KR101525157B1 - Transformer for restraining EMI - Google Patents

Abstract

A transformer for restraining EMI according to the present invention includes a coil winding part which is wound by a coil for trans to be stacked and is for inserting a ferrite core, a pair of both end flange parts which is formed at both ends of the coil winding part, a first counter magnetic flux coil which includes the coil for trans connected to one of the both end flange parts and has one end connected to the coil for trans, and a second counter magnetic flux coil which has an end combined with one of the both end flange parts which is not connected to the coil for trans. The other end of the first counter magnetic flux coil and the second counter magnetic flux coil is connected to each other and are wound with the same turn times around the coil winding part.

Description

Transformer for restraining EMI < RTI ID = 0.0 > (EMI)

The present invention relates to a transformer having an EMI suppressing function, and is capable of preventing a problem caused by coil insulation breakdown caused by a potential difference between a start winding of a coil of a transformer bobbin and a contact portion of each winding layer, And also to enhance the insulation performance between the coil windings of the transformer bobbin by having an insulating barrier rib.
Further, the present invention relates to a transformer function having an EMI suppression function due to noise generated in a transformer by canceling the noise-induced magnetic flux generated in the transformer.

Generally, the coil winding for the transformer is moved along the bobbin wall from the start pin of the winding, and the winding operation is started at the bottom surface of the bobbin. As the winding operation progresses, a coil winding layer is formed, and a coil winding layer is formed while reciprocating right and left between both walls of the bobbin, and a coil winding layer is laminated.

At this time, when the coil winding layer stacked from the lower coil winding layer of the bobbin winding axis reaches the last coil winding layer, the coils of the start winding and the coil layers of the coil winding layers are in contact with each other. When power is applied to the transformer, the potential difference at this contact point is the point where the contact potential difference of each winding layer becomes largest.

On the other hand, during the assembling work of the transformer, heat of the solder is transferred to the coil along the coil until the soldering portion of the final winding, so that the coil coating deteriorates. Such deterioration of the coating is caused by the heat transfer to the contact portion between the start winding and the final winding coil, which causes a deterioration phenomenon in the coil coating of the start winding and the coil layer contact portion of each winding layer.

The inductance value is measured without any abnormality in the characteristic inspection of the transformer measured by the LCR meter. However, if a high frequency voltage / current flows through the transformer, the circuit deterioration due to the insulation breakdown between the coils Which causes problems in reliability.

It is an object of the present invention to provide a structure of a transformer bobbin for coupling with a ferrite core, which is produced by a soldering operation for connecting a transformer coil and a wiring pin, By using a transformer bobbin having a bobbin structure for solving the problem of insulation breakdown between coils which is generated when a deterioration phenomenon due to soldering heat is transmitted to a covering of a contact coil of a final winding wound as a winding, (EMI) interference by causing a current to flow in the opposite direction to generate magnetic fluxes of opposite magnitudes having the same magnitude and thereby canceling the magnetic flux.

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According to an aspect of the present invention, there is provided a coil winding apparatus including a coil winding unit in which a transformer coil is wound and laminated, and a ferrite core is inserted and inserted in a longitudinal direction, and a pair of both- And a transformer coil which is connected to one of the pair of both-end flange portions, the transformer coil being connected to the transformer coil at one end thereof and the transformer coil of the pair of both- And the other end of the first inductor coil and the second inductor coil are connected to each other to turn on the coil winding part in the same direction, It is characterized by being coiled in water.
A pair of end flange portions inserted into both ends of the coil winding portion and having an insulating wall protruding from the outer circumferential surface thereof, at least one insulating protruding portion located between the insulating wall and the end flange portion, And a first coil guide groove formed in the both end flange portion, wherein the transformer coil is wound on the coil winding portion via the first coil guide groove.
An insulating flange portion provided at least one between the pair of both-end flange portions to divide the coil winding portion into a plurality of regions, and a second insulating coil portion provided in the insulating flange portion, the first flange portion being connected to the transformer coil and the first inductor coil A second support pin provided on the insulating flange portion and connected to the other end of the first inductor coil and the second inductor coil; and a second support pin formed on the insulation flange portion at a depth corresponding to the height of the coil winding portion. And a coil guide portion formed on one surface of the insulating flange portion so as to be sloped and communicating with the second coil guide groove, wherein the first inductor coil and the second inductor coil are connected to the coil guide portion and the second coil guide portion, And is wound on the coil winding portion via the second coil guide groove.

