Аntigravity

antigravity    gravity    rotation   antigravitation     gravity energy

LABORATORY HONEST PHYSICS 

 On exposure to temperatures of rotation and difference in gravitational systems.

Antigravity.

The article describes the results of experiments on the effects of gravity on the body system: the rotation and the difference in their  temperatures. To investigate the cause — effect relationship in a gravitational system. The notion antigravity

Novosibirsk 2017.

 

Everyone knows that the force of gravity depends on the mass of bodies and the distance between them. We will try to find out what else can affect the gravity system. And this will help us «Raznoplechie torsion balance» those whom Doctor of Physical and Mathematical Sciences Nikolay Aleksandrovich Kozyrev studied time. We simply study the gravitational influence of the various bodies, energy and light conditions on a non-magnetic arrow of the instrument.

Equipment .

To carry out experiments with the rotation, use desktop grinder with a non-magnetic flywheel — grinding wheel and raznoplechie torsion balance Kozyrev (device). The diameter of the transparent plastic body weights of 220 mm, height 95 mm. Top housing closed glass sufficiently solid cover to which is fastened arrow pointer (which may be a plastic or wooden weight less than 0.1g) suspended on a thin nylon threads 0.05mm thick. Counterweight arrows lead. The distance between the device and the flywheel machine about 30 mm. To check the reproducibility of the experiments, were used different devices. The machine 2 has a flywheel mounted on a single shaft located on both sides of the motor, located in the middle. flywheel diameter 150mm. Mass approximately kilogram. Its linear speed at the rated rotation is 158 km / h. To limit a third party to influence the course of experiments, the room lacked directed sunlight foreign electrical appliances are turned off. Flywheel machine rotates in the vertical plane. The direction of rotation is changed by turning the machine at 180 degrees relative to the instrument. The experiments were conducted in Novosibirsk from June to September 2017. Cock in the conventional position «0º» it was sent to the north (looking from south to north). Table grinding machine was located to the right of the conditional «0º» arrow device to 50º — 60º. For the experiments with high temperatures, used burning, candle wax. For the experiments at low temperatures, ice was used, with the temperature -17ºS. The protective shield is made of sheet metal, the thickness of 0,

Experiments with rotation

In the course of the experiment, it was observed the following. Being in close proximity to the instrument off and not spinning machine has no impact on the arrow of the device.

The rotation of the wheel in a clockwise  direction from the view of the instrument needle: Turn on the machine. There is an increase of the flywheel revolutions to 2800 rev / min. Observe as the rotating flywheel (cause) «pushes» arrow instrument (consequently) on the nominal position «0º» in the opposite direction from itself. Further surprisingly — when switching off the motor (2800 rev / min) and correspondingly reducing machine flywheel rotations, the needle moves rapidly to the flywheel and flywheel even substantially intersects the rotation axis, stopping at 30º to the left of that axis. Then, as the deceleration of rotation, at a speed of less than 1900 rev / min (linear velocity of 107 km / h), the needle again loses contact with the rotation and moves away from the flywheel in the opposite direction. When minimum speed is returned to the original position «0º»

Now we unfold the machine, and have been rotated counterclockwise relative to the instrument. Turning on the machine, the flywheel starts to rotate up to 2800 rev / min, and the needle is attracted to the flywheel. It continues to move almost to indicate the center of gravity of the flywheel, and stops in this area, when the nominal rotational speed of the machine. After switching off the motor, and the flywheel revolutions drop arrow vigorously turns away from the flywheel in the opposite direction. Further, while reducing the flywheel revolutions least 2580 rev / min (linear velocity of 146 km / h), the arrow is close to the flywheel. Upon reaching 1900 rev / min, until complete stop of rotation, the needle moves to the initial position «0º».

Further, the experiment was repeated with a light weight rotating disk 1d, diameter 27 mm, at 35,000 rev / min. (Linear velocity of 356 km / h.) The instrument pointer’s reaction was, but small, and hardly fixed.

