KR101201291B1 - Transformer with backward double winding coil transformer for protceting electro-static shield, surge and eletromagnetic noise - Google Patents

Abstract

PURPOSE: A reverse direction double wire combination transformer is provided to extend life cycle of a load device by controlling the generation of leakage current and electrostatic induction. CONSTITUTION: A primary wire(110) is successively wound from the surface of a core(100) for a transformer to an external direction. The primary wire comprises a primary internal wire(111) and a primary external wire(112). The primary internal wire is wound in the opposite direction with the primary external direction. A secondary wire(120) is successively wound from the surface of the core for the transformer to the external direction. The secondary wire comprises a secondary internal wire(121) and a secondary external wire(122). The secondary internal wire is wound in the opposite direction with the secondary external wire. The primary internal wire and the secondary internal wire are parallely connected to the primary external wire and the secondary external wire, respectively.

Description

TRANSFORMING WITH BACKWARD DOUBLE WINDING COIL TRANSFORMER FOR PROTCETING ELECTRO-STATIC SHIELD, SURGE AND ELETROMAGNETIC NOISE

One embodiment of the present invention relates to a reverse double winding coupled transformer for electrostatic shielding, surge and noise protection.

Lightning strikes occur when the atmosphere is charged by rapid air current fluctuations and temperature changes, and then discharges between clouds with low potential or to the ground. Specifically, the lightning discharge that occurs between the negative and positive charges accumulated and accumulated inside the cloud as cumulonimbus develops is called lightning. Among these lightnings, the discharge phenomenon in the cloud is called cloud discharge, and it is induced to the negative charge and the ground at the bottom of the cloud. The discharge generated between the positive charges is called lightning strike.

Due to the impact of heat, vibration and magnetic field due to such lightning, the transformer may be damaged.

1A to 1C are diagrams for explaining the principle of a general transformer and the effects of lightning.

Referring to FIG. 1, a general transformer 1 winds a primary winding 2 and a secondary winding 3 around a stratified core, and flows through the primary winding 2 when a current flows through the primary winding 2. The magnetic flux is generated in the primary core by the electric current, and the magnetic flux links the secondary winding 3 through the core. At this time, in the core inside the secondary winding 3, magnetic flux is generated in a direction that prevents the change of the magnetic flux by the primary winding 2, and the electromotive force is generated in the secondary winding 3 by the magnetic flux. Current will flow.

At this time, the generated current disappears after a while, which explains that the current is induced only when there is a change in the magnitude of the magnetic field by the primary winding (2), in order to generate a continuous current in the secondary winding (3) In order to change the magnetic field, an alternating current must be supplied to the primary winding (2).

On the other hand, the secondary voltage relative to the primary voltage is proportional to the number of turns. That is, the relationship of (V1 / V2) = (n1 / n2) is established, and this is called the transformer ratio.

These transformers are divided into single-phase and three-phase transformers according to the constant of the power source, and there are inner type, outer iron type, and iron core type depending on the structure of the core core. In addition, there is a single winding transformer that uses the primary and secondary jointly with one winding, which is used as a home voltage regulator because the efficiency is high when the voltage ratio is stepped up and down within a range of less than 2.

As described above, in the case of a general conventional transformer, the primary winding 2 and the secondary winding 3 are each a single coil or a second layer inside a core 1 composed of a steel sheet of silicon steel sheet. A double winding wound by overlapping with (2a, 2b, 3a, 3b) is used, and voltage induced in which a magnetic field is induced in the secondary winding 3 in accordance with the change of the current flowing in the primary winding 2 is used.

Such a conventional transformer has been used by winding each winding in the same direction and connecting each coil in series or in parallel when using a double winding as shown in FIG. 1C.

However, such a conventional transformer generates an electrostatic induction by an abnormal voltage such as a surge between the primary winding 2 and the secondary winding 3, and furthermore, the primary winding 2 or the secondary winding 3 and There was a problem that leakage current may be generated between the cores 1. In addition, the conventional transformer may be damaged due to the electrostatic induction and leakage current, thereby causing a damage of the load device (not shown) connected to the secondary winding (3) side.

