KR20100128078A - Compact inductor core having noise reduction structure and inductor using the inductor core - Google Patents

Abstract

PURPOSE: An inductor core and an inductor thereof are provided to absorb vibrations from a magnetic core by forming a sound absorbing coating layer on the outer surface of the magnetic core. CONSTITUTION: An inductor comprises a case(14,16), a coating layer(12a) for sound absorption, a magnetic core(12), and a coil(18). The magnetic core is stored in the case. The coating layer for sound absorption is formed in the outer surface of the magnetic core. The coating layer for sound absorption prevents the magnetic core from being contacted with the case in order to prevent vibrations from the core from being transferred to the case. The coating layer is made of a silicon material. The coil is wound in the outer surface of the case.

Description

Compact Inductor Core Having Noise Reduction Structure and Inductor Using the Inductor Core}

The present invention relates to an inductor, and more particularly, to an inductor core having an noise canceling and miniaturization structure for removing vibration and noise generated by magnetism or magnetic force, and an inductor using the same.

The basic passive components of electrical / electronic circuits include capacitors, resistors, and inductors, and these passive components are used as essential components for constructing circuits.

Among the passive elements, an inductor is a circuit element that induces a voltage in proportion to the amount of change in the current, and suppresses a sudden change in the current in the circuit or filters electrical noise. Inductors are classified into tuning coils, choke coils, oscillation coils, and transformers depending on the application.

In particular, the inductor is used as a power factor correction (PFC) of the DC-DC converter and an output choke of the switching mode power supply (SMPS) for the power supply.

The inductor used in the power supply is, for example, a structure in which copper wires are wound in a toroidal shape on the outer circumference of a toroidal core made of a magnetic material, and a toroidal coil has an annular core that forms a magnetic circuit. It is used for noise prevention and ripple cancellation of rectifier circuit because it has little leakage magnetic flux without being affected by.

Recently, the soft magnetic core used in the SMPS power supply has become more demanding in accordance with the trend toward miniaturization, integration, and high reliability of the SMPS power supply. The required characteristics of the SMPS cores for smooth choke coils include adequate inductance (L), low core loss and good DC overlap. As a smooth choke core of SMPS, an amorphous soft magnetic core is widely used.

In the conventional inductor, a magnetic core using a magnetic material is mainly used as a device using magnetic characteristics, and a coil is wound around the magnetic core with a constant number of turns so as to have an inductance for determining the characteristics of an electric / electronic circuit.

On the other hand, when all magnetic materials are externally applied with a magnetic field, the magnetic material is magnetized, and magnetostriction (or magnetostriction) occurs according to the strength of the applied magnetic field.

However, the inductor in which the coil is wound around the magnetic core, such as the toroidal coil, has a magnetic field H formed in the advancing direction of the magnetic core when power is applied to the coil. In this case, most users want to use the magnetic core's use area to the magnetic saturation area in general due to the low cost and miniaturization.

1 is a graph illustrating a noise generation state of a conventional inductor as the magnetic field increases.

However, as shown in FIG. 1, when the external magnetic field H increases and the magnetic body starts to saturate, that is, when the magnetic core is used to the saturation region, the magnetic strain occurs and the vibration occurs according to the magnetic strain. There was a problem that the friction noise of the high frequency region rapidly increased while rubbing the coils or the case around.

On the other hand, the amorphous soft magnetic core used as the smooth choke core of SMPS. In case of Fe-Si-B, the magnetostriction of the magnetic core is +27 ppm and 50wt% Ni. In the case of Co, there is a big difference depending on the magnetic material at about +1.0 ppm or less. As described above, the Fe-based magnetic core is inexpensive in terms of material cost, but the degree of magnetostriction is relatively high compared to other alloys.

Therefore, the inductor used in electronic / electrical equipment is mainly installed in the indoor space and operated because of the characteristics of the equipment. Therefore, inductors made of Fe-based or 50wt% Ni-based magnetic materials with high noise (that is, magnetostriction) cannot be employed. Inductors made of expensive alloys (soft magnetic cores) with low noise had to be used.

