Inductor coil and electromagnetic component

Abstract

The present invention provides an inductance coil comprising a magnetic core and a coil, wherein the coil is formed by winding a flat wire, and the flat surface of the wire is perpendicular to the axis around which the coil is wound. The coil is wrapped with an insulating adhesive tape and the tape is wound on the wire around an axis which is substantially in line with the direction along which the wire forming the coil extends, so as to form an isolation layer on the surface of the coil. Additionally, the present invention provides an electromagnetic device including the above inductance coil.

Claims

1. An inductance device comprising: a magnetic core that extends along an axis; a coil wound around the magnetic core, wherein the coil comprises a wire comprising a flat surface and a consistent size; and the flat surface of the wire is perpendicular to the axis such that the coil comprises an exterior surface that comprises a top portion perpendicular to the axis, a bottom portion perpendicular to the axis, and sides that extend parallel to the axis from the bottom portion to the top portion; and an isolation surface on the exterior surface of the coil, wherein the isolation surface comprises an adhesive tape that extends from the bottom portion of the coil to the top portion of the coil substantially along a direction parallel to the axis, and there are no gaps between the isolation surface and the exterior of the coil.

2. The inductance device of claim 1, wherein the isolation surface prevents dust and water from reaching the coil such that the coil is waterproof and dustproof.

3. The inductance device of claim 1, wherein the isolation surface comprises a waterproof paint.

4. The inductance device of claim 1, wherein the coil further comprises a leading out terminal, and the wire and the leading out terminal comprise the flat surface and consistent size.

5. The inductance device of claim 4, wherein the leading out terminal of the coil is sleeved with a heat-shrinkable tube.

6. The inductance device of claim 4, wherein the leading out terminal of the coil is coated with a sealing gum.

7. The inductance device of claim 1, wherein the magnetic core is an E-I shaped magnetic core, a central column of the E-I shaped magnetic core extends along the axis, and the coil surrounds the central column.

8. The inductance device of claim 1, wherein the magnetic core has an air gap, and an insulator in the air gap.

9. The inductance device of claim 1, wherein the inductance device is a reactor, an inductor, a choke coil or a transformer coil.

10. The inductance device of claim 1, wherein the coil is self-supporting and the inductance device does not include a separate holder to support the coil.

11. An electromagnetic device comprising: an inductance device, the inductance device comprising: a magnetic core that extends along an axis; a coil wound around the magnetic core, wherein the coil comprises a wire comprising a flat surface and a consistent size; and the flat surface of the wire is perpendicular to the axis such that the coil comprises an exterior surface that comprises a top portion perpendicular to the axis, a bottom portion perpendicular to the axis, and sides that extend parallel to the axis from the bottom portion to the top portion; and an isolation surface on an exterior surface of the coil, wherein the isolation surface comprises an adhesive tape that extends from the bottom portion of the coil to the top portion of the coil substantially along a direction parallel to the axis, and there are no gaps between the isolation surface and the exterior of the coil.

12. The electromagnetic device of claim 11, wherein the isolation surface prevents dust and water from reaching the coil such that the coil is waterproof and dustproof.

13. The electromagnetic device of claim 11, wherein the isolation surface comprises a waterproof paint.

14. The electromagnetic device of claim 11, wherein the coil further comprises a leading out terminal, and the wire and the leading out terminal comprise the flat surface and consistent size.

15. The electromagnetic device of claim 14, wherein the leading out terminal of the coil is sleeved with a heat-shrinkable tube.

16. The electromagnetic device of claim 14, wherein the leading out terminal of the coil is coated with a sealing gum.

17. The electromagnetic device of claim 11, wherein the isolation surface prevents dust and water from reaching the coil such that the coil is waterproof and dustproof, and the electromagnetic device is not contained in a housing or sealed by an additional sealing device.

