DE1200899B - Magnetic variometer - Google Patents

Description

Magnetic variometer The subject of the invention is a magnetic variometer, which allows a particularly effective utilization of the polarization current and thus with the smallest possible dimensions the setting of self-induction is allowed, that lie between a high and low value that are far apart, and thus the tuning of an oscillation circuit over a wide range of high frequencies enables.

The need for a magnetic variometer with such properties occurs z. B. on when in a cyclic accelerator for electrically charged Particles have a strong acceleration voltage at the output of an oscillator relatively small power is to be generated, with an inductive cavity resonator or a sliding tube is used. Such a magnetic variometer is also advantageous to be used when a wireless connection on a frequency without switching is to be produced that lies within a band of several octaves, as occurs in the remote control of military equipment.

So far, such resonance circles have been used in many ways to tune them the change of a capacitance or an inductance by mechanical means; included it was possible to work with low losses, the vote took place but clumsy and slow, and it was just sweeping a narrow band of frequencies possible.

Also through electrical changes, namely through changes the dielectric constant of the dielectric of a capacitor or the permeability of the magnetic circuit of an induction coil, a vote can be carried out; in the in the first case only a narrow band about the width of an octave is swept over, and the power remains small while changing the permeability of the Material that forms the magnetic circuit of an induction coil (preferably ferrite), Changes in inductance of the coil are possible in which the ratio of the lowest and highest induction value is several hundred.

To perfect the design of such magnetic variometers is because also the aim of the present invention, the following considerations proceeds: If the magnetic circuit is on its entire length or at least on one surrounded by a helical winding for a large part of the length the variable polarization current flows, so this is for maintenance and the conversion is very annoying, especially when the magnetic circuit is made up of groups of frames and wrestling is formed. Surrounds the winding through which the polarization current flows the magnetic circuit only over a short length, the induction lines close partially outside of the actual magnetic circuit, especially with high values of the Polarization current; this requires a high power consumption. Also occurs with a certain increase in the polarization current in the vicinity of the inducing one Induce saturation before induction at other points in the magnetic circuit reached the desired value.

According to the invention is in a magnetic variometer with a closed magnetic core, the cross section of the magnetic core extending along it The center line changes and the polarizing coil only changes the section with the larger cross-section of the core surrounds the core from a self-contained core of the same cross-section and composed of an open core that is interlocked with the closed core is present. It can have various forms, especially in adaptation to the Closed core shape.

If the closed core is designed as a rectangular frame, Thus, according to an expedient development of the invention, the open core is open at least one of the rectangle sides of the frame placed, of course on the one which also carries the polarization winding.

When using the magnetic variometer in a resonance circuit the polarizing magnetic field is an alternating field of generally high frequency superimposed; the losses of the ferromagnetic material should remain as small as possible. You will therefore use means that lead to the reduction of losses, z. B. the division of the kernel into flat sheets. As for the materials used, the closed core is preferably made of ferrite and the open core is made of ferrite soft steel. The cross-sections of the assembled core are chosen so that that the saturation of the core occurs with practically the same values of the current, which flows through the polarization coil. This leads to an as rational as possible Exploitation of the core. This can also be expressed in such a way that the cross-section of the open core is largest within the coil and in each section of the magnetic circuit the faster it decreases, the greater the flow loss to be compensated for at this point is.

The shape of the open core can be simpler, the larger it is Changes in stepping through the various sections of the magnetic circuit Polarization flux are permissible.

The open core guides the magnetic flux of the polarizing coil to sections of the magnetic circuit to which the flux in the absence of the open core would only be inadequately managed. If in particular the portion surrounded by the coil of the magnetic circuit is saturated, it would be practical in the absence of the open core useless to increase the polarization current to the opposite section of the magnetic circuit because the induction lines are in the air and not would close in the magnetic circuit. The magnetic circuit would therefore be an induction coil practically impossible, for the inductance of the same that of complete saturation the corresponding value of the magnetic circuit.

The invention is described below, by way of example, with reference to FIG the drawing explains, in the figures only those for understanding the invention required parts are shown.

F i g. 1 and 2 are schematic longitudinal sections of two according to the invention Magnetic circuits; F i g. 3 shows schematically one with magnetic circuits according to the invention equipped inductive accelerating cavity resonator; F i g. 4 shows this Cavity resonator equivalent circuit diagram; F i g. 5 and 6 show a cross section and a perspective view of the cavity resonator; F i g. 7 shows in one Diagram of certain properties of the cavity resonator.

The in F i g. 1 and 2 shown magnetic circuits each contain a self-contained core 1 made of a magnetic material. This core, which has a constant cross section over its entire length, has in FIG. 1 the shape of a circular ring and in Fig. 2 that of a rectangular frame. It is surrounded over a short length by the polarization coil 2 , and an open core 3 in the form of a crescent moon (FIG. 1) or a U with pointed legs (FIG. 2) is symmetrical along its length towards this core placed on the transverse plane of the coil, with the center of the crescent moon or the U lying within the coil.

In the case of the in FIG. 3 to 6 illustrated embodiment is the relevant one Magnetic circuit used for the high frequency coil 4, which is part of an inductive Cavity resonator to accelerate the protons in a synchrotron forms.

In such an apparatus, the protons pass through a closed one Path in an annular vacuum chamber 5 and are passed through a Potential difference suitable sense accelerates which between two electrodes 6 and 7 is applied, which the two lips of an insulating interruption 8 (or an "acceleration interval") form this chamber.