On the other hand, when the coil is wound around the outer core of the magnetic core, regardless of the amorphous soft magnetic core, magnetic deformation may occur with respect to general magnetic materials, and in addition, vibration may occur due to magnetic force such as Lorentz force in addition to magnetic deformation. .

In order to solve the noise problem of the magnetic core, Japanese Patent Laid-Open No. 61-55242 is provided with a system in which parts near the gap in the magnetic core are fixed. However, the above-described prior art has a limit in the effect of the magnetic core having a part fixed near the gap because the noise reduction effect related to the mechanical fixed strength is disturbed and the noise near the gap is later suppressed.

In addition, as described in Japanese Patent Laid-Open No. 62-224909, when storing the magnetic core in the case, a system is used to fix the magnetic core by using an adhesive in the gap between the magnetic core and the case to prevent noise from leaking from the main body. Is disclosed. However, this prior art has room for improvement in its operation and further noise reduction is desired.

In addition, Korean Laid-Open Patent Publication No. 1992-7012 discloses a low noise magnetic core that reduces the noise by forming a slitting groove in a magnetic core manufactured by winding an amorphous ribbon or forming a support protrusion in a case. The prior art shows that a noise level of about 10 dB is reduced compared to a magnetic core that does not form a slit groove, but such a noise level reduction is not sufficient.

In the conventional inductor, since the magnetic core and the case are separated or partially fixed, friction noise is additionally generated or vibration is generated in the process of transmitting vibration and noise generated from the magnetic core to the case. have.

In order to solve the above problems, the present invention provides an inductor having a noise reduction and miniaturization structure that can prevent the vibration of the magnetic core according to the magnetostriction or magnetic force is transmitted to the case when the magnetic core is used in the saturation region to block the generation of noise. The purpose is to provide.

Another object of the present invention is to reduce the noise generated and miniaturized to minimize the leakage of the outside through the case by absorbing the noise at the same time as the vibration generated from the coil wound on the magnetic core is transmitted to the case To provide an inductor having a structure.

It is still another object of the present invention to suppress the occurrence of noise by forming a multi-coating layer having different strengths on the magnetic core without including a separate sound absorbing member capable of blocking or absorbing vibration or noise generated from the magnetic core. It is to provide an inductor core and an inductor using the same that have a noise reduction and miniaturization structure in terms of productivity while minimizing the overall size of the circuit.

Another object of the present invention is to remove the separate case separated from the magnetic core by forming a multi-coating layer using a strong insulating and sound-absorbing material in order to the outer periphery of the magnetic core and the coil winding is directly on the outer surface of the multi-coating layer The present invention provides an inductor core having a miniaturized structure and an inductor using the same.

In order to achieve the above object, according to an aspect of the present invention, a case; A magnetic core housed in the case; A sound-absorbing coating layer formed on an outer surface of the magnetic core such that the magnetic core is not in contact with the case, thereby integrating the magnetic core and the case to block the vibration of the magnetic core from being transmitted to the case and simultaneously absorb sound; And a coil wound around the outer circumference of the case.

The coating layer is made of a silicon material, the case is made of a metal material.

In addition, the case is composed of a ring-shaped lower case whose upper part is opened to cover the lower and side surfaces of the magnetic core, and a ring-shaped upper case whose lower part is opened to cover the sides of the upper and lower cases of the magnetic core. .

According to another aspect of the present invention, a toroidal magnetic core; At least two coating layers coated on an outer circumference of the magnetic core and made of a material having a stronger strength toward the outside; And a coil wound on an outer circumference of the coating layer.

The coating layer is formed by stacking a plurality of coating layers of different materials with sound vibration energy, the inner coating layer of the plurality of coating layers in contact with the magnetic core is made of a soft material, the outer coating layer exposed to the outside is a rigid material Is made of.

The flexible material is silicone or urethane, and the rigid material is made of powder or liquid epoxy.

