuit with self-movement ( the magnetization of the iron core of the main pole of the permanent magnet current in the coil of the electromagnet increases the pulling power of the magnetic self-motion , The direction of the coil current is not important .) The magnetic self-motion is capable of producing work aimed traction movement , interacting with the iron core of an electromagnet , the main pole magnetized permanent magnet , and the current in the coil of the electromagnet increases the pulling power of the magnetic self-motion. The origin and receiving electrical current. In the center of a copper coil insert sharp iron core . Touching the tip of the core center of the neutral zone (the magnetic self-motion ) of the magnetic -pole magnet cube and a reciprocating motion without an air gap of approximately 1 /10 of the area of ??the magnetic self-motion - an electric current . The same actions committed with the main pole of the permanent magnet - there is a current is negligible. When approaching and removing the main pole of the permanent magnet to the iron core copper coil - an electric current . The same actions committed with the magnetic self-movement - there is negligible current . In the center of a copper coil insert the iron core and magnetic cube making linear motion to zoom in and out , for comparison ( of a constant current at a fixed iron air gap ) in turn are working the main pole of the permanent magnet and the magnetic self-movement - we get almost the same voltage , although there is little current higher in the magnetic self-motion , and the approximation and removal of the main currents of opposite poles of one direction of the magnetic self-motion in the opposite direction of the current , and markedly reduced the attraction between the magnet and iron self-movement . For comparison of electric current to the copper coil with an iron core install a rotating circular platform with electric drive, and in turn compare the impact of the main pole and the magnetic self-motion , setting the magnetic cube on a platform with a fixed air gap between the magnet and the iron core copper coil . In the magnetic self-motion slightly higher voltage , a little below the current. These properties indicate the possibility of the effect of creating an engine - generator , where the resulting current consumption will increase traction effect of the magnetic self-motion. For example: Magnetize the iron cores of the electromagnets main pole permanent magnet installed around the circumference of a semicircle ( unfinished circle) and in different levels to complete the circle , where each half ring in sequence will interact with the magnetic circuit of self-motion , for circular rotation , the rotation of the electric current , reinforcing the pulling force directed dvizheniya.Pri removal of the magnetic circuit of the half-ring creates the effect of gravity. To eliminate the effect of anti- gravity appropriate use of the reservoir. Russia . Stary Oskol. A.Verner . E.Verner .
7. ## magnetic Self-propulsion

Directional movement. The main property is the presence of a permanent magnet force direction of movement with a strong attraction towards any main pole of the other magnet (main poles of a permanent magnet magnetized iron main pole of a permanent magnet). In series unlike poles obtain a chain of movement in two directions (Fig. 1), which has a limited length, corresponding mechanisms of magnetic self-motion. Without limiting the length of the chain distributes forces as follows: beginning of a chain - the mechanism of the magnetic self-motion, the center of the chain - any of the major draws of the poles, the end of the chain - the continuation of the magnetic self-motion. Magnetic self-motion interacts well with the effect (dipole) repulsion (get directions repulsion effect) (Fig. 2) Sequential circuits with magnetic self-movement and the main pole of the permanent magnet can take action (direction) overcoming opposition main poles (the effect of repulsion or attraction). If additional insulation to apply the main poles of the magnetic circuit and the insulation in a tiered sequence of magnetic circuits, where each magnetic circuit and the main pole of the magnet postayanno can do the work of an isolated in its own level - suggests the possibility of a circular rotation technology, based on self-propulsion or directional magnetic repulsion effect. Other variants of: Magnetize the iron cores of the electromagnets main pole of the permanent magnet set in a circle semicircle (not a complete circle) and at different levels to complete the circle. Where each half ring in sequence will interact with the chain of magnetic self-motion, for circular rotation. Interaction with electrocution. In the center of the copper coil insert the iron core, the coil connected to the power supply - are working on the core center of the chain with the magnetic self-movement - no interaction (at AC vibration occurs). To obtain the effect of the magnetic self-motion, on the opposite side of the magnetic circuit, the iron core, attach the main pole of the permanent magnet. Coil connected to the power supply, are working on the core center of the chain with the magnetic self-movement - there was interaction between the iron core, the magnetization of the main poles of a permanent magnet and a magnetic circuit with self-movement (in the magnetization of the iron core of the main poles of a permanent magnet in a coil currents strengthen all magnetic effects, with direction of the current in the coil is not important.) Magnetic self-motion can produce work movement in two directions, interacting with the iron core of an electromagnet, the main pole magnetized permanent magnet, and the current in the coil of the electromagnet increases the effect of the magnetic self-motion. The origin and receiving electric current. In the center of the copper coil insert sharp iron core. Touching the tip of the core center of the neutral zone (the magnetic self-motion) bipolar magnetic cube magnet and committing reciprocating motion without an air gap of approximately 1/10 of the area of ​​the magnetic self-motion - an electric current. The same act committed with the main pole - current appears negligible. When approaching and removing main poles of a permanent magnet to the iron core copper coil - an electric current. The same actions committed by a magnetic self-movement - there is negligible current. In the center of the copper coil insert the iron core. And the magnetic cube, for comparison (of the current at constant iron fixed air gap) in turn are working main pole of the permanent magnet and the magnetic self-motion. We get almost the same voltage, but current appears slightly higher and flatter in the magnetic self-motion, with significantly reduced magnetic attraction between self-movement and iron. To compare the electrical current to the copper coil with an iron core the rotating circular platform with electric drive, and in turn compare the effects of major magnetic pole and self-motion, setting the magnetic cube on the platform with a fixed air gap between the magnet and the iron core copper katushki.U magnetic self-motion-bit higher the voltage, a little below the current. Theoretically: These properties indicate the possibility of the effect of a motor-generator, where it has received current enhance the effect of the magnetic self-motion. Translated into the public domain. 03/05/2001.
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