KR101675166B1 - Transformer having a function of common-mode noise rejection - Google Patents

Abstract

The present invention relates to a noise filter and a transformer for reducing the volume, weight and cost of a noise filter and a transformer used for protection of a user system and a system and for preventing malfunction in an electric system using a general industrial / household single-phase / It is an invention relating to integrating two electric component parts using a common material in common and using reverse winding to integrate them into one electric component part while maintaining the functions of two electric component parts intact. The present invention not only electrically isolates two systems with one electrical component, but also eliminates the transmission of common mode and differential mode noise components.

Description

[0001] Transformer having a filter function for noise [0002]

The present invention is directed to reducing passive components, which occupy a high volume and price, in an electric system using a utility-grid single-phase / three-phase utility for general industrial / household use. The common- (CM) filter for eliminating differential-mode (DM) noise components and a transformer (transformer) used for safety and voltage boosting / decompression of users and systems.

In the case of an electrical system connected to a power system, a 60 Hz (or 50 Hz) power transformer (transformer) is generally constructed between the system and the user system to boost / reduce the voltage and protect the user system. Such a transformer includes a primary winding and a secondary winding for each electrical phase, which is wound around the magnetic core. The primary side winding and the secondary side winding are electrically separated from each other and the electric energy of the primary side (secondary side) is transferred to the secondary side (primary side) by using the electromagnetic effect acting on the commercial power frequency (60 Hz, 50 Hz) . Thus, by adjusting the configuration of the windings, the commercial power supply having a specific voltage magnitude is stepped up or reduced to allow the user system to operate at the proper voltage. In addition, even if the primary (secondary) power supply (or the electrical system) has a problem (eg, phase unbalance, DC voltage, etc.) relative to the earth ground, The user is protected from being electrocuted or the system is destroyed.

On the other hand, the commercial power system (system) varies greatly in voltage quality depending on the transmission impedance and the load. That is, as the user system is far from the power generation facility, the voltage distortion increases and the harmonic harmonic component increases as the nonlinear load increases. The voltage unbalance due to the unbalanced load between phases and the fluctuation of the neutral voltage affect the operation of the user system. I am crazy. In addition, if the user system also contains a harmonic component in the input current, it will adversely affect the power supply system. Therefore, in many cases, a common mode and a differential mode noise filter are configured between the system and the user system in order to prevent the power supply, the user system, and the malfunction of the user system.

For the reasons stated above, the transformer and the noise filter constituting the electric field are widely used in a power conversion system for converting AC to DC. The general structure will be described with reference to the accompanying drawings.

FIG. 1 shows a conventional three-phase power conversion circuit using a transformer and a noise filter, and FIG. 2 shows a structure of a transformer and a noise filter having a single-phase structure as shown in FIG.

In FIG. 1, the electric energy generated in the commercial power source (system) 12 enters the user system via a transmission impedance 11 such as a transmission line or a transformer. An element such as an AC reactor 25 may be mounted for electrical control as required and the transformer 23 and the noise filter 24 are connected in series and then connected to the AC / DC converter 26 . The series connection order of the transformer 23, the noise filter 24, and the AC reactor 25 can be variably configured. The present invention relates to a method of combining a transformer (23) and a transformer (24) of FIG. 1 into one component (20).

Fig. 2 shows the structure of a single-phase transformer 23 and a noise filter 24 for the sake of simplicity. The connection order may be changed as necessary, and in this case also operates in the same manner. The transformer 23 is composed of a primary winding 19 and a secondary winding 18 and a core 13 made of a magnetic material and the primary winding 19 and the secondary winding 18 are electrically insulated And the electric energy is transferred from the primary side to the secondary side or from the secondary side to the primary side by the magnetic field which is transmitted to the core 13 only.