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By adopting a transformer having an EMI suppressing function, which is an embodiment of the present invention, it is possible to effectively remove noise that causes electromagnetic interference (EMI) interference generated when energizing the coil winding of the transobbler.

1 is an exploded perspective view showing a configuration of a transformer having an EMI suppression function according to an embodiment of the present invention.
2 is a diagram showing a configuration of a transformer having an EMI suppression function according to an embodiment of the present invention.
3 is a view showing a configuration of an insulation flange portion of a transformer having an EMI suppression function according to an embodiment of the present invention.
4 is a view showing a coupling state of a transformer having an EMI suppression function according to an embodiment of the present invention.
5 is a view showing a current flow direction of a transformer having an EMI suppression function according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It should be understood, however, that there is no intention to limit the scope of the present invention to the embodiment shown, and that other embodiments falling within the scope of the present invention may be easily devised by adding, Can be proposed.
1 and 2, a transformer having an EMI suppression function according to the present invention includes a coil winding portion 100, a pair of both-end flange portions 200, a first inductor coil 20 And a second inductor coil (30).
The coil winding part 100 is formed to have a predetermined length, and the transformer coil 10 is wound and laminated, and an end flange insertion hole 110 penetrating both ends along the longitudinal direction is formed to insert the ferrite core.
A pair of both end flange portions 200 are formed on the outer circumferential surfaces at both ends of the coil winding portion 100 and at least one or more leading wire connecting fins 220 are provided on the upper surface of each of the both end flange portions 200. Although the transformer coil 10 is connected to the one lead wire fin 220, the lead wire 220 is connected to one end of the transformer coil 10, but according to the present invention, One end connection pin 220 is provided on the upper left and right sides of the both-end flange portion 200 so that the position of the fin 220 can be selected.
5, the transformer coil 10 is connected to the front-end connecting pin 220 provided in any one of the pair of both-end flange portions 200, and the other end of the transformer coil 10 is connected to the front- One end of the first inductor coil 20 is connected.
One end of the second inductor coil 30 is connected to the other end flange portion 200 side where the transformer coil 10 is not connected among the pair of both end flange portions 200, The other end of the coil 20 and the second inductor coil 30 are connected to each other and wound on the coil winding part 100 at the same number of turns.
In an embodiment of the present invention, the coil winding unit 100 is divided into a plurality of regions by using the insulation flange unit 300 described later, and the first inductor coil 20 and the second inductor coil 30 ) Were repeatedly arranged in the same structure.
When this structure is applied, current flows through the transformer coil 10 when the coil is energized through the lead wire fin 220, and the current flows through the transformer coil 10, the first inductor coil 20 and the second inductor coil 20, (30) in this order. At this time, the directions of the currents flowing through the first inductor coil 20 and the second inductor coil 30 are opposite to each other, so that magnetic fluxes in different directions are generated and EMI .
A pair of end flange portions 400 are inserted through the end flange insertion holes 110 at both ends of the coil winding portion 100 and an end flange portion 400 is inserted into the outer peripheral surface of the end flange portion 400, An insulating wall 420 is formed to prevent the inserting hole 42 from being completely inserted into the hole 110.
A core through hole 410 into which the ferrite core is inserted is formed at the center of the end flange portion 400.
One or more insulating protrusions 240 are disposed between the insulating wall 420 and the both flange portions 200 and the insulating protrusions 240 are formed in a direction in which the end flange portion 400 is inserted As shown in FIG.
As shown in FIGS. 2 and 4, when inserting the end flange portion 400, the insulating wall 420 and the insulating protrusion 240 are brought into contact with each other to form an insulating region 500, which is a predetermined empty space. It is possible to prevent contact with the transformer coil 10 at the time of insertion.
A first coil guide groove 210 is formed on an upper surface of the flange portion 200 at a depth corresponding to the height of the coil winding portion 100. The transformer coil 10 has a first end And then wound on the coil winding part 100 via the first coil guide groove 210. [
At this time, in order to prevent contact between the one end side of the transformer coil 10 and the stacked portion, the first coil guide groove 210 is bent after contacting with the outer circumferential surface of the insulation protrusion 240, do.
By forming the first coil guide groove 210 having a depth corresponding to the height of the coil winding part 100 and then passing the transformer coil 10 through the coil winding part 100, The portion contacting between the portion extending from the fin 220 to the coil winding portion 100 is minimized.
On the other hand, at least one insulating flange portion 300 is provided on the outer circumferential surface of the coil winding portion 100 located between the pair of both-end flange portions 200 to divide the coil winding portion 100 into a plurality of regions, The first support pin 330 and the second support pin 340 are disposed on the upper surface of the flange portion 300 and spaced apart from each other.
The other end of the transformer coil 10 and one end of the first inductor coil 20 are connected to the first support pin 330 and the first inductor coil 20 and the second inductor coil 20 are connected to the second support pin 340. [ And the other end of the inductor coil 30 is connected.
Through this structure, a current flowing into the transformer coil 10 is connected to the first inductor coil 20 at the first support pin 330 and flows in one direction continuously along the outer circumferential surface of the coil winding part 100 The second support pin 340 and the third support pin 350 located in the next insulation flange 300 after the second inductor coil 30 flows continuously in the direction opposite to the first along the second inductor coil 30, And is energized by the rear-end connection pin 230 located in the support portion 200.
That is, as the directions of current flow are opposite to each other, magnetic fluxes in different directions are generated and noise that causes EMI interference is suppressed.
A second coil guide groove 310 is formed on the upper surface of the insulating flange 300 at a depth corresponding to the height of the coil winding part 100 and a second coil guide groove 310 The coil guide portion 320 is formed to be inclined.
At this time, the first inductor coil 20 and the second inductor coil 30 are wound on the coil winding part 100 via the coil guide part 320 and the second coil guide groove 310, The portion wound and laminated by applying the guide portion 320 and the second coil guide groove 310 and the portion extending from the second support pin 340 to the coil winding portion 100 come in contact with each other with a minimum area .

