KR101082880B1 - double-core structure for high-utility. - Google Patents

Abstract

The present invention relates to a high-efficiency twin-core structure, and more particularly, to a high-efficiency twin-core structure that minimizes load, heat generation, and the like, which are attracted in the reverse direction by reverse electromotive force inevitably generated by a conventional core structure and a winding method. It is about.

High efficiency double core structure of the present invention,

To offset the load caused by back EMF,

A first core part 120 around which the first coil 110 is wound;

A second core part 220 around which the second coil 210 is wound;

A first magnetic induction core part 300 to which one side of the first core part and the second core part are coupled;

And a second magnetic induction core part 400 coupled to the other side of the first core part and the second core part, wherein the first coil and the second coil are wound in opposite directions.

The present invention provides a dual-core structure to provide the effect of minimizing the overall load (load pulled in the reverse direction of rotation) and heat generated by the counter electromotive force.

Permanent magnet, electric motor, coil, generator, counter electromotive force.

Description

Double-core structure for high-utility.}

The present invention relates to a high-efficiency twin-core structure, and more particularly, to a high-efficiency twin-core structure that minimizes load, heat generation, and the like, which are attracted in the reverse direction by reverse electromotive force inevitably generated by a conventional core structure and a winding method. It is about.

The counter electromotive force refers to the electromotive force opposite to the electromotive force of the power generated in the armature coil of the generator and the motor or the primary coil of the transformer.

The counter electromotive force is generated when an electrical load is applied, and the electrical load means electricity.

In general, when electricity is used, current flows in a coil, which flows in a direction opposite to the existing electromotive force.

At this time, as described in the Fleming's left hand law, rotational force (torque) is generated in a direction opposite to the rotation direction of the rotor, thereby preventing the existing rotation.

The above phenomenon is defined as a load, and additional energy has to be put in order to solve the load or maintain the same RPM.

At this time, the amount of energy input is required for the power corresponding to about three times the output power of the generator.

Eventually, due to the above-described generators, motors, transformers, and the like using conventional coils, the efficiency was inevitably lowered.

Therefore, there is a need to provide a means for increasing the rotational force of the rotor by canceling the rotational force (torque) acting in a direction opposite to the rotational direction of the rotor generated by the direction of the counter electromotive force, or rather using the direction of the counter electromotive force. This will enable the design of high-efficiency generators and motors, heat-free transformers and electronics.

Accordingly, the present invention has been proposed in view of the problems of the prior art as described above, and an object of the present invention is to provide a twin-core structure to minimize the overall load (load pulled in the reverse direction of rotation) and heat generation caused by counter electromotive force. I'm trying to.

Another object of the present invention is to provide a repulsion generated by diamagnetization of the first magnetic induction core portion and the second magnetic induction core portion of the twin-core structure, thereby increasing the RPM of the rotor and simultaneously reducing the input energy.

Another object of the present invention is to form the first core portion, the second core portion, and the first magnetic induction core portion and the second magnetic induction core portion as a ferrite for the core, while operating at a predetermined frequency or higher while increasing the magnetic flux density accordingly. To eliminate the eddy currents.

Still another object of the present invention is to enable a selective application according to the intended use by varying the wiring method of the coil depending on the case where it is used in series or in parallel.

In order to achieve the problem to be solved by the present invention,

High efficiency dual core structure according to an embodiment of the present invention,

To offset the load caused by back EMF,

A first core part 120 around which the first coil 110 is wound;

A second core part 220 around which the second coil 210 is wound;

A first magnetic induction core part 300 to which one side of the first core part and the second core part are coupled;

And a second magnetic induction core part 400 coupled to the other side of the first core part and the second core part, wherein the first coil and the second coil are wound in opposite directions.

The high-efficiency twin-core structure according to the present invention having the above configuration and operation provides a twin-core structure to minimize the overall load (load pulled in the reverse direction of rotation) and heat generation caused by counter electromotive force.

In addition, by providing the repulsive force generated by the diamagnetic of the first magnetic induction core portion and the second magnetic induction core portion of the dual-core structure to increase the RPM of the rotor and at the same time reduce the input energy, high efficiency generator, high efficiency motor, It will provide high efficiency transformers and electronic products with minimal back electromotive force and heat generation.

Further, when the first core portion, the second core portion, the first magnetic induction core portion, and the second magnetic induction core portion are formed of a ferrite for the core, and operated at a predetermined frequency or more, the eddy current can be removed while increasing the magnetic flux density accordingly. As a result, the core portion and the magnetic induction core portion laminated with the conventional silicon steel sheet are provided at a magnetic flux density of about 1/4 as compared with the core portion and the magnetic induction core portion laminated with the conventional silicon steel sheet.