The noise filter 24 of FIG. 2 also includes a core 17 and a winding, but the winding method and the capacitors 14a, 14b, 15a, and 15b at the input and output stages are significantly different from those of the transformer. The two windings are wound around the core in different directions so that the inductance of the winding is generated electromagnetically only for the common mode AC component and equivalently the function of the LC filter relative to the ground 16 is obtained. On the other hand, since the inductance is not seen for the differential mode component, only a simple capacitance is generated in the line, so that it functions as a high-frequency filter composed only of a capacitor.

The principle of the related function is well described in [Literature 2], and the prior art related to the present invention is [Document 1]. The common feature of [1] and the present invention is that they combine the functions of a transformer and a noise filter. In reference to the technical structure of Document 1, the impedance is simply added to the input and output terminals of the conventional transformer so as to have the filtering function for the common mode / differential mode noise. However, in the present invention, since the inherent inductance generation principle of the in-phase mode / differential mode noise of the noise filter is used as it is by using the inverse windings 5 and 7 of each phase, the functions of the transformer 23 and the noise filter 24 It is combined. Therefore, when the structure of the present invention is used, the function of the transformer is maintained, and the filtering function is greatly improved and the degree of freedom of design is increased.

[Reference 1] KR 10-2000-0037829, Jung Soo Kim, Jung Soo Kim, 'Surge and noise multiple shielded power supply system', 2000. 6. 29.

[2] Gordon R. Slemon, 'Electric machines and drives', Addison-wesley publishing company, 1992, pp. 51-75, pp. 241-291

SUMMARY OF THE INVENTION The present invention solves this problem, and a structure in which a conventional transformer 23 and a noise filter 24 are connected has been widely used to protect the user system and the system and to prevent malfunction of the system. However, both of these components have a large volume in the field and are relatively high in price, thus increasing the weight / volume and price of the product. Accordingly, the present invention can reduce the weight, volume, and price of the electric field system, so that the transformer 23 and the noise filter 24 can be manufactured by taking the magnetic core into consideration, To be integrated into a single component 20 while maintaining the functions of the component 20.

In order to achieve the above object, the magnetic cores 13 and 17, which have been separately formed by the transformer 23 and the noise filter 24, are commonly used, and the winding method is changed to include all the functions in the conventional method .

That is, a power transmission winding 6 and a forward filter winding 5 are provided on the primary side of a core such as that used in a conventional transformer, and a tap 1 is provided between two windings, and the tap 1 is connected to a capacitor 3a Connected to the ground 21 via a capacitor 3b and provided with a reverse winding 7 to provide a tab 2 between two windings and connecting the tab 2 to the ground 21 via a capacitor 3b . Here, the main electric power transmission winding 6, the forward winding 5 and the reverse winding 7 are formed by one strand of wire. Further, additional capacitors 22 may be formed at both ends of the stranded conductors.

On the other hand, in the secondary side of the core, one winding 8 is formed, and the capacitors 10a and 10b are provided between the two ends of the winding, and the ground is connected between the grounds 9 at the secondary side. do.

4, the primary winding and the secondary winding can be formed on one axis of the core as shown in Fig. 4. The configuration of the winding is the same as that of the single phase, and after the end of the winding, the conventional three- DELTA connection).

More specifically, a transformer according to one aspect of the present invention includes a transformer core 4 having a primary side and a secondary side opposing the primary side, and a transformer core 4 having a transformer core 4 having a primary side and a secondary side A forward filter winding (5) wound on one side in a first direction and a forward filter winding (5) connected on the same side as the side on which the forward filter winding (5) is wound and wound in the same direction as the first direction (6) separated by the forward filter winding (5) and the first tap (1) and connected to the power transmission winding (6) on the same side as the winding side of the forward filter winding And a reverse filter winding (7) wound in a second direction opposite to the first direction and separated by the forward filter winding (5) and the power transmission winding (6) and the second tab (2) .

On the other hand, the winding structure composed of the forward filter winding 5, the power transmission winding 6, and the reverse filter winding 7 may be configured only on either the primary side or the secondary side, And may be configured on both the vehicle side and the secondary side.