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10: coil for transformer 20: first inductor coil
30: second inductor coil 100: coil winding part
110: end flange insertion hole 200:
210: first coil guide groove 220:
230: rear end connection pin 240: insulation protrusion
300: Insulation flange portion 310: Second coil guide groove
320: coil guide part 330: first support pin
340: second support pin 350: third support pin
400: end flange portion 410: core through hole
420: insulating wall 500: insulating region

Claims (4)

A coil winding portion in which a transformer coil is wound and laminated, and a ferrite core is inserted and inserted in a longitudinal direction;
A pair of both end flange portions formed at both ends of the coil winding portion;
A first inductor coil having the transformer coil connected to one of the pair of both-end flange portions and having one end connected to the transformer coil; And
And a second inductor coil, one end of which is connected to the other end flange side of the pair of the both-end flanges to which the transformer coil is not connected,
And the other ends of the first inductor coil and the second inductor coil are connected to each other to be wound in the same number of turns on the coil winding unit.
The method according to claim 1,
A pair of end flange portions inserted into both end portions of the coil winding portion,
At least one insulating protruding portion located between the insulating wall and the end flange portion,
And a first coil guide groove formed at the both-end flange portion at a depth corresponding to the height of the coil winding portion,
And the transformer coil is wound on the coil winding portion via the first coil guide groove.
3. The method according to claim 1 or 2,
At least one insulating flange portion provided between the pair of both-end flange portions to divide the coil winding portion into a plurality of regions,
A first support pin provided at the insulating flange portion and connected to the transformer coil and the first inductor coil;
A second support pin provided at the insulating flange portion and connected to the other end of the first inductor coil and the second inductor coil;
A second coil guide groove formed in the insulating flange portion at a depth corresponding to the height of the coil winding portion,
And a coil guide portion formed on one surface of the insulating flange portion so as to be inclined to communicate with the second coil guide groove,
Wherein the first inductor coil and the second inductor coil are wound on the coil winding part via the coil guide part and the second coil guide groove. delete

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