One embodiment of the present invention is to prevent the electrostatic induction between the primary winding and the secondary winding and to prevent the occurrence of leakage current between the primary winding or the secondary winding and the core for electrostatic shielding, surge and noise prevention Provide a reverse double winding coupling transformer.

In addition, an embodiment of the present invention provides a reverse double winding coupled transformer for electrostatic shielding, surge and noise prevention that can extend the product life of the transformer and the load device, and also improve the product reliability.

In addition, an embodiment of the present invention provides a reverse double winding coupled transformer for electrostatic shielding, surge and noise protection that can effectively block the noise that can be generated between the coils.

The reverse double winding coupling transformer for electrostatic shielding, surge and noise prevention according to an embodiment of the present invention is formed by double winding on the input side of the transformer core and the transformer core connected to an external power source. A reverse double winding coupling transformer comprising a secondary winding and a secondary winding formed by a double winding on an output end side of a transformer core connected to a load side, wherein the primary winding is outward from a surface of the transformer core. Windings sequentially, each including a primary inner winding and a primary outer winding wound in opposite directions, wherein the secondary windings are sequentially wound outward from the surface of the core for the transformer, respectively, in opposite directions. And a secondary inner winding and a secondary outer winding, wherein the primary inner winding and the secondary inner winding are respectively connected to the primary outer winding and the secondary outer winding. Characterized in that the connecting column.

In addition, the reverse double winding coupling transformer for electrostatic shielding, surge and noise prevention according to another embodiment of the present invention is formed by double winding on the input side of the transformer core and the transformer core connected to the external power supply side A reverse winding coupled transformer comprising a secondary winding formed by a primary winding and a secondary winding formed on the output end side of a transformer core connected to a load side, wherein the primary winding is formed from a surface of the transformer core. Winding sequentially in the outward direction, each including a primary inner winding and a primary outer winding wound in opposite directions, wherein the secondary winding is sequentially wound outward from the outer periphery of the primary winding, respectively A secondary inner winding and a secondary outer winding wound in a direction, wherein the primary inner winding and the secondary inner winding are respectively the primary outer winding and the secondary outer winding. It is connected in parallel characterized.

Winding start points of the primary and secondary internal windings are electrically connected to the winding end points of the primary and secondary external windings and are disposed on the N (neutral) side of a power source. The winding end point of the secondary internal winding is electrically connected to the winding start point of the primary external winding and the secondary external winding, and is disposed on a hot line side of the power source.

A noise blocking unit is formed on the magnetic path region of the transformer core, wherein the noise blocking unit includes at least one EMI coil consisting of a coil and a capacitor, or at least one resonance circuit in which a coil and a capacitor are combined. Characterized in that it may be a (resonance circuit).

In the reverse double winding coupling transformer for electrostatic shielding, surge, and noise protection according to an embodiment of the present invention, the winding direction of the double winding coils forming the primary winding and the secondary winding is reversely formed and then connected in parallel. Since the equipotential is formed between the outer coils of the primary winding and the secondary winding, and between the inner coil and the core of the primary winding and the secondary winding, the primary winding and the secondary winding The occurrence of electrostatic induction and leakage current between the primary winding or the secondary winding and the core can be suppressed.

In addition, since the embodiment of the present invention suppresses electrostatic induction and leakage current, it is possible to extend the product life of the transformer and the load device and to improve the product reliability.

In addition, since an embodiment of the present invention is provided with an EMI coil or LC resonant circuit in the core of the core between the primary winding and the secondary winding, it is possible to effectively block the noise that may be generated between the coils. .

1A to 1C are diagrams for explaining the principle of a general transformer and the effect of lightning.
2 is a diagram illustrating a reverse double winding coupling transformer for electrostatic shielding, surge, and noise protection according to an exemplary embodiment of the present invention.
3A is a cross-sectional view illustrating a reverse double winding coupling transformer in a state in which AA ′ in FIG. 2 is cut.
3B is a diagram illustrating a winding direction of the primary winding of FIG. 3A.
4A and 4B are diagrams for describing an effect of suppressing electrostatic shielding and leakage current generation in the reverse double winding coupling transformer of FIG. 2.
FIG. 5 is a diagram schematically illustrating a structure in which a noise blocking unit is installed in a reverse double winding coupling transformer according to an exemplary embodiment of the present invention.
FIG. 6 is a diagram illustrating a reverse double winding coupling transformer for electrostatic shielding, surge, and noise protection according to another exemplary embodiment of the present invention.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in which those skilled in the art can readily implement the present invention.