The first tap 1 and the second tap 2 are connected to ground through a capacitor so that each terminal of the forward filter winding 5 and the reverse filter winding 7 is connected to the input / Function to perform the function of the noise filter at the same time as the transformer function.

When a general transformer winding 8 is provided on the side opposite to the winding side of the forward filter winding 5, the power transmission winding 6 and the reverse filter winding 7, the transformer winding 8, The ends of the transformer windings 8 can be connected to the ground 9 through the capacitors 10a and 10b by connecting the capacitors 10a and 10b at both ends.

According to another aspect of the present invention, there is provided a transformer comprising: a transformer core (4) having a primary side and a secondary side opposed to the primary side; a power transmission winding (5) provided on the primary side; A forward filter winding 5 connected to one end of the power transmission winding 6 and wound in the same direction as the power transmission winding 5, (7) connected to the other end of the transformer core (6) and wound in the reverse direction with respect to the electric power transmission winding (5), so that the noise filter and the transformer function are performed by a single transformer core .

According to another aspect of the present invention, there is provided a transformer comprising a transformer core (4) having a primary side and a secondary side opposed to the primary side, a power transmission winding (5) provided on the primary side, (1) and a second tab (8) are provided at one point and another point of the winding of at least one of the power transmission winding (5) or the transformer winding (8) 2 and the capacitors 3a and 3b connected to the first tap 1 and the second tap 2 are connected to the power transmission winding 5 or the transformer winding 8, At least one winding is connected to the ground 21 through the capacitors 3a and 3b in the middle of the winding through the first tap 1 and the second tap 2 to perform a noise filter function do.

It is also possible to perform the function of differential mode noise filtering by providing capacitors 22 and 27 at both ends of at least one of the two ends of the power transmission winding 5 or between both ends of the transformer winding 8 .

Further, the number of windings of the forward filter winding (5) and the reverse filter winding (7) are made equal to each other so that a filter function is added to the in-phase mode and the differential mode noise.

The number of turns of the power transmission winding 6 is set to be much larger, preferably 10 times or more, than the number of turns of the forward filter winding 5 and the reverse filter winding 7, While minimizing voltage attenuation.

As described above, the present invention can reduce the weight and volume of the user system by integrating the two conventional electric field components into one, and by using the magnetic core 4 in common, Can be reduced.

In comparison with the conventional technique [Document 1], different inductances can be applied according to the common mode / differential mode, which is a function inherent to the noise filter, so that a far superior filtering function can be achieved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a typical configuration diagram of an electric field system connected to a conventional system to receive electric power.
2 is a view showing a structure of a transformer and a noise filter of a conventional electric field system;
3 is a diagram showing a structure of a single-phase filter transformer constructed by applying the winding method of the present invention.
4 is a view showing the structure of a three-phase filter transformer constructed by applying the winding method of the present invention.
Figure 5 illustrates an electrical equivalent circuit for a differential mode electrical signal of a single phase filter transformer of the present invention.
6 illustrates an electrical equivalent circuit for a common mode electrical signal of a single phase filter transformer of the present invention.

The operation principle of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. It should be understood, however, that the drawings and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention, and are not to be construed as limiting the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to FIGS. Fig. 3 is a view showing a configuration of a single-phase filter transformer according to the present invention, in which a primary winding 5, a secondary winding 6, and a secondary winding 8 are wound around a magnetic core 4. Hereinafter, the portion where the primary windings 5, 6 and 7 are wound will be referred to as a "primary side" and the portion where the secondary winding 8 is wound will be referred to as a "secondary side".

The magnetic core 4 is made of a magnetic core made of a material similar to that of a conventional transformer and has a primary side wound around the primary side windings 5 and 6 and a secondary side wound around the secondary side winding 8, .