18. A component for a reactor, the component comprising: a coil wound around a space configured to receive a magnetic core, the space extending along an axis, wherein the coil comprises a wire comprising a flat surface and a consistent size; the coil is wound with the flat surface of the wire perpendicular to the axis; and the wound coil comprises an exterior surface that comprises a top portion perpendicular to the axis, a bottom portion perpendicular to the axis, and sides that extend parallel to the axis from the bottom portion to the top portion; and an adhesive tape wrapped around the exterior surface of the coil, wherein the adhesive tape that extends from the bottom portion of the coil to the top portion of the coil, and there are no gaps between the adhesive tape and the exterior of the coil.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Below, embodiments of the present invention are further described with reference to the attached drawings, wherein:

(2) FIG. 1 is a schematic view of the E-I shaped magnetic core before installing the coil;

(3) FIG. 2 is a front view of the combination of the E shaped magnetic core and I shaped magnetic core;

(4) FIG. 3 is a schematic view of a vertical wrapping coil;

(5) FIG. 4 shows a schematic view of a coil wrapped with an insulating adhesive tape;

(6) FIG. 5 is a cross-sectional view of the combination of the coil and the E-I shaped magnetic core shown in FIG. 1;

(7) FIG. 6 is a cross-sectional view of the E-I shaped magnetic core including an insulating gasket.

DETAILED DESCRIPTION OF THE INVENTION

(8) In order to make the objects, technical solutions and advantages of the present invention clearer, the present invention is further illustrated in detail by the specific embodiments below. It should be understood that the specific embodiments described herein are merely used to explain the present invention and are not intended to limit the present invention.

Embodiment 1

(9) The present embodiment provides a reactor comprising a magnetic core and a coil.

(10) In this embodiment, the magnetic core of the reactor is an E-I shaped magnetic core. FIG. 1 shows a schematic view of the E-I shaped magnetic core before installing the coil. The E-I shaped magnetic core comprises an E shaped magnetic core 2 and an I shaped (i.e. elongate) magnetic core 1. The E shaped magnetic core 2 has a central column 21 and two side columns 22, wherein the height of the central column 21 is slightly lower than that of the two side columns 22. FIG. 2 shows a front view of the combination of the E shaped magnetic core 2 and I shaped magnetic core 1. The I shaped magnetic core 1 closely attaches to the two side columns 22 of the E shaped magnetic core 2 after assembling the magnetic core. Owing to the height difference h between the central column 21 and the two side columns 22, an air gap G with a height h is formed between the central column 21 and the I shaped magnetic core 1. The air gap can help the inductor store energy. If there were no air gap, the magnetic conductivity of the inductor would be large, and when a certain amount of current flows through the inductor, the inductor would be saturated and thus not be able to inhibit rapid increase of the current, i.e. the inductor would be out of action.

(11) The coil of the reactor provided in the present embodiment is a vertical wrapping coil, the structure of which is shown in FIG. 3. The coil 3 is formed by winding a flat wire, and the flat surface of the wire is perpendicular to the axis around which the coil is wound. In order to ensure its waterproof and dustproof performance, the coil is wrapped with an insulating adhesive tape. FIG. 4 shows a schematic view of a coil wrapped with the insulating adhesive tape 4, wherein the dotted arrow shows the winding direction of the insulating adhesive tape 4. As shown in FIG. 4, the winding direction of the insulating adhesive tape 4 is substantially perpendicular to the winding direction of the coil 3. In other words, the insulating adhesive tape 4 is wound on the wire around an axis which is substantially in line with the direction along which the wire forming the coil 3 extends. In this way, the insulating adhesive tape 4 tightly attaches to the surface of the coil, and an isolation layer for insulating the coil 3 from the surroundings is formed on the surface of the coil 3 so as to make the coil 3 waterproof and dustproof.

(12) FIG. 5 is a cross-sectional view of the combination of the coil 3 and the E-I shaped magnetic core shown in FIG. 1, wherein for clarity, the insulating adhesive tape 4 is omitted. As shown in FIG. 5, the coil 3 is located in a space enclosed by the I shaped magnetic core 1, the central column 21 and the side column 22, so as to surround the central column 21 of the E shaped magnetic core 2.

(13) The reactor provided in the present embodiment uses the coil formed by vertically winding a flat wire. Since the flat wire is wider and has better self-supporting, it is not necessary to provide a coil holder when winding the flat wire and thus a coil without a coil holder can be formed. The shape of the coil is regular, hence, the insulating adhesive tape can be tightly attached to the coil without leaving gaps, such that the waterproof and dustproof performance of the insulating adhesive tape is greatly improved. Accordingly, there is no need to add additional waterproof and dustproof parts, for example housing and sealing resin, which will increase the volume of the inductance coil. Therefore, the volume of the reactor of the present invention is greatly reduced.