The thickness of the coating layer is made of 0.10mm ~ 0.2mm.

According to another aspect of the present invention, there is provided a magnetic core having a toroidal shape; The inductor core is coated on the outer circumference of the magnetic core and includes at least two coating layers made of a material having a stronger strength toward the outside.

In the present invention described above, by forming a sound-absorbing coating layer on the magnetic core so that the magnetic core does not come in direct contact with the case, even if a low-cost Fe-based magnetic core having a large degree of magnetic deformation is used, vibration generated during magnetic deformation is prevented. By absorbing and blocking the transfer to the case there is an advantage that can significantly reduce the noise compared to the conventional inductor.

In addition, the outer surface of the magnetic core is different in strength, forming a multi-coating layer for absorbing vibration and noise, eliminating the case by eliminating the case, and at the same time to minimize the overall size of the inductor, while also in terms of productivity There is an excellent advantage.

Hereinafter, a configuration of an inductor having a noise canceling and miniaturization structure according to a first embodiment of the present invention will be described with reference to FIGS. 2 and 3.

2 and 3 are exploded perspective views and partial cross-sectional views of the inductor.

The inductor 10 of the first embodiment is a toroidal type magnetic core 12 having a silicon coating layer 12a on its outer surface, an upper case 14 made of a metal material, a lower case 16, and a coil 18. It includes. The upper case 14 is a ring shape of which the lower part is opened to cover the upper part of the magnetic core 12, and the lower case 16 is a ring shape of which the upper part is opened to cover the lower part of the magnetic core 12. The coil 18 is, for example, wound around the insulated copper wire to have a desired inductance value and is wound along the ring-shaped cases 14 and 16.

The magnetic core 12 is formed in a ring shape constituting a closed loop, and is a general magnetic material, preferably amorphous magnetic alloy, and Fe-B, Fe-C, Fe-B-Si, Fe-B-Si-C, Fe Fe-alloy systems such as -B-Si-Cr, Fe-Co-B-Si, and Fe-Ni-Mo-B, and Co-B, Co-Fe-Si-B, Co-Fe-Ni-Mo -B-Si, Co-Fe-Ni-B-Si, Co-Fe-Mn-B-Si, Co-Fe-Mn-Ni, Co-Mn-Ni-B-Si, and Co-Fe-Mn- Co-alloy systems, such as Ni-B, are mentioned.

In addition to the amorphous magnetic alloy, a Fe-Si-B-Cu-Nb alloy or the like may use a Fe-based nanocrystalline soft magnetic material.

Of these magnetic materials, a particularly preferable material may be made of a low-cost Fe-based amorphous soft magnetic core, although magnetic deformation is large.

In addition, the magnetic core 12 according to the present invention particularly uses, for example, an amorphous soft magnetic core having excellent DC overlapping characteristics, which uses an Fe-based amorphous metal ribbon manufactured by a rapid solidification method (RSP). The Fe-based amorphous alloy is an amorphous magnetic alloy containing at least one or more of P, C, B, Si, Al, and Ge as Fe and a base metal as a basic composition.

The amorphous soft magnetic magnetic core is, for example, using a Fe-based amorphous alloy, such as Fe ₇₈ -Si ₁₃ -B ₉ by using an amorphous metal ribbon prepared by the rapid solidification method (RSP), the amorphous ribbon 300 ℃, After pretreatment by heat treatment for 1 hour, the amorphous metal ribbon is pulverized by a pulverizer to obtain amorphous metal powder, and then the amorphous metal powder is classified and mixed in a powder particle size distribution having an optimum composition uniformity.

Thereafter, a binder, for example, phenol, polyimide or epoxy, is mixed with the mixed amorphous metal powder, and then a ring-shaped core is formed by using a press and the molded core is maintained at a temperature of 450 ° C. for 30 minutes. Annealing is performed to obtain the magnetic core 12.

