KR101139819B1 - Variable capacitor - Google Patents

Abstract

The present invention relates to a variable capacitor. The variable capacitor of the present invention includes a stator having a plurality of stator electrodes; And a rotor having a plurality of rotor electrodes positioned on the stator and provided on the rotatable rotating shaft, wherein the rotor is provided on the rotating shaft and rotates according to the rotation of the rotating shaft. And a feeding bridge provided in contact with the rotating plate to transfer current to the rotating plate, the current being provided to the rotating plate, the rotating shaft, and the rotor electrode through the feeding bridge, and the rotation is performed according to the rotation of the rotor. A variable capacitance occurs between the electron electrode and the stator electrode. According to the variable capacitor of the present invention, since the current is supplied to both sides of the rotating shaft provided with the rotor electrode, the current is uniformly supplied throughout the rotor electrode, thereby efficiently forming a variable capacitance. In addition, a feed bridge for providing a current to the rotating shaft is provided to provide a stable current to the rotating shaft and the rotor electrode.

Description

Variable capacitors {VARIABLE CAPACITY}

The present invention relates to a variable capacitor, and more particularly to a variable capacitor for varying the capacitance by rotating the rotor electrode with respect to the stator electrode.

In general, the variable capacitor is composed of a plurality of stator electrodes and a plurality of rotor electrodes, which means that the capacitance changes according to the effective opposing area of the rotor electrode with respect to the stator electrode.

The configuration and operation principle of the variable capacitor will be briefly described as follows. The stator electrode is fixed to the bottom of the variable capacitor, the rotor electrode is provided on the top of the stator electrode. Here, the rotor electrode is fixed to the rotatable rotating shaft to rotate along the rotating shaft. Rotating the axis of rotation each rotor electrode is located between a plurality of stator electrodes. Here, the variable capacitance is formed in the surface where the stator electrode and the rotor electrode face each other.

As the axis of rotation rotates, the rotor electrode is moved towards the stator electrode. The ratio of the opposing surfaces of the rotor electrode and the stator electrode is changed according to the rotation rate of the rotating shaft. That is, when the rotor electrode is rotated, the opposing area of the rotor electrode with respect to the stator electrode can be changed to change the capacitance.

Here, a feed line is connected to a rotating shaft formed of a conductor in order to supply current to the plurality of rotor electrodes. The feed line is connected to one end of the rotating shaft and rotates with the rotating rotating shaft to operate the rotor electrode. As the rotation axis rotates, the feed line is twisted, and the twisted feed line is cut off. That is, when the power supply line is twisted or broken, current supply to the rotor electrode becomes difficult, and thus the function of the variable capacitor cannot be performed.

In addition, since a feed line is connected to one end of the rotating shaft to supply current, a uniform amount of current cannot be supplied to the plurality of rotor electrodes mounted along the rotating shaft. Therefore, the capacitance cannot be uniformly formed between the plurality of rotor electrodes and the stator electrodes.

SUMMARY OF THE INVENTION An object of the present invention is to provide a variable capacitor for more efficiently supplying a variable capacitance by uniformly supplying current to both sides of a rotating shaft on which the rotor electrode is installed.

One aspect of the present invention for achieving the above technical problem relates to a variable capacitor. The variable capacitor of the present invention includes a stator having a plurality of stator electrodes; And a rotor having a plurality of rotor electrodes positioned on the stator and provided on the rotatable rotating shaft, wherein the rotor is provided on the rotating shaft and rotates according to the rotation of the rotating shaft. And a feeding bridge provided in contact with the rotating plate to transfer current to the rotating plate, the current being supplied to the rotor electrode through the feeding bridge, and the rotor electrode and the stator electrode according to the rotation of the rotor. Variable capacitance occurs between.

In one embodiment, the rotating plate is provided at both ends of the rotating shaft.

In one embodiment, one end of the feed bridge is in contact with the rotating plate and the other end is connected to a feed line for receiving a current.

In one embodiment, the feed bridge has a plurality of contact portions in contact with the rotating plate.

In one embodiment, the plurality of contact portions are provided in the feed bridge to be in contact with any one or both sides of the rotating plate.

In one embodiment, the contact portion is formed in a hemispherical shape.

In one embodiment, the stator includes a first feed plate for providing a current to the stator electrode while fixing the stator electrode at regular intervals.

In one embodiment, the rotor includes a second feed plate connected to the feed line for providing a current to the rotor electrode.

According to the variable capacitor of the present invention, since the current is supplied to both sides of the rotating shaft provided with the rotor electrode, the current is uniformly supplied throughout the rotor electrode, thereby efficiently forming a variable capacitance. In addition, a feed bridge for providing a current to the rotating shaft is provided to provide a stable current to the rotating shaft and the rotor electrode.

1 is a perspective view showing a variable capacitor according to a preferred embodiment of the present invention.
FIG. 2 is an exploded perspective view of the variable capacitor shown in FIG. 1.
3 is an enlarged view of a rotating plate provided with a side of a variable capacitor and a power supply bridge.
4 is a perspective view illustrating a state in which a rotating shaft of the variable capacitor is rotated.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiment of the present invention may be modified in various forms, the scope of the invention should not be construed as limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings and the like may be exaggerated to emphasize a more clear description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals. Detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention are omitted.

