DE977886C - Process to achieve quasi-amagnetic behavior of ferromagnetic bodies - Google Patents

Description

Process for achieving quasi-amagnetic behavior of ferromagnetic Body The invention is concerned with a method for achieving quasi-amagnetic Behavior of ferromagnetic bodies, d. i.e., the ferromagnetic bodies behave themselves in a magnetic field with a much constant direction and size like non-ferromagnetic ones Body, d. i.e., the effect of the magnetic moment induced by this field is zero.

Although the method according to the invention can advantageously be used in all cases in which it is a question of achieving a quasi-amagnetic behavior in ferromagnetic bodies in a magnetic field of essentially constant direction and size, be it in the following in connection with the elimination of the induced moment of vehicles, especially ships, which are not allowed to cause any significant disturbance of the earth's magnetic field at a certain distance. Such vehicles are partly made of non-magnetic materials, but in all cases they still have a very large number of components that are made of steel, that is, of a ferromagnetic material, for reasons of strength alone. A large part of these components made of ferromagnetic material in vehicles has a vertical position or the magnetic moment that develops in these components under the influence of a magnetic field is directed vertically: However, it is precisely these components that are suitable for significant magnetic disturbances below the vehicle Cause the earth field, because in our latitudes the vertical component of the earth field is about twice as large as the horizontal component. The magnitude of the magnetic field strength as a function of the magnitude of the magnetic moment M and as a function of a distance Z in the first main position results from the relationship The first main position is understood to be a measuring position in which the direction of the magnetic and the sensitive direction of the measuring probe measuring this moment are the same, the axes of the magnetic moment and the measuring probe coinciding.

If a magnetic moment is measured in the second main position, then the field strength at distance Z reaches an amount of It can be seen from this that with a measurement in the second main position the height of the magnetic field only reaches a value of 50% of what was measured in the first main position with the same magnetic moment. When measuring in the second main position, the magnetic moment and the probe measuring this moment are parallel, but the axes of and measuring probe do not coincide, they only lie in one plane which contains both axes. It can be proven that in a measurement in which the measuring probe is directed vertically, but the magnetic moment is directed horizontally (hereinafter referred to as the third main position), the height of the measured magnetic field at distance Z only reaches 42% of the amount that is in the first main layer is measured.

If one takes into account that, as mentioned, in our latitudes the vertical component of the earth's field is twice as the horizontal component, and one continues to carry the fact that the determination of disturbances of the magnetic earth field installed measuring probes are arranged vertically, one arrives at the following result A component made of a ferromagnetic material installed on a vehicle, which is arranged vertically has opposite a horizontally arranged of the same size component with regard to the generation of magnetic interference fields five times as effective, the measurement of this interference field by means of a perpendicular arranged measuring probe takes place. The induced magnetic moment is at this vertically arranged component I must be larger by a factor of 2 than with a horizontally arranged component because the vertical component generating the induced magnetic moment is twice as large as the horizontal component, and 2. will be in the case of a vertical component Position of the measuring probe and a horizontal position of the magnetic moment (third Main position), as already mentioned above, measured only 42% of the amount in the first main position would be measured.

This means that two components of the same size, one of which may be arranged vertically and the other horizontally, cause interference fields with respect to their effect on a vertically positioned measuring probe at a distance Z in the earth's magnetic field, which have the following relationship to one another: ' where Z = the interference field originating at the distance Z from the vertical component and Hzh = the interference field originating at the distance Z from the horizontal component.

The magnitude of a magnetic moment induced by a magnetic field H. of a ferromagnetic body is not constant, but changes under the influence mechanical vibrations. In Fig. I the function 4 T = f (H) is shown, namely, on the one hand the so-called new curve (I) with the moment M1 at H1 and on the other hand the idealized curve (2) with the moment M2 at the same value of H1 is shown. The amount of magnetization 4 T (i.e.