In addition, it is possible to use a series connection method to increase the voltage or to use a parallel connection method to increase the amount of current to provide an effect that can be selectively applied according to the intended use.

High efficiency twin-core structure of the present invention for achieving the above object,

To offset the load caused by back EMF,

A first core part 120 around which the first coil 110 is wound;

A second core part 220 around which the second coil 210 is wound;

A first magnetic induction core part 300 to which one side of the first core part and the second core part are coupled;

And a second magnetic induction core part 400 coupled to the other side of the first core part and the second core part, wherein the first coil and the second coil are wound in opposite directions.

At this time, when used in series,

Characterized in that the start point A of the first coil and the start point B 'of the second coil are connected, or the output point A' of the first coil and the output point B of the second coil are connected. .

At this time, when used in parallel,

The start point A of the first coil and the output point B of the second coil are connected, and the output point A 'of the first coil and the start point B' of the second coil are connected. .

In addition, the high efficiency double core structure of the present invention,

The input frequency is characterized in that 60Hz ~ 1KHz.

At this time, the material of the first core portion, the second core portion, the first magnetic induction core portion and the second magnetic induction core portion is characterized in that the ferrite for the core.

In this case, according to another embodiment, the first core part, the second core part, the first magnetic induction core part, and the second magnetic induction core part may be formed of a mixed material of a core ferrite and a laminated silicon steel sheet. .

Hereinafter, the embodiment of the high efficiency double core structure according to the present invention will be described in detail.

1 is a perspective view of a dual-core structure for high efficiency according to an embodiment of the present invention.

As shown in Figure 1, the high-efficiency twin-core structure of the present invention,

To offset the load caused by back EMF,

A first core part 120 around which the first coil 110 is wound;

A second core part 220 around which the second coil 210 is wound;

A first magnetic induction core part 300 to which one side of the first core part and the second core part are coupled;

And a second magnetic induction core part 400 coupled to the other side of the first core part and the second core part, wherein the first coil and the second coil are wound in opposite directions.

By providing a twin-core structure of the present invention as described above, if used in electronic products including not only generators but also coils, that is, motors, transformers, LCD TVs, etc., it is possible to minimize the overall load generated from the coils.

In other words, when the dual-core structure is applied to the generator and the motor, the reverse force that hinders the rotation of the rotor generated by the counter electromotive force disappears. This is to obtain a higher RPM with the same input energy or to obtain the same RPM. Less input energy is needed, which means that more efficient generators and motors can be built.

In addition, in the case of a transformer, an electronic product such as a coil, it is possible to provide an additional advantage that does not require a device for cooling the heat by reducing the heat generated from the coil.

Referring to Figure 1 to be described in more detail as follows.

The first coil 110 is wound around the first core part 120, and the second coil 210 is wound around the second core part 220.

In addition, the first magnetic induction core unit 300 is coupled to one side of the first core unit and the second core unit, and the second magnetic induction core unit 400 is connected to the other side of the first core unit and the second core unit. Will be combined.

At this time, the first coil and the second coil is to be wound in the opposite direction as shown in FIG.

Referring to the generator, for example, as shown in Figure 3, the direction of the counter electromotive force is determined in the winding direction of the coil, the present invention has a twin-core structure in which the winding direction of the coil is opposite to each other, so Formed opposite to each other, the rotational forces (torques) acting in a direction opposite to the rotational direction of the rotor generated by the counter electromotive force cancel each other, thereby reducing the mechanical and electrical loads generated by the counter electromotive force.

In addition, the heat generated in the transformer, electronics, etc. is also due to the back electromotive force of the coil, the twin-core structure of the present invention will be able to reduce the heat generated in the coil because the offset of the heat load generated by the back electromotive force.

Meanwhile, referring to FIG. 4, when a rotor having a magnetic body is rotated in a dual core structure, two poles of the rotor magnetic material, that is, the N pole 10 and the S pole 20 sequentially pass through the core. When the first magnetic induction core portion 300 and the second magnetic induction core portion 400 become a diamagnetic material and the N pole of the rotor passes through the first magnetic induction core portion 300, the first magnetic induction core portion 300 ) And the magnetic pole of the first magnetic induction core portion 300 becomes the S pole when the S pole of the rotor passes.

