RU2022115363A - A highly efficient method for generating electromagnetic unipolar linear motion - Google Patents

Claims (5)

1. A highly efficient method of creating electromagnetic unipolar linear motion, which uses electrically conductive rails (1), permanent magnets (2), magnetic cores (3), electrically conductive jumpers (4), control circuit (5), power supply (6), rolling/ sliding contacts (7), a linear rotor (8) (movement body) and electrically conductive current leads (9), and characterized in that the movement of the magnetic poles of the stator (current circuits) is synchronous with the movement of the magnetic poles of the rotor (8) (permanent magnets (2) ) is provided by the system of movement of the stator magnetic poles, while the area of the stator magnetic poles (current circuits) and the average values of the distribution of magnetic fields in them are unchanged (S=const, B=const) when the rotor moves (8), in addition, when the rotor moves (8 ) the magnetic poles of the rotor (8) (permanent magnets (2)) are always at a constant distance from the magnetic poles of the stator (current circuits), while along the length of the rotor (8) there is an alternation of the polarity of at least one pair of opposite magnetic poles of the rotor ( 8) (permanent magnets (2) of polarity S/N and N/S), and between them there is an alternation of the polarity of opposite magnetic poles of the stator (current circuits). 2. A highly efficient method of creating electromagnetic unipolar linear motion according to claim 1, in which two electrically conductive rails (1) electrically isolated from each other are located in the same plane and with the same distance between them along their entire length, between them there is at least one pair of permanent magnets (2), the main vector of magnetic induction ↑B _{the magnet} of which is directed inside them perpendicular to the plane of the electrically conductive rails (1), while the permanent magnets (2) are opposite (N/S and S/N) magnetic poles of the rotor (8 ), to which they are rigidly connected and can move freely between electrically conductive rails (1). 3. A highly efficient method of creating electromagnetic unipolar linear motion according to claim 1, in which the system of movement of the magnetic poles of the stator consists of at least two electrically conductive jumpers (4) moving together with the rotor (8) and at least one pair of current leads (9 ), while electrically conductive jumpers (4) with rolling contacts (7) provide electrical contact between electrically conductive rails (1) and are located in the dimensions of the magnetic poles of the rotor (8) (permanent magnets (2)) of the same polarity, and located in the dimensions of the magnetic pole rotor (8) (permanent magnet (2)) of a different polarity, current leads (9) with rolling contacts (7) are connected to the control circuit (5) and power source (6) and provide electrical contact with electrically conductive rails (1); in this case, electrically conductive rails (1), electrically conductive jumpers (4) with rolling contacts (7) and current leads (9) with rolling contacts (7) with current in them form opposite magnetic poles of the stator (current circuits). 4. A highly efficient method of creating electromagnetic unipolar linear motion according to claim 1, in which the system of movement of the magnetic poles of the stator consists of electrically conductive jumpers (4) moving together with the rotor (8) with rolling contacts (7), which provide electrical contact between electrically conductive rails ( 1) in the dimensions of the opposite magnetic poles of the rotor (8) (permanent magnets (2)); in this case, electrically conductive rails (1) and electrically conductive jumpers (4) with rolling contacts (7) with current in them form opposite magnetic poles of the stator (current circuits). 5. A highly efficient method of creating electromagnetic unipolar linear motion according to claims. 1-4, in which the magnetic cores (3) surround the electrically conductive stator rails (1) on the outer sides.