the magnitude of the magnetic moment) changes under the influence large mechanical vibrations at a certain field strength H1 in such a way that that an approximation of 4 T to the stable point M2 of the ideal characteristic occurs. These vibrations can be caused by the application of a decaying alternating magnetic field specific maximum amplitude (effect of aging). To with one ferromagnetic body in a magnetic field of essentially constant size and direction to achieve a quasi-amagnetic behavior, d. H. that through this Magnetic field induced magnetic moment to disappear, suggests the Invention, one or more permanent magnets on the ferromagnetic body corresponding size and shape, their magnetic moment that of the ferromagnetic Body is directed in the opposite direction, by z. B. welding, soldering or gluing to attach. Is the effect of all magnetic moments in the outer space zero or opposite is small in the uncompensated state, the ferromagnetic body behaves in quasi-amagnetic to the magnetic field as long as no mechanical vibrations act on him. Spreads under the action of mechanical vibrations on the other hand, the one caused by the permanent magnet initially only in its immediate Proximity generated magnetization state over the body to be compensated, so that a magnetic moment occurs which is similar to the originally induced magnetic Moment is opposite. In a further development of the invention will in order to avoid this magnetic moment the ferromagnetic body and the permanent adjustment magnet firmly connected to it with simultaneous action mechanical shocks of the magnetic field generating the induced magnetic moment and / or alternating magnetic fields, the size of which is slowly reduced to zero, exposed (aging process). In Fig. 2 the course of the magnetization (4.J) depending on the level of mechanical or magnetic vibrations Alternating field (E) for different initial values (P0) of the magnetization of the ferromagnetic Body and the adjustment magnet connected to it before the action of the mechanical Shocks or the alternating magnetic field shown. The course of the Curve 2 shows that with increasing alternating magnetic field strength, the magnetic body to be compensated is initially more and more overcompensated. In the end If the alternating field strengths continue to grow, there is a second effect, the acts in the opposite direction. From point P2,2 there is an ever stronger one predominant weakening (demagnetization) of the compensation permanent magnet with increasing Alternating field strength, thereby reducing the overcompensated magnetic moment of the magnetically compensated body again. If the alternating field strength, the the body to be compensated is exposed, increased to extremely high values, so the magnetization of the permanent magnet is completely extinguished. Consequently the body to be compensated must have the ideal magnetization as the maximum limit value under the action of the inducing field, this is usually included 2 to 5 times the amount and in the direction of the induced magnetization. Between the strongly overcompensated state (point P2,2 in Fig. 2) and the state of the idalen Magnetization (point P4,2 in Fig. 2) is at a certain alternating field strength a zero crossing of the magnetization (point P3,2). But this zero crossing is in contrast to the first zero crossing (point P0,2 or P1,1) completely stable against mechanical shocks. Because of the equivalence of mechanical vibrations and alternating magnetic fields for changing the state of magnetization corresponds to the relatively very high alternating field that led to the stable zero point has (point P3,2), extremely large mechanical vibrations that lead to destruction of the material would lead. Because the mechanical vibrations that occur in nature are much lower than those that produce these high alternating magnetic fields natural vibrations cannot change the state of magnetization change more. The curves i to 3 in FIG. 2 show the dependence of the magnetization state from the applied magnetic alternating field of a ferromagnetic body and the Adjusting magnets connected to it, whose moments are opposite, but not are of the same size, so that a positive (point P0,1) or negative (point P0,3) residual magnetization was present. The positive residual magnetization can be chosen so that the first zero crossing (point P1,1) at so strong alternating fields takes place that the mechanical corresponding to these fields Vibrations are much greater than those occurring in nature, so that naturally occurring mechanical vibrations do not affect the state of magnetization can influence more. The presence of residual magnetization before application the alternating magnetic fields is given preference, as this is not a complete one Adjustment of the two opposite magnetic moments of the permanent magnet and the ferromagnetic body requires.