The primary winding is again divided into a forward filter winding (5), a power transmission winding (6), and a reverse filter winding (7). The forward filter winding 5 and the power transmission winding 6 are wound in the same direction, and the two windings 5 and 6 are divided on the basis of the first tab 1.

In addition, the reverse filter winding 7 is switched in direction at the second tab 2 and wound in the opposite direction to the two windings 5 and 6. Therefore, the three windings are distinguished from each other based on the first tap 1 and the second tap 2, respectively.

의 방향으로 유기되며 권선 7에 의한 자속은 도 3의

의 방향으로 유기되게 된다. Therefore, the flux according to the windings 5 and 6 for the differential mode (Diffential Mode, flow from the + terminal to the - terminal) which is fed to the primary + terminal by the Ampere's law,

And the magnetic flux by the winding 7 is induced in the direction of FIG. 3

As shown in FIG.

－

가 된다. 즉, 권선 5, 6, 7에 의한 1차측 마그네타이징(magnetizing) 인덕턴스는 L ₅ + L ₆ = L ₇ 이 된다. As a result, the flux due to the primary side differential mode current

-

. That is, the primary magnetizing inductance by the windings 5, 6, 7 is L ₅ + L ₆ = L ₇ .

At this time, if the same number of turns (number of turn) of the winding 5 with winding 7 is the primary inductance L ₆ is only for the differential mode (L ₆ = L _7). Where L ₅ , L ₆ , L ₇ Is the inductance generated by the windings 5, 6 and 7, respectively. Therefore, the voltage / current ratio between the primary side and the secondary side due to the differential mode voltage is determined according to the following equation (1).

_{(N 6 »N 5, N} 6» N 7)

Where N ₆ And N ₈ are the number of turns of winding 6 and winding 8, respectively. According to the above-described principle, an electric equivalent circuit is constructed as shown in FIG. 5 for the differential mode current.

That is, the turn number N ₆ of the power transmission winding ₆ is much larger than the turn number N _{5 of the} forward filter winding 5 and the turn number N ₇ of the reverse filter winding 7, So as to minimize the voltage attenuation while performing the noise filter function.

의 방향으로 유기된다. On the other hand, for a current component that flows into the common mode (+ or - terminal to ground) input to the primary + terminal, the power delivery winding 6 is open in terms of the magnetic circuit, Only the magnetic flux component due to the magnetic flux (5)

.

방향의 자속이 유기되므로 이 때, 정방향 필터 권선(5)과 역방향 필터 권선(7)에 의한 인덕턴스는 L ₅ + L ₇ 가 되어 자연스럽게 LC 필터 회로를 구성하게 된다. Further, by the reverse filter winding 7

The inductance due to the forward filter winding 5 and the reverse filter winding 7 becomes L ₅ + L ₇ , and the LC filter circuit naturally forms.

＋

의 자속이 2차측으로 다소의 에너지를 넘김으로써 이 에너지가 2차측에 차동모드 성분으로 나타나는데, 이것은 트랜스포머의 2차측 리키지(leakage) 인덕턴스와 2차측 캐패시터들(10a, 10b)에 의해 다시 차동모드 LC 필터가 구성됨으로써 제거되게 된다. only,

+

This energy is shown as a differential mode component on the secondary side because the flux of the magnetic flux of the secondary side of the transformer turns on some energy to the secondary side. This is because the secondary side leakage inductance of the transformer and the secondary side capacitors 10a, The LC filter is removed by construction.

Therefore, only the voltage of the primary side pure sine wave component is transmitted to the secondary side with a slight phase delay, and the common mode noise of the primary side is removed. According to the above-described principle, an electric equivalent circuit is constructed for the common mode current as shown in FIG.

When the energy is transferred from the secondary side to the primary side, only the differential mode component of the secondary side will be transferred to the primary side, and the power transmission winding 6 is connected to the primary side through the primary side power transmission winding 6 and the secondary side winding 8, Will be determined.