On the other hand, to summarize the terms used below to describe the reverse double winding coupled transformer for electrostatic shielding, surge and noise protection according to an embodiment of the present invention, firstly, the primary winding is connected to the commercial power source to the transformer Winding, the secondary winding means a winding that is connected to the load side of the transformer. In addition, an inner winding means a winding wound on the inner side when the double winding divided into two in the primary winding or the secondary winding, and the outer winding means a winding wound on the outer side. And, 1S terminal is the terminal in the direction of the winding start point of the primary winding, 1E terminal is the terminal in the direction of the winding end point of the primary winding, 2S terminal is the terminal in the direction of the winding start point of the secondary winding, and 2E terminal is the secondary This is the terminal in the winding end point direction of the winding. In addition, 1-1S terminal is a terminal in the direction of the winding start point of the inner winding of the primary winding, 1-1E terminal is a terminal in the direction of the winding end point of the inner winding of the primary winding, and 1-2S terminal is an outer side of the primary winding. Terminal in the direction of the winding start point of the winding, and terminal 1-2E is the terminal in the direction of the winding end point of the external winding of the primary winding. And, the 2-1S terminal is a terminal in the winding start point direction of the inner winding of the secondary winding, the 2-1E terminal is a terminal in the winding end point direction of the inner winding of the secondary winding, and the 2-2S terminal is a terminal of the secondary winding. Terminal in the direction of the winding start point of the outer winding, and 2-2E terminal is the terminal in the direction of the winding end point of the outer winding of the secondary winding. The above terms may be applied to all embodiments of the present invention in common.

FIG. 2 is a diagram illustrating a reverse double winding coupling transformer for electrostatic shielding, surge, and noise protection according to an embodiment of the present invention, and FIG. 3A is a reverse double winding in a state of cutting AA ′ of FIG. 2. 3B is a cross-sectional view illustrating a coupling transformer, and FIG. 3B is a diagram illustrating a winding direction of the primary winding of FIG. 3A, and FIGS. 4A and 4B illustrate an effect of suppressing electrostatic shielding and leakage current generation in the reverse double winding coupling transformer of FIG. 2. 5 is a view for schematically explaining a structure in which a noise blocking unit is installed in a reverse double winding coupling transformer according to an exemplary embodiment of the present invention.

2 to 5, the reverse double winding coupling transformer 10 for electrostatic shielding, surge and noise prevention according to an embodiment of the present invention, the transformer core 100, the primary winding 110 And a secondary winding 120. Here, the reverse double winding coupling transformer 10 according to an embodiment of the present invention, the primary winding 110 and the secondary winding 120 is wound in the opposite direction to each other with a double winding structure It is a transformer.

The transformer core 100 may be a magnetic powder core, that is, a core made of a metal alloy in the form of magnetic powder or a core including ferrite. The core 100 is a metal material having a high permeability, and means a metal provided inside the winding in which the wire is wound to help form magnetic flux density or magnetic field. Here, the core made of a metal in the form of magnetic powder is a high permeability alloy having a composition of aluminum (Al; about 5%), silicon (Si; about 10%), and iron (Fe; about 85%). Including cores made of alloys well known under the trade name Magnetics (kool-μ). The magnetic powder core has a low permeability compared to the ferrite core to be described later has the advantage of excellent current overlap characteristics. In addition, the ferrite core is an insulator including a magnetic material sintered by mixing iron oxide with zinc oxide, manganese oxide, nickel oxide, and the like, and has a high permeability and excellent loss characteristics. In addition, it is easy to make a variety of shapes when sintering is widely used as a magnetic core.

