JPH0810946Y2 - Rotary transformer - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to a rotary transformer used in a rotary magnetic head device such as a video tape recorder (VTR).

[Outline of device]

The present invention is a rotary transformer that transmits and receives signals between a circuit provided on the rotating side and a circuit provided on the fixed side, and by providing a conductor connected to the ground on at least a part of the magnetic core, a cross in the high frequency region is provided. It seeks to improve talk.

[Conventional technology]

The rotary transformer is widely used as a connecting means for transmitting a signal obtained by a rotary magnetic head provided on the rotary side to a circuit on the fixed side in a rotary magnetic head device such as a video tape recorder.

In general, a rotary transformer is formed by fitting, for example, an annular coil into each winding groove provided concentrically on one side surface of a substantially disk-shaped magnetic core in accordance with the number of channels. A rotor and a stator, which are arranged to face each other with a minute gap therebetween. Then, by electromagnetic coupling between each coil of the rotor provided on the rotating side and the stator provided on the fixed side, for example, a rotating magnetic head connected to the rotor and a reproducing circuit connected to the stator are connected, Video signals and digital audio signals are transmitted.

In such a rotary transformer, improvement in performance is demanded in order to cope with high performance and high functionality in recent video tape recorders. For example, in order to improve crosstalk characteristics between adjacent channels, it has been practiced to provide a short ring in which an insulating wire material is formed into an annular shape between the channels. Furthermore, in order to further improve the crosstalk characteristics, two short rings are provided in the same groove, or two short ring grooves are provided and each short ring is provided therein. There is.

However, since the short ring magnetically separates the channels, a high frequency region (for example, several MHz)
There is a limit to the improvement of crosstalk in the above). This is because the influence of the electric field becomes dominant as the frequency becomes higher. To improve the crosstalk characteristics in the high frequency region, for example, the method of grounding the short ring to the ground, or the fixed drum partially protruding into the short ring groove and connecting it with the short ring There have been proposed methods for lowering the strength of the electric field.

However, the method of grounding the short ring to the ground is not sufficient to reduce the strength of the electric field,
Moreover, the method of projecting a part of the fixed drum into the short ring groove is structurally complicated and difficult to realize.

[Problems to be solved by the device]

Therefore, the present invention has been proposed in view of such conventional circumstances, and an object thereof is to provide a rotary transformer having a simple structure and capable of improving crosstalk in a high frequency region.

[Means for solving the problem]

The present invention has been proposed in order to achieve the above-mentioned object, and in a rotary transformer in which a pair of magnetic cores in which a plurality of coils are concentrically arranged are arranged to face each other, the facing surfaces of the magnetic cores are arranged. Is characterized in that a conductor pattern is formed on the surface on the opposite side to and the conductor pattern is electrically grounded.

[Action]

In the rotary transformer of the present invention, since the conductor connected to the ground is provided on at least a part of the magnetic core, the potential of the core itself is lowered and the electric field generated near the coil is lowered. Therefore, the crosstalk characteristic in the high frequency region is improved.

〔Example〕

Hereinafter, specific embodiments to which the present invention is applied will be described with reference to the drawings.

In the rotary transformer of this embodiment, as shown in FIG. 1, a pair of magnetic cores (1) and (2) are arranged to face each other with a minute gap, and these magnetic cores (1) and (2) are arranged.
Are configured to rotate relative to each other.

The magnetic cores (1) and (2) are formed of a magnetic material such as ferrite in a substantially disc shape, and are provided on the opposing surfaces (1
a) and (2a) the number of coils corresponding to the number of channels (two channels in this embodiment), the number of coils is the number of annular winding grooves (3), (4), (5), (6). have. These winding grooves (3), (4), (5), and (6) are concentrically formed as grooves having a substantially U-shaped cross section, and a coil (7) formed by forming a copper wire or the like into a substantially annular shape. ), (8), (9), (1
0) are fitted and arranged. In the present embodiment, the coils (7), (8), (9) and (10) provided in the winding grooves (3), (4), (5) and (6) in order to increase the inductance. Was laminated in two layers. By doing this, the winding grooves (3), (4),
Since it is not necessary to widen the groove width of (5) and (6), a sufficiently large inductance can be secured with the small diameter core.
The coils (7), (8), (9), and (10) may be stacked on only one magnetic core, or on each channel, if necessary. Good.

The winding grooves (3), (4) are provided between the winding grooves (3), (4), (5), (6) provided on the magnetic cores (1), (2). , (5), (6) respectively, the short ring (11) for preventing mutual interference between the coils (7), (8), (9), (10) and the generation of noise. Short ring grooves (13) and (14) for fitting and arranging (12) are provided. The short ring grooves (13), (14) are also the winding grooves (3), (4),
Similar to (5) and (6), the winding grooves (3), (4), (5), and (6) are formed as concentric circular grooves having a substantially U-shaped cross section.

In addition, the facing surfaces (1) of the magnetic cores (1) and (2)
On the surfaces (1b) and (2b) opposite to a) and (2a), conductor patterns (15) connected to the ground G for lowering the potential of the magnetic cores (1) and (2) themselves. , (16) are provided. The conductor patterns (15) and (16) are provided as large as possible in order to reduce the potential of the magnetic cores (1) and (2) themselves, and for example, the outer peripheral edge and the central portion of the magnetic cores (1) and (2). Center hole (1
c), all its faces (1b), except for the opening edge of (2c),
It is formed like a donut in (2b). As a method of forming the conductor patterns (15) and (16), for example, a method such as printing is mentioned, but this is not particularly limited.

