DE1466123C - Support device with a magnetic core - Google Patents

Description

1 2

The invention relates to a tuning device with FIG. 6 shows the relationship between the excitation current of a magnetic core at which the inductance of a and the tuning frequency of the one shown in FIG. 7 demonstration winding by changing the current in an realized ferromagnetic coordination,
energizing winding is effected. . - F i g. 7 Another application example of the invention is already known, in such tuning devices, in which two ferrite cores of ring-shaped devices find the cross-section of the core in the area of the turn, and.

the winding to be controlled is smaller than in the area of FIG. 8 to make a tuning circuit for the case of the taxable winding in order to be able to better control the magnetic turn of a ferromagnetic vote according to the saturation of the core. To the invention for a television receiver,
for this purpose changes in a known advance. FIG. 1 shows a coordination with the core direction in the area of the winding of the wound coils to be controlled. The excitation coil 3 is a cross-section of the core in order to be wound around the core 1 in such a way that the individual degrees of saturation in the various core parts surrounded by the winding controlling the windings through the free space 2 in the ring are one in the loop. The resonance coil can be achieved through special holes 4, essential, linear control characteristics over a desired part of the working area 15 and 5, which are attached in the annular core. It wraps. If direct current is used for excitation, a magnetic variometer is also known, in which a, but this is not limited to direct current from at least two coupled magnetic circuits, but also alternating current or pulsating stationary core is used, whose material a direct current is used for excitation can, has rectangular characteristics of the hysteresis loop 20 and the excitation current flowing through the coil 3 in ι and the at least one of the magnetic flux controlling is changed in any way, the 'winding for setting the remanence states in the inductance of the coil 6.'
Core and a winding of the controlled circuit on. It has been found that in the vote according to one of a partial flow interspersed with that of the invention, in which a capacitor 7 with a more conical magnetic circuit, a reduced cross-section 25 of constant capacitance and a coil 6 is provided, which having core legs. Resonance frequency of the circle by changing the

The invention has the task of changing an excitation current. The, - to create relationships between the magnetic tuning device,. In which see the excitation current / and - 'the effective permeate a steady and precise coordination in a wide flexibility μ-Η is shown in FIG. 2 illustrates. In the case of the frequency range in which the same 30 reception of radio waves is made possible, even if direct current is reliably used with a certain excitation at any time, the relationship of the current value can be adjusted and with which it is made possible between the excitation current and the permeability, To receive radio and television waves with slightly higher sensitivity than the static characteristics and thereby change the. As is known, when alternating current or tuning circuit is to be made as small as possible. 35 pulsating direct current is used for the excitation

In order to solve this problem, there is a decline in this relationship in the form shown in FIG. 2 shown

Mood with a magnetic core in which the mode changed considerably.

Inductance of a winding by changing the If the excitation current / steadily from the value zero

Current is caused in an excitation winding and (corresponding to the curve α in FIG. 2) to the value / _m

at which the cross-section of the core is in the region of 40 (that is the point at which the value μ ™ is its maximum

the winding to be controlled rises smaller than in the range of mum), the relationship is obtained

controlling excitation winding is, according to the invention, between the excitation current / and the resonance frequency

Core made of a ferrite material whose permeability sequence /, which is indicated by the curve a ' in FIG. 3 cause

value / W / 'o is greater than 3 and whose coercive force is clear.

is less than 1 Oersted, the current change takes place in 45. If the excitation current continues according to curve b

the excitation winding in the permeability range of the FIG. 2 is reinforced, you get the through the

Kernes, in which the curve of his '- // - character curve b' in FIG. 3 illustrated relationship between

ristics with increasing excitation current decreasing see the excitation current / and the resonance frequency /.

Has permeability values, and is the cross-sectional If the section α is the one in F i g. 2 shown

area of the core is used in the area of the curve to be controlled, shows the relationship between

development is smaller than half the cross-sectional area in the excitation current and the resonance frequency

Field of excitation winding. any amplification and weakening of the excitation current

With this tuning device, there is expediently a deviation from the curve.

the winding levels of tuning coils, e.g. which is why in this case it is desirable to have a

Antenna coil and the resonance coil in the direction of 55 to use magnetic material that has a con-

of the exciting magnetic field running in the core has constant permeability.

and are the antenna coils and the resonance coil if, in contrast, the part of the curve is used

guided through holes in the magnetic core. which is the curve in F i g. 2, the

The invention becomes so small with reference to the hysteresis of the magnetic material that it

