DE3923120A1 - Magnetic drive force generating method - using endless band with spaced individual magnets of similar polarity passed through monopolar magnetic section - Google Patents

Abstract

The magnetic band (1) has a number of magnets (11) having the same polarity and size and spaced one after the other in a row. The spacing between the individual magnets (11) corresponds to half their length. The magnetic band (1) is displaced relative to a monopolar magnetic section (2), with the input end (21) of the latter having an opposing polarity to that of the leading pole of each individual magnet (11). The output end (22) of the magnetic section (2) has the opposite polarity to the trailing pole of each individual magnet (11). ADVANTAGE - Prevents roll movement.

Description

A magnetic force usually arises from Change in magnetic polarity, and the conventional one Method of generating a magnetic force is through a System realizable in the magnetic polarity is changeable.

The invention has for its object a method for Creating a magnetic force. This task is achieved in that a variety of Magnets of the same polarity and size in one Row spaced equidistant from each other, and wherein the row of magnets is in a monopolar magnetic  Section is used. Here, each magnet in the Magnet row both magnetic forces, d. H. Attraction and Absorb repulsive forces so that the row of magnets without Interrupt is moved forward while the row of magnets is moving located in the monopolar magnetic section.

Further details, features and advantages result from the following description of one in the drawing illustrated embodiment of a system for Implementation of the method according to the invention. It shows

Fig. 1 is a schematic representation of the operating principle of the magnetic force,

Fig. 1-A is a view of an N-polar magnetic portion,

Fig. 1-B is a representation of an S-polar magnetic portion,

Fig. 2 is a representation of the effect of the magnetic force according to the invention,

Fig. 2-A is an enlarged portion of Fig. 2, and

Fig. 3 is a spatial representation of an embodiment of the system for performing the method for generating a magnetic driving force.

Fig. 1-A shows an embodiment of an N-polar magnetic portion 2, wherein all of the magnets 41 in a non-polar cylindrical element 4 are wrapped. All N poles are directed outwards and all S poles are directed inwards, so that consequently the center of the element 4 becomes an N-polar magnetic section 2 . In contrast to this, the center of the cylindrical element 4 becomes an S-polar magnetic section 2 if - as shown in FIG. 1-B - all S-poles are directed outwards and the N-poles of all magnets 41 are directed inwards.

From Fig. 1 it can be seen that a plurality of mutually independent magnets 11 are arranged in a row to form a magnetic tape 1 . Each magnet 11 has the same polarity and the same magnetic force (ie the same size), with adjacent magnets 11 being spaced apart by half their length. The magnetic tape 1 is then inserted into a monopolar magnetic section 2 which has two ends, namely an inlet end 21 and an outlet end 22 . When the input end 21 is an N-pole and the output end 22 is an S-pole, the magnets 11 approaching the input end 21 can absorb the attractive force from the opposite polarity. The closer the magnets 11 come to the output end 22 in the N-polar magnetic section 22 , the stronger the attraction and repulsion forces absorbed by the magnets 11 . Then the situation necessarily arises that 11 A < 11 B < 11 C < 11 D < 11 E. However, since the magnets 11 A 'and 11 B' have left the N-polar magnetic section 2 , they absorb an attractive force from the S pole at the output end 22 , which results in a resistance to 11 A 'and 11 B'. However, since the resistance of 11 A 'and 11 B' is weaker than the attraction of 11 A, 11 B, 11 C, 11 D and 11 E, the resistance of 11 A 'and the driving force of 11 A can balance. Accordingly, the resistance of 11 B 'and the driving force of 11 B can balance. However, it follows that the magnetic tape 1 can be moved forward in the monopolar magnetic section 2 along the row of magnets by the driving force of 11 C, 11 D and 11 E. This balancing phenomenon of the driving force and the resistance force is irrelevant from the point of view of the principle of economy, which is why, according to the invention, the magnetic force at the output end 22 of the monopolar magnetic section 2 is suitably reduced. This can be seen in particular from FIG. 2, in which figure the magnetic force at the outlet end 22 is suitably reduced step by step by gradually decreasing the size of the magnets 42 , so that the attraction force caused by the magnets 42 is reduced accordingly. Due to such a configuration, the driving force of the magnet 11 is A 'is not balanced, the same applies for the magnets 11 B and 11 B' by the holding force of the magnet 11A, ie, the driving force is 11 B not by the holding force of the magnet 11 B ' balanced. In addition, the attraction and the repulsive force of the monopolar magnetic portion 2 toward the magnetic tape 1 can be changed very suddenly when the attractive force A of the monopolar magnetic portion 2 toward the opposite pole of the magnetic tape 1 toward the repulsive force B of said portion 2 toward the same pole of the magnetic tape 1 is added as shown in Fig. 2-A. Then the magnetic tape 1 inserted in the section 2 can be moved in the direction shown by the arrow.

If the monopolar magnetic sections 2 are arranged alternately as shown in FIG. 3, the magnetic tape 1 is assembled endlessly, that is to say without an end, and if the tape 1 is arranged in said section 2 , the tape 1 can be circular in section 2 without interruption are moved circumferentially by the attractive and repulsive forces caused by the band 1 and section 2 .

If the monopolar magnetic section 2 is divided into two parts, one part of which is provided on the top and the other part on the underside, the section 2 can stop the magnetic tape 1 , ie interrupt the movement of the tape 1 when the upper one or the lower part is removed from the other part. Then the section 2 cannot act to cause the attraction or the repulsive force towards the band 1 .

Claims (1)

Method for generating a magnetic driving force, characterized in that a magnetic tape ( 1 ) made of a plurality of magnets ( 11 ) of the same polarity and size are arranged in a row at a distance from one another, the distance between adjacent magnets ( 11 ) being half their length and that the magnetic tape ( 1 ) is arranged in more than one monopolar section ( 2 ) for its forward movement in the monopolar section.