Instead of applying the electrical voltage generated by a high-frequency generator with high electromotive force directly to these electrodes, for reasons of economy these are better switched into a resonance circuit containing the inductance 4 and the capacitance 9 , which is excited by a high-frequency generator 10, the power of which can be considerably lower .

The acceleration frequency must change according to the principle of the synchrotron with the energy of the accelerated protons, and the resonance circuit 4 to 9 , like the generator 10, must be able to be tuned to the entire corresponding frequency band.

If the capacitance is variable in the ratio 1: 4, the inductance must be variable in the ratio of 1:35.

The inductance 4 shown in the figures is symmetrical with respect to the body and is formed by two coaxial lines arranged in alignment, each of which surrounds a section of the proton path following the acceleration interval 8. The opposite ends of these lines are short-circuited by the bottoms 11 (Fig. 6), and at their opposite ends the outer conductors are united with one another, whereby the outer wall of the cavity resonator is formed, while their inner conductors, which are insulated from one another, form two sections of the annular chamber 5 realize, which are completed by the mentioned acceleration lips 6 and 7.

The inductance 4 is variable by magnetic cores 1 made of ferrite made which between the inner and outer conductors of each coaxial line are arranged, these cores polarizable by coils 2 and to the above are provided with open cores 3 for the purpose described.

A practical version of the inductive cavity resonator, which has proven itself fully is shown in FIG. 5 and 6 shown.

The one common to the two coaxial lines, the outer wall of the cavity resonator Realizing outer conductor is supported by four plates 4 a made of soft steel (which forming a magnetic shield), which on both sides with Copper foils (for the production of electrical conductivity) are coated, whereby the arrangement a rectangular parallelepiped with a length of 1.90 m, one Width of 1 m and a height of 0.70 m forms.

The inner conductors are made of stainless steel by two sleeves 4 b formed with a width of 450 mm and a height of 134 mm.

At the point of the acceleration interval there is an isolating connection Seal 12 made of the material known under the name Araldit with a width 55 mm tight the two cuffs 4 b. The cuffs 4 b penetrate the floors 11 and their sections lying outside the cavity resonator are connected to the rest of the vacuum chamber by flexible membrane systems.

The magnetic core 1 consists of an arrangement of forty rectangular frames made of ferrite (known under the brand name "Fernilite 1101") with internal dimensions 553 X 200 mm and external dimensions 800 X 447 mm with a thickness of 25 mm. Each of these frames is formed by the union of two large rods 13 and two small rods 14. These frames are joined together in pairs with the aid of removable flanges 15 (FIG. 5), which pull the assembly in place and are fastened to a rigid structure 16 provided within the cavity resonator. Wide spaces 17 separate the frame groups from one another and enable them to be cooled.

The polarization of the core is done by the current, which in two Coils 2 flows, which surround only a small part of the length of the ferrite frame and symmetrical about the median transverse plane of the cavity resonator within it are arranged on the same side of the vacuum chamber. For decoupling the low frequency polarization field The coils 2 are twisted eight-shaped by the high-frequency acceleration field. For this purpose, the frames of each cavity resonator half are combined into packets of ten, and the turns of the coils 2 are sequentially in different sense to the appropriate Rod arrangement of each package wound up, thereby causing the undesired induced electromotive forces are almost completely canceled out by counter-switching. Each coil consists of ten copper tubes with an outer square cross-section, which are cooled by an internal water circulation. The total inductance of this Coils is on the order of 5 mH, while the maximum permissible current is around 400 A. Outside the cavity resonator is a screening device for the Polarization current provided to prevent the passage of high-frequency interference inductions to prevent in the rest of the plant.

The open cores 3 are rods which are attached to the sides of the ferrite frames are placed and the coils 2 penetrate. These bars have a length of 447 mm and a square cross-section with a side length of 50 mm. she are formed by stacks of sheets of mild steel, which have a thickness of 0.5 mm and with each other by means of the material known under the name Araldit are glued. The diagram of FIG. 7 shows the practical importance of presence of the open cores 3.

In this diagram, the ordinates are the tuning frequencies of the cavity resonator plotted in MHz and as the abscissa the strength of the polarization current in amperes, assuming that the cavity resonator is on its at the end of the working cycle current value is maintained.

The curve 18 relates to the case of one evenly distributed around the frames Polarization winding. It can be seen that the tuning frequency is 8.4 MHz with one polarization of 184 A is reached.

The curve 19 relates to the case that the polarization coil is localized and the magnetic circuit has no open cores. There are 460 A polarization current required to achieve the frequency 8.4 MHz.

Finally, curve 20 corresponds to the above-described case of a localized coil combined with open cores. A polarization current of 229 A is then sufficient to achieve a frequency of 8.4 MHz.

Claims (4)

Claims: 1. Magnetic variometer with a self-contained magnetic core, the cross-section of the magnetic core changes along its center line and the polarization coil only surrounds the section with the largest cross-section of the core, characterized in that the core consists of a self-contained core (1) is composed of the same cross-section and an open core (3) resting positively on the closed core. 2. Magnet variometer according to Claim 1, characterized in that the closed core is a rectangular frame formed and the open core on at least one of the rectangular sides of the frame is put on. 3. Magnetic variometer according to claim 2, characterized in that the closed core is made of ferrite and the open core is made of soft steel. 4. Magnet variometer according to claim 1 to 3, characterized in that the cross-sections of the assembled core are calculated so that the saturation occurs in the different sections of the core at practically the same values of the current flowing through the polarization coil. Documents considered: German Patent No. 741 116; British Patent Nos. 470,945, 473,384; U.S. Patent No. 2,799,822.