Drawings explained. It show ⁶ ° is negligible. That is why it is possible by yourself

Fig. 1 to 3 the principle of the vote according to when the rise and fall of the excitation current

of the invention should be repeated, always the same frequency im

F i g. Figure 4 shows the application of the invention to a ratio of the same current value when tuning

Broadcast receiver for the medium wave range and to receive.

also a tuning circle for an overlay 65 If a magnetic material is in a tuning

rungsempfänger, mung according to the invention. is used, whose

F i g. 5 the // - // - characteristic of the ferrite material, the hysteresis curve is rectangular, it is also possible

that in the vote according to F i g. 4 is used, borrowed, a relationship between the excitation current and

the tuning frequency, which is almost straight.

It is therefore preferable to use a method of magnetization in a ferromagnetic tuning according to the invention, as shown by curve b in FIG. 2 is illustrated.

If ferrite with a larger hysteresis loss is used as a magnetic material, it is particularly necessary to start the magnetization process according to curve b in FIG. 2 to use.

The method according to the invention can be used in a modulation circuit, in a rectifier circuit, in a resonant circuit, an amplifier circuit or a similar high-frequency circuit. A magnetic alloy, ferrite, a magnetic mass core or the like can be used as the magnetic material. can be used, and it is particularly desirable to use a ferrite material whose high frequency loss is relatively "low and that has a high permeability.

According to the invention, the magnetic properties of the magnetic material significantly influence the efficiency of the tuning, and therefore the selection of this' material is particularly important.

When using ferrite for the ferromagnetic Vote this material. The following Have properties:

(1) The ferrite material used in the ferromagnetic tuning should have a μ-η / μο value that is greater than 3, urtd. the coercive force H ₀ should be less than 1 oersted.

(2) The cross-sectional area should be in the section of the Ferrite material around which the coil is wound, the inductance of which is to be changed, so reduced * that it is less than half the size of the cross-sectional area of the section around which the excitation coil is wound.

If the ferrite material with a small / W / V Value is used in the ferromagnetic tuning according to the invention, it is namely difficult to change the inductance of the group of coils in a wide range. To z. B. the vote in To change the medium wave range (530 to 1600 kHz), it is necessary to increase the inductance of the resonance coil to change by ten or one tenth in both directions.

Therefore the μ, η / μο value of the ferrite material used should be 10. Generally speaking, the ratio μτηίμο for the ferrite material is relatively small, and values around 10 are common. Therefore, the disadvantage of a small μπι / μα value must be compensated for by the shape of the ferrite. If the cross-sectional area of the magnetic circuit at the point where the coil is wound is reduced to less than half the cross-sectional area of the magnetic circuit at the point where the excitation coils are to change the inductance, it is possible to change the inductance of the coil in a wide range. However, if the ratio / < _m / j «o of the ferrite material is less than 3, it is difficult to change the inductance of the coil up to ten times or one tenth even if the cross-sectional area of the magnetic circuit is less than half is reduced. Unless the coercive force of the ferrite is less than 1 oersted, a larger excitation current is required, and this is undesirable from the manufacturing or industrial point of view. The ferrite which is used in the method or in the device according to the invention consists not only of one type of material, but it is very expedient to use combinations of two different types of material. That is, it is desirable that the portion of the core around which the excitation coil is wound has a high permeability and that the portion around which the resonance coil, the antenna coil, and ίο the oscillator coil is wound, has a high permeability. (? -Value. Therefore, if one uses ferrite of high permeability and materials with a high β-value in a tuning according to the invention, electromagnetic waves in the medium wave range of the radio transmitters can be received with high sensitivity. Combinations of ferrite materials can also be used, the components made of hard materials, plastics, rubber or the like. Have.

ao In the following, exemplary embodiments of the finding dealt with.

In Fig. 4 shows a ferromagnetic tuning with ferrite material, which is placed in an overlay device is used for reception in the medium wave range.