1 is a perspective view showing a variable capacitor according to a preferred embodiment of the present invention, Figure 2 is an exploded perspective view of the variable capacitor shown in FIG.

As shown in FIGS. 1 and 2, the variable capacitor 1 according to the present invention includes a stator 10 having a plurality of stator electrodes 12 and a rotor 20 having a plurality of rotor electrodes 22. It consists of. The stator 10 is located below the variable capacitor 1, and the rotor 20 is located above the stator 10. The variable capacitor 1 generates a variable capacitance between the stator electrode 12 while the rotor electrode 22 rotates.

The stator 10 includes a plurality of stator electrodes 12 and a first feed plate 14 on which the stator electrodes 12 are installed. The plurality of stator electrodes 12 are formed of semicircular conductor plates and are arranged and fixed to the first feed plate 14 at regular intervals. The first feed plate 14 is formed of a conductor and has a feed terminal 14a on one side for receiving a current from a power supply source (not shown). The stator electrode 12 receives a current through the feed terminal 14a provided in the first feed plate 14.

The rotor 20 is installed to be in contact with the rotating shaft 23 on which the plurality of rotor electrodes 22 and the rotor electrodes 22 are installed, and the rotating plate 26 and the rotating plate 26 installed on the rotating shaft 23. The power supply bridge 27 is included. The plurality of rotor electrodes 22 are arranged at regular intervals in a semicircular conductor plate like the stationary and electrode 12. The plurality of rotor electrodes 22 are fixed to the rotation shaft 23 to rotate in accordance with the rotation of the rotation shaft 23. At this time, each of the rotating plate electrode 22 is arranged to be input between each stator electrode 12 disposed at the bottom when rotating by the rotary shaft 23. In other words, the stator electrode 12 and the rotor electrode 22 are alternately positioned. The rotating shaft 23 It is formed of a conductor and rotates by driving means (not shown) while being energized with the rotor electrode 22. The rotating shaft 23 is installed in the through hole formed in the second feed plate 24 formed at both ends of the first feed plate 14 of the stator 10. The rotating plate 26 is formed of a conductor and fixed to both ends of the rotating shaft 23. The rotating plate 26 rotates together when the rotating shaft 23 rotates. The feed bridge 27 is connected to one end is connected to the feed line 28 and the other end is in contact with the rotating plate (26). The power supply bridge 27 receives current from a power supply source (not shown) through the power supply line 28 and transmits the electric current to the rotating plate 26. The feed bridge 27 is fixed to the feed line 28 to supply current to the rotating plate 26 that rotates along the rotary shaft 23. One or more feed bridges 27 are provided to contact the rotating plate 26. At this time, the contact portion (27a) is provided in the portion in contact with the rotating plate 26 in the feed bridge (27). The power feeding bridge 27 is provided with a plurality of contact portions 27a so as to contact one surface or both surfaces of the rotating plate 26 to efficiently supply current to the rotating plate 26.

On both sides of the first feed plate 14, there are provided second feed plates 24 for supplying current to the rotor electrode 22, respectively. The second feed plate 24 is provided with a feed terminal 24a for receiving a current from a power supply source (not shown) on one side. The power supply line 28 is connected to the second electrode plate 24. The current provided to the feed terminal 24a of the second electrode plate 24 is delivered to the feed line 28, the feed bridge 27, the rotating plate 26, and the rotating shaft 23, and is supplied to the rotor electrode 22. . Therefore, the capacitance of the rotor electrode 22 is generated between the stator electrode 24 supplied with the current through the first feed plate 14. One or more fixing means 32 having a rod shape is provided between the two second feed plates 24 to maintain the space between the second electrode plates 24.

Here, since the second feed plate 24 and the first feed plate 14 are both conductors, an insulating member 30 for electrical insulation is provided therebetween. In addition, an insulating ring 25 for electrical insulation is provided between the rotation shaft 23 and the second feed plate 24. In addition, the second electrode plate 24 is fixed by the first electrode plate 14, the insulating member 30, and the fastening means 34, and the second feed plate 24 and the fastening means 32 are also fastening means 34. ) Is fixed. As the fastening means 34, for example, a bolt 34a and a nut 34b can be used.

3 is an enlarged view of a rotating plate provided with a side of a variable capacitor and a power supply bridge.

As shown in FIG. 3, the feed bridge 27 is provided with a contact portion 27a at a portion in contact with the rotating plate 26. The contact portion 27a is formed in a hemispherical shape, and the round portion is provided so as to contact the rotating plate 26. The power feeding bridge 27 is provided with a plurality of contact portions 27a so as to contact one surface or both surfaces of the rotating plate 26 to efficiently supply current to the rotating plate 26. The power feeding bridge 27 is divided into two nodes, and each of the separated nodes is provided with contact portions 27a to be in contact with both sides of the rotating plate 26. In addition, in the present invention, the three feed bridges 27 are installed on one rotating plate 26 as an example, but the number of the feed bridges 27 can be adjusted and installed as necessary.