(14) In addition, vertically winding is an efficient way for winding. For a certain air gap, a higher inductance value is available in the limited space. For a certain inductive value, the volume occupied by the reactor achieved through vertically winding is smaller than that occupied by other reactors achieved through other winding ways. Therefore, the volume of the reactor is further reduced.

(15) Additionally, in the conventional coil winding way, it is necessary to wind multiple layers of copper wires so as to meet the requirements. However, air gaps with lower thermal conductivity between each layer of the coils are unavoidable, which may cause a high temperature difference between the inside and outside of the coils, even as high as 40° C. Due to this, the internal temperature of the coils may be too high and thus damage the enamel-cover of copper wire and cause interturn short circuit, resulting in the burned inductor. The vertical winding coil of the present embodiment uses a flat wire, the surface of which is perpendicular to the axis around which the coil is wound. Therefore, one layer of the coil can meet requirements. It prevents too high internal temperature and reduces the temperature difference between the inside and outside of the coils.

Embodiment 2

(16) As described in the embodiment 1, an air gap G with a height h is formed between the central column 21 and the I shaped magnetic core 1. However, leakage flux will cause the central column 21 and the I shaped magnetic core 1 provided on both sides of the air gap G to vibrate and collide, resulting in a noise. The present embodiment provides a reactor which can avoid this noise.

(17) FIG. 6 shows a reactor of the present embodiment, the structure of which is basically the same as that of the reactor provided in the embodiment 1. The structures are different in that an insulating gasket 5 is provided between the central column 21 and the I shaped magnetic core 1. The insulating gasket 5 is positioned against to the central column 21 and the I shaped magnetic core 1, and can not only provide the functionality of the air gap, but also avoid the vibration and collision of the central column 21 and the I shaped magnetic core 1, thereby avoiding a noise. The insulating gasket 5 may be made of, for example insulating material such as silicone, and preferably a flexible insulating material.

(18) According to other embodiments of the present invention, insulation materials such as epoxy resin can also be filled in the gap between the E-I shaped magnetic core and the coil 3 so as to prevent them from colliding with each other, and prevent turns of the coil colliding with each other due to the effect of electromagnetic force, which may further reduce noises.

(19) According to other embodiments of the present invention, other waterproof and dustproof measures can also be provided to the above reactor so as to further improve its waterproof and dustproof performance. For example, after assembling the coil 3 and the E-I shaped magnetic core, the assembly may be immersed in the Varnish, baked and cooled, and dipped into waterproof paint. It can also improve waterproof and dustproof performance without increasing the volume of the reactor. In addition, a leading out terminal of the coil 3 may be coated with a sealing gum or sleeved with a heat-shrinkable tube to prevent the tape near the leading out terminal not being completely sealed. Using either one of the above waterproof and dustproof measures or any combination of them, the reactor can be completely sealed as a whole such that it is impossible for water to enter any location of the reactor and a high level of waterproof can be achieved.

(20) In the above embodiments, the E-I shaped magnetic core as an example of the reactor according to the present invention has been described. Those skilled in the art will appreciate that the reactor provided in the present invention is not limited to the E-I shaped magnetic core, and other types of magnetic cores may be used based on actual needs.

(21) In essence, the reactor provided in the above embodiments is an inductance coil. The reactor of the above embodiments can also be used in other occasions applying inductance coil, such as inductors, transformers, choke coils, etc. Therefore, the present invention provides an inductance coil, which can be used in any occasion applying inductance coil, for example used as reactors, inductors, chock coils, transformer coils, etc.

(22) Finally, it should be noted that the above embodiments are merely provided for illustrating the technical solutions of the present invention and not for limiting. Although the present invention has been described in detail with reference to the embodiments, those skilled in the art will appreciate that the technical solutions of the invention can be modified or replaced by equivalents, without departing from the spirit and scope of the invention, which are covered by the protection scope of the claims of the invention.