1 is a ferrite core of ringfqcm, the outer diameter of which iÜTDtmT, the inner diameter of which is 3.5 mm and the thickness of which is 3 mm. The composition of the ferrite material is as follows: 22.5 CuO / 27.5 Zn / O 0.25 Bi ₂ O ₃ / 49.75 Fe ₂ O ₃ . This material is ^{sintered at 1000 °} C. for a period of 5 hours. The ^ - // properties of the material are shown in FIG. 5 illustrates, from which it can be seen that μ ₀ 700, μ ^ 2500 and the ratio μτη / μο is about 3.6.
The Q value was 6 at 500 kHz (in the case of an annular core). The excitation coil 2 had 400 turns on the main magnetic circuit shown in FIG. 4 is illustrated. 10 is the direct current source, 11 is a variable resistor and 12 is the ammeter for the direct current. Two small bores 3 in the magnetic circuit 1 had a diameter of 1.5 mm, the distance between the bores was 3 mm. The antenna coil 4 with ten windings and the resonance coil 5 with 20 windings ran through these bores. These coils were similar to those shown in FIG. 4 connected circuits shown. In the section of the magnetic circuit in which this is considerably narrower because a piece is cut off (in the exemplary embodiment discussed here, the magnetic circuit was narrowed to a tenth), the oscillator coils 6 and 7 were fitted with 80 and 15 windings, respectively. 8 and 9 are fixed capacities that were 250 and 200 pF, respectively. First, the resonance circuit, consisting of the resonance coil 5 and the capacitance 8, is tuned to 500 kHz by changing the excitation current flowing through the coil 2, and at the same time the oscillator circuit, consisting of the two coils 6 and 7 and the capacitance 9, is set to 965 kHz tuned. Then it is possible to vote on a higher one. A frequency of 500 or 965 kHz can be brought about by steadily increasing the excitation current in coil 2. This makes it possible to receive all frequencies in the medium wave range of the radio transmitters. The relationship between the excitation current and the tuning frequency is illustrated by curve 1 in FIG.

In other words, it is possible to have a voting

Claims (8)