In this case, the second magnetic induction core unit 400 has a magnetic pole opposite to that of the first magnetic induction core unit 300.

As described above, the rotor magnetic body and the magnetic induction core generate repulsive force to push the rotor by diamagnetization of the first magnetic induction core part 300 and the second magnetic induction core part 400. RPM increases and input energy decreases.

The degree of semi-magnetization of the first magnetic induction core unit 300 and the second magnetic induction core unit 400 is the material and electrical frequency of the first magnetic induction core unit 300 and the second magnetic induction core unit 400. This depends on the amount of current in the back EMF.

In addition, the first core portion, the second core portion, the first magnetic induction core portion 300 and the second magnetic induction core portion 400, the higher the magnetic flux density, the greater the strength of the semi-magnetization.

Therefore, in the related art, a magnetic induction core part in which a silicon steel sheet having a high magnetic flux density is laminated is used, and power generation can be increased, but eddy current is also increased.

However, according to the present invention, the first core part, the second core part, and the first magnetic induction core part 300 and the second magnetic induction core part 400 are constituted by a ferrite for the core and operated above a predetermined frequency. The magnetic flux density is about 1/4 of the magnetic induction core portion, so that electric power can be produced as much as the magnetic induction core portion laminated with the conventional silicon steel sheet.

This is because the eddy current can be removed by the ferrite for the core.

In addition, the higher the frequency, the greater the intensity of diamagnetization, preferably 60 Hz to 1 KHz.

In addition, the current amount of the counter electromotive force also affects the diamagnetization. The larger the current amount of the counter electromotive force, the greater the intensity of the antimagnetization. When the antimagnetization becomes stronger, the rotor, the first magnetic induction core unit 300, and the second magnetic induction are increased. As the repulsive force of the core unit 400 increases, the RPM of the rotor is further increased, and the input energy for rotating the rotor is further reduced.

Figure 2a is an exemplary view showing a wiring method when using a series of high efficiency twin-core structure in accordance with an embodiment of the present invention.

Figure 2b is an exemplary view showing a wiring method in parallel use of a high efficiency twin-core structure according to an embodiment of the present invention.

When using in series as shown in FIG. 2A, the start point A of the first coil and the start point B 'of the second coil are connected, or the output point A' of the first coil and the output of the second coil are The point (B) is connected.

That is, when connecting the start point A of the first coil and the start point B 'of the second coil, a + (-) pole is connected to the output point A' of the first coil and the output point B of the second coil is connected. You will connect-(+) to.

On the contrary, when connecting the output point A 'of the first coil and the output point B of the second coil, a + (-) pole is connected to the start point A of the first coil and the start point B' of the second coil. Connect the (-) pole to.

On the other hand, when using in parallel as shown in Figure 2b by connecting the start point (A) of the first coil and the output point (B) of the second coil to connect the + (-) pole and the output point of the first coil ( A ') and the starting point (B') of the second coil are connected to connect the-(+) pole.

Therefore, the series connection method can be used to increase the voltage, or the parallel connection method can be used to increase the amount of current, thereby providing an effect that can be selectively applied according to the intended use.

6 is an exemplary view showing a conventional generator or motor load curve.

As shown in FIG. 6, when energy of 6 horsepower is input, power corresponding to 2 horsepower is produced, since the secondary eddy current load and the power generation load increase when using electricity.

Here, the mechanical load is determined by the size, weight of the rotor, the type of both bearings supporting the rotor, etc. In the case of a conventional generator, the mechanical load is very high as 97%, so the mechanical load is only a fraction of the total power generation load.

The primary eddy current load is determined by the magnetic strength of the permanent magnets or electromagnets mounted on the rotor, the arrangement of the cores and the number of cores mounted on the generator. The combined load corresponds to about one third of the total generator load, and the secondary eddy current load and the generated load under electric load correspond to about two thirds.

Mechanical loads and eddy current loads under no-load become larger as the generator becomes larger, and smaller as the generator becomes smaller.

However, when the first core portion, the second core portion, and the first magnetic induction core portion and the second magnetic induction core portion according to the embodiment of the present invention are applied to a conventional laminated silicon steel sheet (the energy source is a motor). .) Mechanical load is measured as 1A X 200V = 200W, eddy current load is measured as 4A X 200V = 800W, power generation load is 0W, the total input power is 1,000W.

At this time, the measured output is 3.5AX 200V = 700W. This figure shows that the existing generator has improved the generation efficiency considerably compared to the consumption of 2,400W input power at 700W output. Could be obtained.