The magnetic core 12 forms a silicon coating layer 12a on the outer surface for noise reduction. That is, the magnetic core 12 is coated by dipping (deeping) the silicon, and assembled to the upper case 14 and the lower case 16 made of a metal material before the silicon is completely cured, and the metal cases 14 and 16 Allow core 12 to be integrally bonded.

The magnetic core 12 is coated with a flexible silicone coating layer 12a on its outer surface and is assembled and integrated by the rigid metal cases 14 and 16. Therefore, the noise generated from the magnetic core 12 is dissipated from the inside of the flexible silicon coating layer 12a and the rigid metal casings 14 and 16 as the sound vibration energy of the sound is passed through the different medium layers and is not spread to the outside. Done.

In addition, the silicon coating layer 12a is formed on the outer surface of the magnetic core 12 to minimize direct contact between the magnetic core 12 and the metal cases 14 and 16 to increase the noise removing effect.

Figure 4 shows the result of measuring the noise of the inductor before the improvement and the inductor 10 according to the first embodiment of the present invention in a graph.

Referring to FIG. 4, the inductor before the improvement without forming the silicon coating layer reaches about 40 dB or more between 7500 to 10000 Hz bands as the frequency level rapidly increases after the 5000 Hz band, whereas the inductor 10 ), The noise level does not increase rapidly even in the frequency range of 5000Hz, and the maximum noise does not exceed about 30dB even in the band 7500-10000Hz, which is lower than the inductor before improvement. In addition, the total decibel (total dB) indicating the total noise level of the inductor before improvement was 53.8 dB, whereas the total decibel of the inductor 10 of the first embodiment was 42.8 dB.

As can be seen from the comparison experiment, the inductor 10 of the present invention forms the silicon coating layer 12a on the magnetic core 12 and at the same time the silicon coating layer 12a is formed of the magnetic core 12 and the metal case ( 14 and 16 are in close contact with each other, thereby preventing vibration or noise generated during magnetic deformation of the magnetic core 12 from being transmitted to the metal cases 14 and 16, thereby allowing the magnetic core 12 and the cases 14 and 16 to be blocked. Minimize high-frequency noise due to friction between the, and the metal case (14, 16) acts as a sound insulation layer to block the leakage of noise to the outside, there is an advantage that can significantly reduce the noise compared to the inductor before improvement. .

5 and 6 are partial cross-sectional views and conceptual views of an inductor having a noise canceling and miniaturization structure according to a second embodiment of the present invention.

5 and 6, the inductor 20 of the second embodiment includes a magnetic core 22, a coil 26, and a plurality of coating layers 28a-28c as a toroidal type.

The inductor 20 has sound vibration energy different from each other on the outer surface of the magnetic core 22, and forms a plurality of coating layers 28a-28c made of a material having a higher rigidity toward the outer surface, in which case a separate case Is not assembled. Then, the coil 26 is wound to the outside of the outermost coating layer 28c to manufacture the inductor 20.

The plurality of coating layers 28a-28c are coated in a ring shape corresponding to the magnetic core 22 so as to completely surround the inside and the outside of the magnetic core 22. The coating layer 28 may be formed of at least two or three layers, and the thickness of the total coating layer 28 is preferably maintained at about 0.10 to 0.2 mm. The material of the plurality of coating layers 28a-28c should form a coating layer of flexible and rigid material toward the outside from the surface in contact with the magnetic core 22, which is the outermost coating layer 28c of the plurality of coating layers 28a-28c. This is because the coil 26 must be wound with strong tension. Therefore, the outermost coating layer 28c of the plurality of coating layers 28a-28c cannot be coated with a soft material, but should be coated only with a rigid material.

Here, the flexible material may be silicone, urethane, liquid epoxy (liquid) and the like, and the rigid material may be epoxy (powder or liquid). In this case, it is also possible to use other materials having the same physical properties as the above materials as the ductile and rigid materials.

FIG. 5 shows an example in which the coating layer 28 is composed of a flexible first coating layer 28a and a rigid third coating layer 28c.