On the other hand, when the coil is wound around the coil core 100 as described above and a current is applied, a magnetic field is induced by the electric field, and magnetic flux is generated in the core. It is desirable to maintain a constant relationship with the current while the magnetic flux density exhibiting magnetism increases in proportion to the applied current and the core reaches a saturation state in which the magnet is lost. The correlation of the magnetic flux density with the current is called the current overlapping characteristic, and when the magnetic flux density increases too rapidly with the increase of the current to reach a saturation state, it is determined that the current overlapping characteristic is not good. In other words, if the core is easily saturated even with a small current change, it is difficult to use it as an electronic device. Therefore, it is preferable that the core has a good current overlapping property because the magnetic flux density is appropriately increased according to the change of the current.

The permeability (μ) is an amount representing the magnetic properties of a specific material and is also referred to as a magnetic induction capacity or magnetic permeability. The ratio of the magnetic flux flux density that occurs when a material is magnetized under the influence of a magnetic field and the magnetic field strength in a vacuum. In ordinary materials, that is, paramagnetic or diamagnetic materials, the magnetic permeability is close to 1, and the value is determined according to the type of the material. The value changes depending on the magnetic history of the magnetic body or the strength of the magnetic field. The higher the permeability, the more magnetic and easily affected by the magnetic field.

The primary winding 110 is formed by a double winding on the input end side of the transformer core 100 connected to an external power source (not shown) side. In addition, the primary winding 110 includes a primary inner winding 111 and a primary outer winding 112 sequentially wound outward from the surface of the transformer core 100. Here, the primary inner winding 111 and the primary outer winding 112 are respectively wound in opposite directions.

The secondary winding 120 has a configuration similar to that of the primary winding 110, and is positioned to face the primary winding 110 so as to be connected to the load (not shown) side of the transformer core 100. It is formed by double winding on the output side. In addition, the secondary winding 120 includes a secondary inner winding 121 and a secondary outer winding 122 sequentially wound outward from the surface of the transformer core 100. Here, the secondary inner winding 121 and the secondary outer winding 122 are wound in opposite directions, respectively.

The primary inner winding 111 and the secondary inner winding 121 of the primary winding 110 and the secondary winding 120 as described above and the primary outer winding 112 and the secondary outer winding 122, respectively It is connected in parallel. More specifically, the winding start point 1S of the primary inner winding 111 is electrically connected to the winding end point 2E of the secondary outer winding 122 and disposed on the N (neutral) side of the power source. In addition, the winding end point 1E of the primary inner winding 111 is electrically connected to the winding starting point 2S of the secondary outer winding 122 and disposed on the H (hot line) side of the power source. do. That is, the N pole of the power supply side is connected to the terminal connecting 1S and 2E of FIG. 3A, and the H (that is, hot line) side of the power supply is connected to the terminal connecting 1E and 2S. At this time, as shown in Figure 4a and 4b, the outer winding of the primary winding 110 and the secondary winding 120 is an equipotential N pole so that the electrostatic induction (C1) between each other does not occur, the primary winding Since the inside of the secondary winding 120 and the secondary winding 120 and the transformer core 100 are the same equipotential N-ground, no leakage current (ie, C3a and C3b are open) is generated.

In general, most transformers induce electrostatic induction by the coil and the core and the capacitance between the coil and the coil. The electrostatic induction generated by the electrostatic induction thus causes the transmission of surges, electromagnetic waves and noise, resulting in damage to the transformer. This will damage the load. Conventionally, in order to solve this problem, an electrostatic shielding plate is installed between the primary winding and the secondary winding. However, in this case, an accident may occur in the primary winding due to the rise of the ground potential of the secondary winding. In the present invention, the primary inner winding 111 and the secondary inner winding 121 of the primary winding 110 and the secondary winding 120, the primary outer winding 112 and the secondary outer winding 122, respectively By connecting in parallel to generate an electrostatic shielding effect, the above problem can be solved simply. That is, in the present invention, by connecting the primary inner winding 111 and the secondary inner winding 121 and the primary outer winding 112 and the secondary outer winding 122 in parallel, respectively, the electric field of the core and the coil is grounded. By maintaining the side and the equipotential state, the noise of the constant mode (COMMON MODE) is canceled by the N-side electric field outside the coil. Through this, the electric field of the applied power source can be naturally dissipated by the stepwise electric field between the layers of the coils inside the transformer, and the earth potential can be always maintained for the core part and the outer edge of the coil most vulnerable to transformer insulation.

