MD650Z - Electrostatic engine - Google Patents

Abstract

The invention relates to electrical engineering, in particular to small-sized electric motors and can be used in automation and instrument engineering.The electrostatic engine includes a dielectric housing (5), inside which are located coaxially with clearance (3) a stator (1) and a rotor (2). The rotor (2) is made of dielectric material, on which are mounted electrodes (4) in the form of metal plates, longitudinal to it, with the same pitch, and on the inner perimeter of the stator (1) are mounted electrodes (6) with a number twice greater than the electrodes (4) of the rotor (2), longitudinal to the stator (1), with the same pitch, which are connected over one to the like poles of the high voltage source (7). At the same time, the electrodes (6) of the stator (1) are made with an undercutting and are equipped with pointed projections (9). The ratio between the transverse size of the electrodes (6) of the stator (1) and the transverse size of the electrodes (4) of the rotor (2) S2/S1 is in the range 1.1…1.8. The pointed projections (9) are made in the form of needles or blades.

Description

The invention relates to electrical engineering, in particular to small electric motors and can be used in automation and apparatus construction.

The electrostatic motor with a movable hollow rotor is known, which includes conductive and non-conductive coatings [1].

The disadvantage of this engine is that the main effect in such an engine occurs only as a result of the formation of the "electric wind" in it.

The electrostatic motor is known, which includes a stator, inside which a rotor is placed, made of dielectric material and electrodes, while the stator is connected to the electrodes.

The disadvantage of this motor is that it operates only from complicated high-voltage sources, which create a rotating electric field [2].

The closest solution is the electrostatic motor, which includes a dielectric body, inside which a stator and a rotor are placed coaxially with clearance, while the rotor is made of dielectric material, on which electrodes in the form of metal plates are installed [3].

The disadvantage of this motor is that it belongs to the class of motors that operate from three-phase voltage sources, which create a rotating electric field. Such a motor from a simple high-voltage source will not work.

The problem solved by the present invention consists in improving the construction of the electrostatic motor, which will allow operation from a simple high voltage source.

The motor, according to the invention, eliminates the above-mentioned disadvantages by including a dielectric body, inside which a stator and a rotor are placed coaxially with a clearance, the rotor is made of dielectric material, on which electrodes in the form of metal plates are installed, longitudinally, with equal pitch, and on the inner perimeter of the stator are installed electrodes with a number twice greater than the rotor electrodes, longitudinally of the stator, with equal pitch, which are connected one above the other to the same pole of the high voltage source. At the same time, the stator electrodes are made with recesses and equipped with sharp protrusions. The ratio between the transverse dimension of the stator electrodes and the transverse dimension of the rotor electrodes S2/S1 is in the range 1.1…1.8. The sharp protrusions are made in the form of needles or blades.

The invention is explained by the drawings in Fig. 1-3, which represent:

- Fig. 1, diagram of the electrostatic motor;

- Fig. 2, diagram of the electrostatic motor with the ratio between the transverse dimension of the stator electrodes and the transverse dimension of the rotor electrodes S2/S1;

- Fig. 3, diagram of the electrostatic motor with the rotor electrodes displaced to a threshold equal to half of their transverse dimension.

The electrostatic motor includes a dielectric body 5, inside which are placed coaxially with a clearance of 3 a stator 1 and a rotor 2, installed in the bearing 8. The rotor 2 is made of dielectric material, on which electrodes 4 in the form of metal plates are installed, longitudinally thereof, with equal pitch, and on the inner perimeter of the stator 1 electrodes 6 are installed with a number twice greater than the electrodes 4 of the rotor 2, longitudinally of the stator 1, with equal pitch, which are connected one above the other to the same pole of the high voltage source 7. At the same time, the electrodes 6 of the stator 1 are made with recesses and equipped with sharp protrusions 9. The ratio between the transverse dimension of the electrodes 6 of the stator 1 and the transverse dimension of the electrodes 4 of the rotor 2 S2/S1 is in the range 1.1…1.8. The sharp protrusions 9 are made in the form of needles or blades.

The electrostatic motor works as follows.