6 shows an embodiment in which the coating layer 28 is formed of three layers, for example. The first to third coating layers 28a, 28b, and 28c are formed of a medium having different sound vibration energy. That is, the first coating layer 28a is a coating layer that directly contacts the magnetic core 22 and uses the most flexible material, and may be coated with, for example, a silicon coating layer. In addition, the third coating layer 28c should be coated with the most rigid material because the coil 26 should be wound on the outer surface, and may be coated with, for example, an epoxy coating layer. In addition, the second coating layer 28b is a material different from the remaining two first and third coating layers 28a and 28c, and is stronger than the first coating layer 28a and weaker than the third coating layer 28c. Material can be used. The noise emitted from the magnetic core 22 through the three first to third coating layers 28a, 28b, and 28c thus formed passes through three different media layers, absorbs the noise, interferes with, and disappears. The release can be minimized.

The coil 26 is wound along the ring-shaped coating layer 28, for example, by winding an insulated copper wire to have a desired inductance value.

In the inductor 20 according to the second embodiment, a plurality of coating layers 28 are formed on the outer circumference of the magnetic core 22 by omitting a case that can block noise generation and vibration transmission as a medium layer having different strengths. Even when the magnetic core 22, in particular, a low-cost Fe-based amorphous soft magnetic magnetic core having a large degree of magnetic deformation, is used, it is possible to fundamentally block the transmission of vibration generated from the magnetic core 22 to the case, thereby suppressing noise generation. Can be.

7 is a graph measuring noise according to a frequency change of the inductor 20 according to the present invention and the inductor before the improvement (before improvement) without forming a plurality of coating layers.

Referring to FIG. 7, the inductor 20 of the second embodiment was manufactured with two samples to measure the noise level.

Sample 1 is coated with silicon on the outer surface of the magnetic core 22 with a plurality of coating layers 28a of the inductor 20, followed by powder epoxy coating, and sample 2 is applied to the outer surface of the magnetic core 22. After coating with silicon, the liquid epoxy coating was applied to a 400W SMPS power supply to measure the noise level for each frequency.

The inductor before improvement refers to an inductor with a conventional simple insulation coating instead of forming a plurality of coating layers according to the invention.

First, before the improvement, the inductor rapidly increased the noise level after 5000Hz, and noise of 45dB or more was measured in the frequency band around 8000Hz. However, in case of sample 1, the maximum noise was measured below 40dB even in the frequency 8000Hz band, and in case of sample 2, below 35dB, the noise level was significantly reduced compared to the inductor before improvement.

In addition, the total decibel (total dB) indicating the total noise level of the inductor before improvement was 56.6 dB, while the total decibel of Sample 1 of the second embodiment was 52.4 dB, and the total decibel of Sample 2 was 50.3 dB.

As can be seen from the comparison experiment, the inductor 20 according to the second embodiment of the present invention forms a plurality of coating layers 28 on the outer surface of the magnetic core 22, thereby forming the magnetic core 22. As vibration or noise generated during magnetostriction is minimized from being transmitted to the metal case or emitted to the outside, noise can be significantly reduced compared to the inductor before improvement.

On the other hand, in order to determine the noise reduction effect according to the coating thickness in the second embodiment described above as a result of measuring the noise (Total Noise) while increasing the coating thickness to 0.3mm per surface, as shown in Figure 8, the silicon coating layer (Si-Coating Thickness ) As the thickness increases, the noise reduction effect is obtained, but after coating the final epoxy coating layer, the appearance of the magnetic core is not good and the silicon on the inside and the outside flows or swells, resulting in a thickness of 0.10mm to 0.2mm. It has been shown to be desirable to maintain.

In addition, in the second embodiment, when the thickness of the silicon coating layer is fixed at 0.15 mm per surface and the epoxy coating times are repeated, the level of total noise is more than four times as shown in FIG. 9. This increasing phenomenon occurred.