At least one noise blocking unit 130 is formed on the magnetic path region of the transformer core as shown in FIG. 5. Here, the noise blocking unit 130 is at least one coil for Electro Magnetic Interference (Coil for Electro Magnetic Interference) consisting of the coil 132 and the condenser 131 or at least one resonance circuit in which the coil 132 and the condenser 131 is combined It may be a resonance circuit. The noise blocking unit 130 serves to block noise by acting as a filter of a specific frequency with respect to the noise generated on the magnetic field of the transformer core 100. The noise blocking unit 130 has an EMI coil or a coil 132 formed in the transformer core 100 between the primary winding 110 and the secondary winding 120 (that is, connected in series to the transformer core). The capacitor 131 is formed in parallel to the EMI coil or the coil 132.

Although not shown, in order to maximize the electrostatic shielding effect, inside and outside of the primary winding 110 and the secondary winding 120 are respectively provided with an inner shield shielding layer and an outer shield shielding layer connected to ground. Can be formed. Here, since the inner shield shielding layer and the outer shield shielding layer are formed of a copper plate or a conductor, an electrostatic shielding effect is generated, and further, an induction electromagnetic field generated in the winding can be easily shielded. More specifically, the inner shield shielding layer attenuates the capacitance generated in the gap between the inner side of the primary winding 110 and the secondary winding 120 and the transformer core 100. In addition, the outer shield shielding layer attenuates the capacitance generated outside the primary winding 110 and the secondary winding 120. In addition, the outer shield shielding layer shields lightning and noise flowing from the outside of the transformer, and prevents the surge and noise generated from the primary winding 110 and the secondary winding 120 to be emitted to the outside.

Accordingly, the reverse double winding coupling transformer 10 according to the exemplary embodiment of the present invention configured as described above has an inner side of the primary inner winding 111 and the secondary inner winding 121 close to the transformer core 100. (I.e., winding start point) and the outside of the primary outer winding 112 and the secondary outer winding 122 (i.e., the winding end point) to the N pole of the power source, thereby the primary inner winding 111 and the secondary It is possible to obtain an insulation performance and an electrostatic shielding effect on the inner side of the inner winding 121 and the outer side of the primary outer winding 112 and the secondary outer winding 122.

Referring to FIG. 6, in the reverse double winding coupling transformer 20 for electrostatic shielding, surge, and noise protection according to another embodiment of the present invention, the primary winding 210 and the secondary winding 220 may be formed in a single transformer. It is a wound iron transformer which is wound in the opposite direction to the core pillars and is formed in two turns and has a quadruple winding structure.

In the reverse double winding coupling transformer 20 of the outer iron type according to another exemplary embodiment of the present invention, the primary winding 210 and the secondary winding 220 are double wound coupled like the inner coil type transformer.

More specifically, the primary winding 210 is formed by double winding on the input end side (that is, the central core) 230 of the transformer core connected to the external power supply side. The primary winding 210 also includes a primary inner winding 211 and a primary outer winding 212 that are sequentially wound outwardly from the surface of the central core 230. Here, the primary inner winding 211 and the primary outer winding 212 are respectively wound in opposite directions.

The secondary winding 220 has a configuration similar to that of the primary winding 210, and is sequentially wound outwardly from the outer circumference of the primary winding 210, and of the transformer core 200 connected to the load side. It is formed by double winding on the output side. In addition, the secondary winding 220 includes a secondary inner winding 221 and a secondary outer winding 222 that are sequentially wound outward from the outer circumference of the primary winding 210. Here, the secondary inner winding 221 and the secondary outer winding 222 are respectively wound in the opposite direction.

The primary inner winding 211 and the secondary inner winding 221 of the primary winding 210 and the secondary winding 220 as described above and the primary outer winding 212 and the secondary outer winding 222, respectively. It is connected in parallel. More specifically, the winding start points of the primary inner winding 211 and the secondary inner winding 221 are electrically connected to the winding end points of the primary outer winding 212 and the secondary outer winding 222 to supply power. It is arranged on the N (neutral) side of. In addition, the winding end points of the primary inner winding 211 and the secondary inner winding 221 are electrically connected to the winding starting points of the primary outer winding 212 and the secondary outer winding 222 so that the power source is hot. It is arranged on a hot line side. Accordingly, since the interior of the primary winding 210 and the transformer core 200 are the same equipotential N − ground, leakage current does not occur. In addition, the outer side of the primary winding 210 and the outer side of the secondary winding 220 are the same equipotential N pole so that the electrostatic induction between each other does not occur.