If you want the particularly strong vertical, induced, magnetic Moment of a ferromagnetic body, e.g. B. a motor, a generator, a Guns, or parts thereof, such as screws, bolts and connecting rods, to disappear bring, the ferromagnetic body with a permanent magnet will be more appropriate Size and shape provided and mechanical vibrations and / or alternating magnetic fields exposed. In the same way, the disruptive effect of Ammunition, e.g. B. grenades, made to disappear. In Fig. 3 is an example the many possible uses of the invention on a ferromagnetic hollow cylinder with a removable cover the procedure for achieving a quasi-magnetic behavior shown schematically. With i a hollow cylinder made of iron is referred to, which in advantageously for receiving ferromagnetic bodies, such as. B. Tools, Devices, screws, nails or ammunition, cans and the like on vehicles, is used. The hollow cylinder can also be used to hold canned food. In Permanent magnets 2 are embedded in the bottom and / or in the upper edge of the hollow cylinder i. The hollow cylinder i is surrounded by a coil 3, which by its strength variable alternating current source 4 is fed. In the direction of the longitudinal axis of the hollow cylinder i a pair of forester probes $ is arranged in a gradient arrangement in the immediate vicinity. With the help of the magnetic field measuring device 6 connected to the probes, the Magnetization state measured and the strength of the alternating field increased so long until the field measuring device displays the value zero after the alternating field has subsided. In the same way, the induced vertical moment of entire vehicles, z. B. of ships and iron, make it disappear. Be on the vehicle suitable permanent magnets attached and the vehicle a rising and decaying alternating magnetic field exposed to the state of magnetization Zero is reached. A particular advantage of the invention is that on the according to the invention Wise ferromagnetic bodies, which are exposed to an inducing field, can be treated in such a way that after this treatment they are at a defined In this inducing magnetic field, they behave as if these bodies were created from a non-ferromagnetic material. Another advantage of the invention is it that z. B. vertically to be installed components for non-magnetic vehicles the assembly can be treated in the manner according to the invention and thereby in addition to the disappearance of the vertical component of the magnetic interference field achieve an extremely stable state in relation to mechanical vibrations.

The components treated by the method according to the invention can also advantageously z. B. on ships with magnetic self-protection systems be used.

Claims (5)

PATENT CLAIMS: I. A method for achieving quasi-amagnetic behavior of ferromagnetic bodies in a magnetic field of essentially constant size and direction, characterized in that the ferromagnetic body is provided with at least one permanent magnet, the magnetic moment of which corresponds to the moment of the ferromagnetic induced by this magnetic field Body is opposite. 2. The method according to claim I, characterized in that the Moment of the permanent magnet the induced moment of the ferromagnetic body just picks up. 3. The method according to claim I and / or 2, characterized in that that the ferromagnetic body and the permanent magnet connected to it mechanical Shocks and / or decaying alternating magnetic fields is subjected. 4. The method according to claim 3, characterized in that before the action of mechanical vibrations and / or magnetic alternating fields the induced Moment of the ferromagnetic body is greater than the moment of the permanent magnet. 5. The method according to claim 3, characterized in that before the action of mechanical vibrations and / or the alternating magnetic fields (aging process) the induced moment of the ferromagnetic body is smaller than the moment of the permanent magnet is: 6. The method according to one or more of claims 3 to 5, characterized in that that the alternating magnetic field used is so large that the corresponding to it mechanical vibrations lead to the destruction of the ferromagnetic body would. 7. The method according to any one of the preceding claims, characterized in, that the alternating magnetic field used to reach the stable zero point corresponds to a mechanical shock which is greater than one in this case ferromagnetic body every occurring mechanical shock. B. Procedure according to one or more of claims 3 to 6, characterized in that the Interference field effect in the outer space of the ferromagnetic body with the permanent magnets with the help of arranged in the immediate vicinity of the ferromagnetic body, Förster probe pairs connected to a magnetic field measuring device in gradient switching is determined. G. Method according to one or more of the preceding claims, characterized in that the method for eliminating the earth's field induced vertical moment of ferromagnetic bodies is used. Io. Method according to claim g, characterized in that these ferromagnetic bodies Components or parts of components of non-magnetic vehicles, e.g. B. Ships are. II. The method according to claim Io, characterized in that the component is a container for storing ferromagnetic tools and devices. or from canned food is. I2. Method according to claim g, characterized in that the ferromagnetic Body is an iron vehicle, e.g. a ship. 13. The method according to claim g, characterized in that the ferromagnetic body ammunition, e.g. B. a grenade is. 14. The method according to any one of claims g to i i, characterized in that the ferromagnetic bodies treated with it in vehicles, e.g. B. Ships with magnetic self-protection systems.