As described above, in the differential mode, the forward filter winding 5 and the reverse filter winding 7 have no influence and a very small voltage reduction occurs. However, this is because the winding ratio of the power transmission winding 6 and the secondary winding 8 .

The differential mode noise on the secondary side is once attenuated by the capacitors 10a and 10b and is removed by the primary side leakage inductance of the transformer and the capacitors 3a and 3b when electrical energy is transferred from the secondary side to the primary side. .

Meanwhile, the secondary ground 9 may be formed in common with the primary ground 21 (may be connected and configured), and the capacitors 22 and 27 may be formed separately from the primary side And to control the filter function for differential mode noise on the secondary side.

Figure 4 shows a filter transformer configuration of the present invention in a three-phase system. The basic structure is the same as that of the single phase of Fig. 3, and the way in which the primary and secondary ends are connected to the other phase to form a transformer of the Y or delta connection is the same as that of the existing three-phase transformer.

In addition, the shape of the magnetic core 4 in Fig. 4 can be changed according to the design purpose.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be readily apparent to those skilled in the art that the present invention can be modified and changed without departing from the scope of the present invention.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention.

That is, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the present invention.

Therefore, the scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

1: a tab (first tab) formed between the primary side forward winding and the power transmission winding,
2: a tab (second tab) extending between the primary side power transmission winding and the reverse winding,
3a and 3b: filter capacitors (capacitors)
4: Transformer core
5: primary side forward filter winding
6: Primary side power transmission winding
7: Primary side reverse filter winding
8: Secondary transformer winding.
9: Secondary ground
10a and 10b: filter capacitors (capacitors)
11: Transmission line impedance on the utility grid side
12: Power generation system
13: Conventional transformer core
14a, 14b, 15a, 15b: filter capacitors used in conventional noise filters
16: Ground used for conventional noise filter
17: Conventional noise filter core.
18: Conventional transformer secondary winding.
19: Conventional transformer primary winding.
20: Structure using conventional transformer and noise filter connected in series
21: Primary ground
22: Capacitor configured to primarily filter differential mode noise on the primary side
23: Conventional transformer
24: Conventional noise filter
25: Noise filter and AC reactor that can be configured in front of transformer
26: AC / DC converter that can be configured at the rear of the noise filter and transformer
27: A capacitor configured to filter the differential mode noise on the secondary side first

Claims (5)

A transformer core (4) having a primary side and a secondary side facing the primary side,
A forward filter winding (5) wound on the transformer core (4) in a first direction on either the primary side or the secondary side,
Is wound in the same direction as the first direction by being connected to the forward filter winding (5) on the same side as the winding direction of the forward filter winding (5) and wound by the forward filter winding (5) A divided power transmission winding 6,
Is wound in a second direction which is connected to the power transmission winding (6) on the same side as the winding side of the forward filter winding (5) and which is opposite to the first direction, and the forward filter winding (5) (7) separated by a first tab (6) and a second tab (2). The method according to claim 1,
Wherein the winding structure composed of the forward filter winding (5), the power transmission winding (6) and the reverse filter winding (7) is constituted only on either the primary side or the secondary side, The transformer being configured on both sides of the transformer. The method according to claim 1,
The first tap 1 and the second tap 2 are connected to the ground through a capacitor and each end of the forward filter winding 5 and the reverse filter winding 7 functions as an input / And at the same time, functions as a noise filter. The method of claim 3,
A transformer winding (8) is provided on the side opposite to the winding side of the forward filter winding (5), the power transmission winding (6) and the reverse filter winding (7)
Capacitors 10a and 10b are connected to both ends of the transformer winding 8,
Each end of the transformer winding (8) being connected to the ground (9) through the capacitors (10a, 10b). The method of claim 3,
Wherein a filter function is added to the in-phase mode and the differential mode noise by making the number of windings of the forward filter winding (5) and the reverse filter winding (7) the same.

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