FIG. 7 is an exemplary diagram showing a generator or motor load curve in which a secondary eddy current load and a generation load generated by counter electromotive force are removed with a high efficiency twin-core structure according to an embodiment of the present invention.

As shown in FIG. 7, it was measured that the primary and secondary eddy current loads and power generation loads generated by counter electromotive force can be eliminated when the high efficiency twin-core structure of the present invention is adopted.

FIG. 8 is an exemplary view showing a generator or motor load curve in which eddy current load is minimized when a ferrite for a core is configured in a high efficiency dual core structure according to an embodiment of the present invention.

Meanwhile, as shown in FIG. 8, when the first core part, the second core part, and the first magnetic induction core part and the second magnetic induction core part are configured as core ferrites. The mechanical load is measured at 1A X 200V = 200W, the primary eddy current load is measured at 20W, and the generating load is measured at 3A X 200V = 600W, resulting in a total input of 820W.

At this time, the measured output is 3.5AX 200V = 700W. This figure shows that the generator with the existing ferrite core has improved the generation efficiency considerably compared to the consumption of 2,220W of input power at 700W output. The same efficiency can be obtained in the motor.

In conclusion, through the structure of the present invention it is possible to manufacture a generator with a higher efficiency than the conventional generator power generation efficiency 35%.

The power generation efficiency cannot be displayed accurately because power generation efficiency cannot simply be compared with the input power of the motor that operates the generator and the output power of the generator, and the torque of the generator rotor, etc. must be precisely measured.

By providing the high-efficiency twin-core structure to provide the effect of minimizing the overall load (load pulled in the reverse direction of rotation) and heat generated by the back electromotive force.

Those skilled in the art to which the present invention pertains as described above may understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential features of the present invention.

Therefore, the above-described embodiments are to be understood as illustrative in all respects and not restrictive.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

High-efficiency twin-core structure of the present invention provides a twin-core structure to provide the effect of minimizing the overall load (load pulled in the reverse direction of rotation) and heat generated by the back electromotive force to be widely used in the field of electronic products for high efficiency It will be possible.

1 is a perspective view of a dual-core structure for high efficiency according to an embodiment of the present invention.

Figure 2a is an exemplary view showing a wiring method when using a series of high efficiency twin-core structure in accordance with an embodiment of the present invention.

Figure 2b is an exemplary view showing a wiring method in parallel use of a high efficiency twin-core structure according to an embodiment of the present invention.

3 is an exemplary view showing an example in which a high efficiency twin-core structure according to an embodiment of the present invention is applied to a generator.

4 is an exemplary view showing an example of diamagnetization of a high efficiency dual core structure according to an embodiment of the present invention.

5 is a view showing the effect of diamagnetization of the high efficiency double-core structure according to an embodiment of the present invention.

6 is an exemplary view showing a conventional generator or motor load curve.

FIG. 7 is an exemplary diagram showing a generator or motor load curve in which a secondary eddy current load and a generation load generated by counter electromotive force are removed with a high efficiency twin-core structure according to an embodiment of the present invention.

FIG. 8 is an exemplary view showing a generator or motor load curve in which eddy current load is minimized when a ferrite for a core is configured in a high efficiency dual core structure according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

110: first coil

120: first core part

210: second coil

220: second core part

300: first magnetic induction core part

400: second magnetic induction core part

Claims (6)

To offset the load caused by back EMF, A first core part 120 around which the first coil 110 is wound; A second core part 220 around which the second coil 210 is wound; A first magnetic induction core part 300 to which one side of the first core part and the second core part are coupled; And a second magnetic induction core part 400 coupled to the other side of the first core part and the second core part, wherein the first coil and the second coil are wound in opposite directions. If using serially, Connecting the start point A of the first coil and the start point B 'of the second coil, or the output point A' of the first coil and the output point B of the second coil, If used in parallel, Connecting the start point (A) of the first coil and the output point (B) of the second coil, and the output point (A ') of the first coil and the start point (B') of the second coil. , The first core portion, the second core portion, the first magnetic induction core portion, and the second magnetic induction core portion, A high efficiency dual core structure, characterized in that the material is a ferrite for the core. delete delete The method of claim 1, In the high efficiency double core structure, High efficiency dual core structure, characterized in that the input frequency is 60Hz ~ 1KHz. delete The method of claim 1, The first core portion, the second core portion, the first magnetic induction core portion and the second magnetic induction core portion, A high efficiency dual core structure comprising a ferrite core and a laminated silicon steel sheet made of a mixed material.

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