Then, lead wires (17) and (18) are connected to the conductor patterns (15) and (16), respectively.
The other end of (18) is connected to the ground G. Therefore, the conductor patterns (15) and (16) and the lead wires (17) and (18) reduce the potentials of the magnetic cores (1) and (2). For example, when Ni-based ferrite is used for the magnetic cores (1) and (2), since the relative permittivity ε of the ferrite is as large as about 10, one of the magnetic cores (1) has an outer peripheral side channel and The capacitance between the channels on the inner peripheral edge side of the other magnetic core (2) facing each other is about 15 pF.
Conductor pattern (15) connected to ground G in (2),
Providing (16) reduces the capacitance to about 2 pF. It should be noted that simply dropping the short rings (11) and (12) provided on the magnetic cores (1) and (2) to the ground G reduces the capacitance to 10 pF. In this way, if the potential of each of the magnetic cores (1) and (2) itself decreases, the strength of the electric field generated near the coils (7), (8), (9) and (10) decreases, Crosstalk between each channel is improved. Therefore, improvement of crosstalk in the high frequency region can be expected. Further, in the rotary transformer of the present embodiment, the conductor patterns (15) and (16) connected to the ground G are connected to the magnetic cores (1),
The surface (1b) opposite to the facing surface (1a) and (2a) of (2),
Since it is only formed in (2b), the structure is simplified and its manufacture is easy.

The magnetic cores (1) and (2) configured as described above are
A rotary transformer is formed by facing each other with a small gap on the rotating side and the fixed side, and between each coil of the magnetic core (rotor) arranged on the rotating side and the magnetic core (stator) arranged on the fixed side. Video signals, digital audio signals, etc. are transmitted by electromagnetic coupling.

By the way, when the crosstalk characteristics of the above rotary transformer were actually measured, the following results were obtained.

FIG. 2 shows the waveform of the output level signal when the frequency is gradually increased. In FIG. 2, line A shows the output level signal waveform between the same channels, line B ₁ and line B ₂ show the output level signal waveform between adjacent channels, and line C ₁ and line C ₂
Shows output level signal waveforms obtained by plotting the values obtained by subtracting the output values of line B ₁ and line B ₂ from the output values of line A at each frequency. The lines B ₁ and C ₁ show the output level signal waveforms of the rotary transformer when the conductor pattern connected to the ground is not provided in the magnetic core, and the lines B ₂ and C ₂ are connected to the ground. 7 shows an output level signal waveform in the rotary transformer of this embodiment in which a conductor pattern is provided on a magnetic core.

As can be seen from FIG. 2, the crosstalk in the rotary transformer of the present embodiment in the high frequency region is the crosstalk of the rotary transformer in which the conductor pattern connected to the ground is not provided in the magnetic core as shown by the line B _2. It can be seen that the output is much lower than that (shown by line B ₁ ). Therefore, in the rotary transformer of the present embodiment, as shown by the line C ₂ , a waveform close to the output level signal waveform between the same channels (shown by the line A) is obtained, and the crosstalk in the high frequency region is improved. You can see that

The embodiment of the rotary transformer to which the present invention is applied has been described above, but the present invention is not limited to this, and various modifications can be made.

For example, in the above-described embodiment, the conductor patterns (15) and (16) connected to the ground G are replaced by the magnetic cores (1) and (2).
The electric potential of the magnetic cores (1) and (2) themselves is lowered by the provision of the short ring () on the conductor patterns (15) and (16) in order to further lower the electric potential. 11) and (12) may be connected.

Further, the present invention is not limited to the so-called flat rotary transformer in which the disk-shaped magnetic cores (1) and (2) shown in the above-described embodiment are arranged to face each other with a minute gap, but the cylindrical magnetic core is coaxial. The present invention can also be applied to a so-called vertical rotary transformer, which is arranged on the upper side and close to the inner side and close to each other.

[Effect of device]

As is clear from the above description, in the rotary transformer of the present invention, the conductor connected to the ground is provided in the magnetic core, so that the potential of the core itself can be lowered and the magnetic field generated near the coil can be reduced. The strength can be reduced. Therefore, crosstalk in the high frequency region can be improved.

Further, in the rotary transformer of the present invention, since the conductor connected to the ground is formed only on the surface opposite to the facing surface, the structure is simplified,
It is easy to manufacture.

[Brief description of drawings]

FIG. 1 is an enlarged sectional view showing an embodiment of a rotary transformer to which the present invention is applied, and FIG. 2 is a characteristic diagram showing an output level signal waveform when the frequency is increased. 1,2 …… magnetic core 7,8,9,10 …… coil 11,12 …… short ring 15,16 …… conductor pattern

Claims (1)

[Scope of utility model registration request] 1. A rotary transformer in which a pair of magnetic cores, each having a plurality of coils arranged concentrically, are arranged opposite to each other, wherein a conductor pattern is formed on a surface opposite to the facing surface of the magnetic core. A rotary transformer characterized in that the conductor pattern is electrically grounded.