The experiments with the screen. Low and high temperature

We repeated the experiment with a rotating flywheel. Only now the balance to set the flywheel shield made of iron. Turn motor clockwise view of the scale and seeing a jump attraction unit flywheel arrows to set the nominal speed. After earning the necessary momentum, there is a repulsive effect arrows flywheel device field. Turn off the motor. There is a strong, short-term jump in the direction of increasing the repulsion of the arrow on the field of the flywheel. As the number of revolutions of deceleration, on the contrary,  there is the effect of gravity, which is maintained until a complete stop of rotation.

Next, hold the experience with our device and fire a small wax candle. Immediately there is a strong gravitational interaction between the hand and a lit candle. Now repeat the experience, just close the unit from the flame of iron sheet. The result does not change. The arrow just enters the gravitational interaction with a burning candle.

Place the ice in a plastic bottle located next to the instrument. Immediately we observe intense needle deflection in the opposite direction from the container with ice. Arrow turned in the opposite direction to 180º.

Experience with massive steel weight

For this experiment we use a set of goods for barbells and dumbbells. Gaining loads of over 20 kg. Is 20 mm from the device. Arrow jerked to the appearance of goods, returned to its original position. No longer respond.

On the basis of these experiments, the following conclusions:

At fixed point and having the same body, the gravitational interaction is not detected.

There is gravity and antigravity. In this case, gravity pulls the body, anti-gravity on the contrary, pushes. Gravity and antigravity depend on the mass bodies system, rotational velocities of the bodies and its variations, as well as by the temperature difference between the bodies:

  1. Clockwise rotation.

Acceleration, constant rotation — weak antigravity

Slow rotation of 2800 r / min. up to 1900 rev / min. — gravity is significantly higher than on the force of gravity that occurs during acceleration and constant rotation.

Slow rotation of 1900 r / min. up to 1400 rev / min. — weak antigravity.

Less than 1400 revolutions / min. to stop — very weak antigravity.

2. Clockwise rotation with protective shield:

Set the rated speed, the rotation — antigravity.

Turn off the motor — a significant, short-term surge of anti-gravity.

Reducing the speed of rotation — gravity, saved to a full stop of the flywheel.

3. Counterclockwise rotation.

Acceleration, constant rotation — weak gravity.

Slowing rotation to from 2800 rev / min. up to 2580 rev / min. — anti-gravity is significantly higher than on the force of gravity that occurs during acceleration and constant rotation.

Slow rotation of 2580 r / min. up to 1900 rev / min. — gravity.

Less than 1,900 rev / min. to stop — gravity decreases in proportion to reduction in speed.

   Changing the direction of rotation or decrease the speed (deceleration) in each specific range of linear velocity, changes the gravitational effect on the opposite side of each of the next sinusoid range.

Logical impossibility of a force to rotate the flywheel change the instrument pointer location. But its rotation flywheel effect on the shooter. Thus, the rotation is the reason. Zoom in or out direction (as a body) follows under the influence of the flywheel.

The protective shield of the iron does not prevent the passage through it of gravity and anti-gravity fields do not significantly alter the results of experiments with the rotation, and does not change the results of experiments with an open fire. At the same time, it has been found that the fire matches, hot objects attract arrow device even more of a rotating flywheel. Chilled body, on the contrary, actively pushes away the arrow of the device by setting the location of the arrow on the 180º in the opposite side from you. As it becomes clear that the mass body itself does not have sufficient gravitational properties.

Conclusion.

We found that gravitational and anti gravitational interaction between the system bodies varies depending on the body weight, difference in their temperatures, time the direction of linear velocity and variation of this velocity Thus, it can be argued that the gravitational interaction is quite under control and management in addition to the law of gravity Gravity is necessary to study in the broader sense of the word, than the story of attracting their weight discs. And this, in turn, opens up vast scope for research and new discoveries.  Do not claim «impossible» to admit — is not known.

And yet, at the time of our experiments, we call gravitational repulsion  — antigravity. It’s easier to work with. Most people find it difficult to accept the possibility of antigravity. It’s time to get used to.

A.V.Matrakshin

To understand man we must explore all by yourself.

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Antigravity. Wikipedia.