In addition, a noise blocking unit (not shown) is formed on the outer core 240 positioned at both sides of the central core 230, which is a magnetic domain of the transformer core 200. The noise blocking unit may be at least one EMI coil consisting of a coil and a capacitor, or at least one resonance circuit in which the coil and the capacitor are combined. The noise blocking unit serves to block the noise generated on the magnetic field of the transformer core by acting as a filter of a specific frequency.

Therefore, the reverse double winding coupling transformer according to another embodiment of the present invention configured as described above can prevent the induction of the electrostatic component of the electric field component when the surge and the influx of electromagnetic waves and noise occur.

As a result, according to the reverse double winding coupling transformer according to the embodiment of the present invention, the expectation of the earth-to-earth insulation strength is high, and the burden of maintaining the earth-to-earth insulation strength of the insulator is reduced, so the life of the transformer is increased. In addition, in the case of dry and molded transformers, the outer surface of the coil, that is, the contact surface of the core and the contact surface of the atmosphere are all N-phase, and thus are electrically stable, thereby eliminating the risk of human contact. As the adsorption of dust is small, it is possible to prevent insulation breakdown by dust and to maintain cleanness.

What has been described above is only one embodiment for implementing a reverse double winding coupled transformer for the electrostatic shielding, surge and noise protection according to the present invention, the present invention is not limited to the above embodiment, the following claims As claimed in the scope of the present invention, those skilled in the art to which the present invention pertains will have the technical spirit of the present invention to the extent that various modifications can be made.

100, 200: transformer core 110, 210: primary winding
111, 211: primary internal winding 112, 212: secondary internal winding
120, 220: secondary winding 121, 221: secondary internal winding
122, 222: secondary outer winding 230: center core
240: outer core

Claims (4)

Primary winding formed by a double winding on the input side of the transformer core and the transformer core connected to the external power supply side, and secondary winding formed on the output end side of the transformer core connected to the load side A reverse double winding coupling transformer comprising a winding,
The primary winding is sequentially wound outwardly from the surface of the core for the transformer, each of which includes a primary inner winding and a primary outer winding wound in opposite directions,
The secondary winding is sequentially wound in an outward direction from the surface of the core for the transformer, each of which includes a secondary inner winding and a secondary outer winding wound in opposite directions,
And the primary inner winding and the secondary inner winding are connected in parallel to the primary outer winding and the secondary outer winding, respectively. Primary winding formed by a double winding on the input side of the transformer core and the transformer core connected to the external power supply side, and secondary winding formed on the output end side of the transformer core connected to the load side A reverse double winding coupling transformer comprising a winding,
The primary winding is sequentially wound outwardly from the surface of the core for the transformer, each of which includes a primary inner winding and a primary outer winding wound in opposite directions,
The secondary winding is sequentially wound in the outward direction from the outer circumference of the primary winding, each of which includes a secondary inner winding and a secondary outer winding wound in opposite directions,
And the primary inner winding and the secondary inner winding are connected in parallel to the primary outer winding and the secondary outer winding, respectively. The method according to claim 1 or 2,
The winding starting point of the primary inner winding and the secondary inner winding is electrically connected to the winding end points of the primary outer winding and the secondary outer winding, and is disposed on the N (neutral) side of the power source.
The winding end points of the primary and secondary internal windings are electrically connected to the winding starting points of the primary and secondary external windings, and are disposed on a hot line side of the power source. Reverse double winding coupled transformer for electrostatic shielding, surge and noise protection. The method according to claim 1 or 2,
A noise blocking part is formed on the magnetic path region of the transformer core.
The noise blocking unit may be at least one EMI coil consisting of a coil and a capacitor, or at least one resonance circuit in which the coil and the capacitor are combined. Reverse winding winding transformer for protection.

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