The operation of the variable capacitor 1 will be described below.

4 is a perspective view illustrating a state in which a rotating shaft of the variable capacitor is rotated.

As shown in FIG. 4, the rotor electrode 22 of the variable capacitor 1 rotates according to the rotation of the rotation shaft 23 to enter between the stator electrodes 12 of the stator 10. In the variable capacitor 1, current is supplied to the stator electrode 12 and the rotor electrode 22 so that capacitance is generated according to the opposing area between the stator electrode 12 and the rotor electrode 22. When the current is supplied to the feed terminal 14a provided in the first feed plate 14 of the variable capacitor 1, the current is supplied to the stator electrode 12. In addition, when a current is supplied to the feed terminal 24a provided in the second electrode plate 24 of the variable capacitor 1, the feed bridge 27, the contact portion 27a, the rotating plate 26, and the rotating shaft 23 are provided. The current is moved to supply current to the rotor electrode 22. Here, the rotating plate 26 may be provided at both ends of the rotating shaft 23 to uniformly supply current to the entire rotating shaft 23 than when the current is supplied from one end of the rotating shaft 23.

In order to generate the capacitance, the rotating shaft 23 is rotated in one direction by using a driving means (not shown). At this time, when the opposite area is generated between the rotor electrode 22 and the stator electrode 12, the capacitance is generated in preparation for the opposite area of the rotor electrode 22 and the stator electrode 12. In addition, the opposing areas of the rotor electrode 22 and the stator electrode 12 change as the rotation shaft 23 rotates. Therefore, the effective opposing areas of the rotor electrode 22 and the stator electrode 12 can be changed to change the capacitance.

For example, the rotor electrode 22 and the stator electrode in the state where both the rotor electrode 22 is located at the top so as to be parallel to the ground (when there are no opposing surfaces of the rotor electrode 22 and the stator electrode 12). Since there is no opposing area of (12), the generated capacitance becomes zero. At this time, when the rotating shaft 23 is rotated in one direction, the rotor electrode 22 enters between the stator electrodes 12, and an opposing area of the rotor electrode 22 and the stator electrode 12 is generated. Since the capacitance changes with respect to the opposing area between the rotor electrode 22 and the stator electrode 12, the larger the opposing area of the rotor electrode 22 and the stator electrode 12, the larger the capacitance is generated. do. Although not shown in the drawing, when the rotor electrode 22 is positioned so that both the front surface of the rotor electrode 22 and the front surface of the stator electrode 12 face each other, capacitance is generated to the maximum.

As in one embodiment of the present invention, since the current provided to both ends of the rotary shaft 23 is uniformly supplied throughout the rotary shaft 23, the rotor electrode 22 is uniformly supplied to the plurality of rotor electrodes 22 The capacitance is uniformly generated between the stator electrode 12 and the stator electrode 12.

The embodiments of the variable capacitor of the present invention described above are merely exemplary, and those skilled in the art will appreciate that various modifications and equivalent other embodiments are possible. There will be. Accordingly, it is to be understood that the present invention is not limited to the above-described embodiments. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the present invention includes all modifications, equivalents, and substitutes within the spirit and scope of the invention as defined by the appended claims.

1: variable capacitor 10: stator
12: stator electrode 14: first feed plate
14a: power supply terminal 20: rotor
22: rotor electrode 23: rotating shaft
24: second feed plate 24a: feed terminal
25: insulating ring 26: rotating plate
27: power supply bridge 27a: contact portion
28: power supply line 30: insulating member
34: fastening means 34a, 34b: bolts, nuts

Claims (8)

A stator having a plurality of stator electrodes; And
And a rotor having a plurality of rotor electrodes positioned on the stator and provided on the rotatable rotation shaft.
The rotor
A rotating plate provided on the rotating shaft to rotate according to the rotation of the rotating shaft; And
One or more feed bridges, one end of which is in contact with the rotating plate and the other end of which is connected to a feeding line for receiving a current, to transfer current to the rotating plate;
And a current is provided to the rotor electrode through the feed bridge, and a variable capacitance is generated between the rotor electrode and the stator electrode according to the rotation of the rotor. The method of claim 1,
The rotating plate is provided at both ends of the rotating shaft. delete The method of claim 1,
The feeding bridge has a variable capacitor, characterized in that it has a plurality of contact portions in contact with the rotating plate. The method of claim 4, wherein
The plurality of contact portion is a variable capacitor, characterized in that provided in the feed bridge to be in contact with any one or both sides of the rotating plate. The method of claim 5,
The contact portion is a variable capacitor, characterized in that formed in a hemisphere. The method of claim 1,
The stator includes a first feed plate for supplying a current to the stator electrode while fixing the stator electrode at regular intervals. The method of claim 1,
The rotor is connected to the feed line variable capacitor, characterized in that it comprises a second feed plate for providing a current to the rotor electrode.

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