5 6 mung on all frequencies in the medium wave range coil 2 are connected in parallel or in series. For a relatively small change in this example, the relationship between the ErCurrent of 0.1 to 6.3 mA can be achieved. Since the excitation current and the tuning frequency are changed by the excitation current in a current range, curve 2 in FIG. 6 illustrates. In order to avoid the constant 5 winding work that was more difficult than I _m , the ferrite core relationship between / and /, shown in Fig. 6, e.g. B. have a bar shape or pot shape,
are always precisely maintained or maintained, · In F i g. 8, the invention is illustrated, for example, in a television receiver even if the current is changed in strength and direction. 1 is the ringförwurde. If a ferrite material is used, the moderate ferrite core, the outside diameter of which is 10mm has a rectangular hysteresis characteristic, can be 10 and the inside diameter is 3.5 mm. Two relationships between the excitation current and the reso small holes are made in a part by nanzfrequency (see. Fig. 6) are established so that the magnetic flux passes through. These holes can be represented as a straight line, that is, proportionally, have a diameter of 1 mm, and they run off. When the cross-sectional area of the section stood the holes is 3 mm. The ferrite material of the magnetic circuit on which the antenna 15 is composed as follows:. 10 MgO / 15 NiO / coil, the resonance coil and the oscillator coil are 25 ZnO / 50 Fe ₂ O ₃ . This material is made considerably smaller than the one ^{sintered at 1350 0} C when air is exposed. The value of μ ₀ is 100, the cross-sectional area of the magnetic circuit at / < _m is 550, and Q at 100 MHz is 20. The excitation point at which the excitation coil is wound, coil 2 can have 700 turns. 10 is the direct current the inductance of all coils (with the exception of the source 20 and 11 and 11 'are adjustable resistors, exciter coil) in a wide range with small changes - namely the resistor 11' is used to fine-tune the excitation current. Even if the excitation current. 12 is the ammeter for which the ferrite core has a small ratio of μ ₀ and μ »direct current. Through the holes 3 are the antennas, it is possible to wind the inductance in a wide coil 4 and the resonance coil 5. The coupling area by a considerable enlargement of the 25 treatment coils 16 and 17 with five turns each are to change the ratio of the cross-sectional areas mentioned too close to that portion of the magnetic. If the distance between the small circles is wound, which is made much smaller, say a hole 2 smaller, the tenth of the effective cross-sectional area is reduced as the dTF cross-sectional area. which the excitation coil 2 is located. On the As mentioned above, the design is narrowed before the portion of the magnetic circuit preferably made so "that. the antenna coil, the cross-section is at a small distance from the group Resonance coil and the Oszillatojspule around one of the coupling coils, the oscillator coil 18 with five section of the magnetic circuit, the windings of which are attached. With this arrangement or Cross-sectional area smaller than half of the cross-connection of coils as shown in the drawing area of the magnetic circuit, around which 35 is, could be changed with a change in the excitation the excitation coil is wound. "Current of coil 2 by amplification or weakening About electromagnetic waves in the medium wave range in the range from 5 to 110 mA in the television realm the broadcast station with high sensitivity will receive a clear picture and sound to be able to, the coil group to which reception can be reached. the antenna coil, the resonance coil and the oscilloscope 40 In all of the exemplary embodiments described lator coil, wound so that it was preferably used ferrite as the magnetic material, it ^. almost at right angles to the magnetic flux, however, a laminated magnetic alloy, lying, which is generated by the excitation coil and ■ which is electrically isolated, can be used or a goes through the magnetic circuit (see Fig. 4). In magnetic mass core. A ferromagnetic ab- In this case, there is the disadvantage that the induction 45 tuning with magnetic alloy is required change in activity due to the perpendicular to the direction in a frequency range below 10 kHz of the magnetic flux wound coil is small. the eddy current losses are applied. Cu-Zn All coils whose inductance is too high or Ni-Zn ferrite can therefore be used for coordination. change, be wound in the same direction, in order to receive frequencies of the television which the magnetic flux runs after carefully 50 radio, · and Ni-Zn, Mg-Zn and Li-Zn ferrites the magnetic disturbance of the individual coils, sub-appropriate for a vote for the reception of each other has been considered. Frequency-modulated waves and frequencies of the z. B. the resonance coil, the antenna coil and the television broadcasting. Oscillator coil be wound around the same section, As explained in detail, the ferromagnetic which is so considerably smaller as shown in FIG. 4 shows a comparison according to the invention is, whereby between the individual coils tuning with known tuning is relatively small stalls remain. be carried out, and it is possible to In the case of the in FIG. 4 illustrated circuit is accurate and continuous, it is possible, it is also possible to obtain the variable (adjustable) a uniform scale graduation for the receiving resistor 11 · by a group of fixed resistors 60 frequency, and the operation of the tuning and to replace a switch. It is also possible,. ming over long distances is easy.
To receive frequencies of the medium wave range,. as in Fig. 7 illustrates when looking at ferrite cores claims:
1 and 1 'are used, with the. - ... Antenna coil and the tuning coil 3 or 4 with 65 1st tuning device with a magnetic core, 15 or 50 windings are attached, while in which the inductance of a winding is through on the other core the oscillator coils 6 and 7 change the current in an excitation winding with 80 or 10 windings are located and the exciter is effected and in which the cross-section of the The core in the area of the winding to be controlled is smaller than in the area of the controlling excitation winding, characterized in that the core consists of a ferrite material whose permeability value μτη / μο is greater than 3 and whose coercive force is less than 1 Oersted, that the current change in the excitation winding takes place in the permeability range of the core in which the curve of its ^ - // - characteristic shows decreasing permeability values with increasing excitation current, and that the cross-sectional area of the core in the area of the winding to be controlled is less than half the cross-sectional area in the area of the excitation winding. 2. Tuning device according to claim 1, characterized in that the winding planes of tuning coils, e.g. B. the antenna coil (4) and the resonance coil (5) in the direction of the im Core extending exciting magnetic field lie. 3. Tuning device according to claim 2, characterized in that the antenna coil (4) and the resonance coil (5) are guided through holes (3) in the magnetic core. 4. Tuning device according to claim 1, characterized in that the winding planes of the tuning coils (4, 5) perpendicular to the direction of the magnetic flux running in the core at one Place where the core cross-section is less than half of the core cross-section at the location of the Excitation coil is. 5. Tuning device according to claim 1 or the following, characterized in that the ferrite core consists of more than two materials selected from the group of ferrites of high permeability, of ferrites with a high Q value, of soft ferrites, hard ferrites, plastics and rubber are. 6. Tuning device according to one of claims 1 to 5, characterized in that as Excitation current direct current, alternating current or pulsating direct current is used. 7. modification of the tuning device according to claim 1 to 6, characterized in that for The magnetic core is used instead of ferrites as a magnetic material, a material that is part of the group belongs to the magnetic alloys or is a mass core. 8. Tuning device according to one of claims 1 to 7, characterized in that on a closed magnetic core made of ferromagnetic material has more than two Coils are provided and that the frequency tuning is done by changing the current, the through more than two exciter coils, so that the inductivity of more than other exciter coils is thereby changed. 1 sheet of drawings 009 538/281