When voltage is applied to the electrodes 6, connected across each other to the same pole of the high-voltage source 7, the electrodes 4, due to the corona discharge from the sharp protrusions 9 of the electrodes 6, are charged with the same potential as the electrodes 6. The electrodes 4 and 6 having the same polarity begin to repel each other, which leads to their movement to the left and right. The diagram, according to Fig. 1, represents the electrostatic motor at the moment when it is not possible to determine the direction of rotation. Everything depends on a non-observance of symmetry in the placement of the electrodes 4 and 6. Obviously, all the electrodes 4 simultaneously have a tendency to approach the next electrode 6 with the opposite potential. As they move towards it, all electrodes 4, due to the corona discharge from the sharp protrusions 9 of the next electrode 6, connected to another pole of the voltage source, lose their previous charge and obtain the charge of that electrode towards which they move. Only at a calculated ratio of the number of electrodes of the stator 1 and the rotor 2, when the number of electrodes 6 of the stator 1 is twice as large as that of the electrodes 4 of the rotor 2 and they are placed with equal pitch longitudinally of the stator 1, is a concordance of the actions of the electrodes observed, which generates a maximum permissible rotation speed. At a random ratio of the number of electrodes on the stator 1 and rotor 2, some of the electrodes 4 and 6 operate inconsistently, which leads to a decrease in the rotational moment of the rotor 2.

Due to the corona discharge from the sharp protrusions 9 of the electrodes 6, a rapid recharge of the electrodes 4 on the rotor 2 is obtained and, therefore, this influences the rotation speed of the rotor 2. The sharp protrusions 9 are located in the recesses of the electrodes 6. At the same time, the electrodes 6 also perform the function of a diaphragm or an electrostatic focusing lens, which also contributes to the rapid recharge of the electrodes 4.

At the same time, a certain technical contradiction appears. According to the theory of electrostatic induction, the clearance 3 between the stator 1 and the rotor 2 must be minimal, but the sharp protrusions 9 located on the electrodes of the stator 1 can prevent this. For these reasons, the sharp protrusions 9 are located in the recesses of the electrodes 6 and there are no more restrictions on the clearance 3 between the stator 1 and the rotor 2 and the possibility of rapid recharging of the electrodes 4 is maintained.

In the case when all the electrodes 4 of the rotor 2 are moved to a threshold equal to half of their transverse dimension, there is no indeterminacy in choosing the direction of rotation of the rotor 2. When the electrodes are moved, according to Fig. 3, the permanent rotor will rotate clockwise, and when the electrodes are moved in the opposite direction, the direction of rotation of the rotor will be counterclockwise.

It is worth noting that all the listed variants are characteristic only for motors powered by high-voltage transformers. For motors powered by a source that creates a rotating electric field, these indices are unimportant. The direction of rotation of these motors depends on the direction of rotation of the electric field.

If the ratio between the transverse dimension of the electrodes 6 of the stator 1 and the transverse dimension of the electrodes 4 of the rotor 2 S2/S1 is in a range smaller than 1.1, then the motor rotation moment decreases, and if this ratio is in a range larger than 1.8, then the electrodes 4 of the rotor 2 are simultaneously acted upon by the positively and negatively charged electrodes 6 of the stator 1, which also acts on the motor rotation moment. The sharp protrusions 9 are made in the form of needles and blades.

Thus, an electrostatic motor, powered by a cheap voltage source, was proposed, which can be used in automation and apparatus construction as an actuator, in cooling systems for high-voltage power equipment, especially in cooling systems for X-ray emitters.

1. Dyadyukin D.A. Electrodynamics. Opening of a new physical effect: "The phenomenon of rotation of wires in the electric field of moving charges". Physics of consciousness and life, cosmology and astrophysics. No. 1, 2007, c. 52-59

2. SU 594568 A1 1978.02.25

3. SU 1452427 A1 1994.12.30

Claims (3)

1. Electrostatic motor, which includes a dielectric body (5), inside which a stator (1) and a rotor (2) are placed coaxially with a clearance (3); the rotor (2) is made of dielectric material, on which electrodes (4) in the form of metal plates are installed, longitudinally thereof, with equal pitch, and on the inner perimeter of the stator (1) are installed electrodes (6) with a number twice greater than the electrodes (4) of the rotor (2), longitudinally of the stator (1), with equal pitch, which are connected one above the other to the same pole of the high voltage source (7), at the same time the electrodes (6) of the stator (1) are made with recesses and equipped with sharp protrusions (9). 2. Motor according to claim 1, wherein the ratio between the transverse dimension of the electrodes (6) of the stator and the transverse dimension of the electrodes (4) of the rotor (2) S2/S1 is in the range 1.1…1.8. 3. Motor according to claim 1, wherein the sharp protrusions (9) are made in the form of needles or blades.