According to the first and second embodiments described above, the inductor using the plastic case and the flaw material as a comparative example has an outer diameter of 28.9 mm, an inner diameter of 12.7 mm, a height of 12.4 mm, and a DC resistance of 189 mΩ, The inductor 10 has an outer diameter of 27.5 mm, an inner diameter of 14.1 mm, a height of 12.0 mm, and a direct current resistance of 146 mPa. In addition, the inductor 20 according to the second embodiment has an outer diameter of 27.3 mm, an inner diameter of 14.3 mm, a height of 11.9 mm, and a DC resistance of 139 mΩ.

Here, the DC resistance is when the coil wire diameter is 0.8 phi and the number of coil winding turns is 95 turns. Since the DC resistance of the coil wound around the core acts as an important variable to determine the efficiency of the power supply (SMPS), the DC resistance should be as small as possible. This reduces the number of coil turns, which in turn reduces the cost of the final inductor.

Therefore, the inductors 10 and 20 according to the first and second embodiments of the present invention not only have excellent noise reduction structure, but also have a smaller structure than conventional inductors in terms of size, and have a small DC resistance. Can reduce the unit cost.

In the above embodiments, the magnetic core is described as an example of a ring-shaped core, but any shape of magnetic core may be used as long as the inductor is wound around the magnetic core.

The present invention forms a coating layer so that the magnetic core does not come into direct contact with the case, or omits the case to form a multi-coating layer. Applied to inductors that can be significantly reduced.

1 is a graph showing a noise generation state according to the increase of the magnetic field of the conventional inductor,

2 and 3 are an exploded perspective view and a partial cross-sectional view of the inductor having a noise canceling and miniaturization structure according to a first embodiment of the present invention,

4 is a graph measuring noise according to a frequency change with respect to the inductor before the coating layer is formed (before improvement) and the inductor according to the first embodiment of the present invention;

5 and 6 are a partial cross-sectional view and a conceptual diagram of an inductor having a noise canceling and miniaturization structure according to a second embodiment of the present invention;

7 is a graph measuring noise according to a frequency change with respect to the inductor before the formation of a plurality of coating layers (before improvement) and the inductor according to the second embodiment of the present invention;

8 is a graph showing the results of measuring the noise according to the coating thickness,

9 is a graph showing the results of measuring the noise according to the number of epoxy coating.

* Description of Signs for Main Parts in Drawings *

10,20: inductor 12,22: magnetic core

14, 16: Case 12a, 28, 28a-28c: Coating layer

18,26: coil

Claims (10)

case; A magnetic core housed in the case; A sound-absorbing coating layer formed on an outer surface of the magnetic core such that the magnetic core is not in contact with the case, thereby integrating the magnetic core and the case to block the vibration of the magnetic core from being transmitted to the case and simultaneously absorb sound; And Inductor comprising a; coil wound around the outer periphery of the case. A toroidal magnetic core; At least two coating layers coated on an outer circumference of the magnetic core and made of a material having a stronger strength toward the outside; And Inductor comprising a; coil wound around the outer periphery of the coating layer. The inductor of claim 1, wherein the coating layer is made of a silicon material. The inductor of claim 1, wherein the case is made of a metal material. The inductor according to claim 1 or 2, wherein the coating layer has a thickness of 0.10 mm to 0.2 mm.  According to claim 1, wherein the case is a ring-shaped lower case which is open at the top to cover the lower side and the side of the magnetic core, An inductor characterized in that the upper case of the magnetic core is formed of a ring-shaped upper case is opened to cover the side of the lower case. The inductor of claim 2, wherein the coating layer is formed by stacking a plurality of coating layers having different sound vibration energy. The inductor of claim 7, wherein an inner coating layer of the plurality of coating layers contacting the magnetic core is made of a soft material, and the outer coating layer exposed to the outside is made of a rigid material. The inductor of claim 8, wherein the flexible material is silicon or urethane, and the rigid material is made of powder or a liquid epoxy. A toroidal magnetic core; Inductor core, characterized in that the coating is formed on the outer periphery of the magnetic core made of a material having a stronger strength toward the outside.

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