KR102677672B1 - Transformer impedance control device - Google Patents

Abstract

Disclosed is a transformer impedance control device. The present invention controls the amount of leakage magnetic flux by installing one or more ferromagnetic materials through which leakage magnetic flux can easily pass on the outside of the transformer in order to adjust the amount of leakage magnetic flux of an already installed transformer, making it possible to adjust the impedance of the transformer without replacing the installed transformer. do.

Description

Transformer impedance control device {TRANSFORMER IMPEDANCE CONTROL DEVICE}

The present invention relates to a transformer impedance control device. More specifically, the present invention relates to a transformer impedance control device, and more specifically, to control the amount of leakage magnetic flux of an already installed transformer by installing one or more ferromagnetic materials through which the leakage magnetic flux can easily pass on the outside of the transformer to control the amount of leakage magnetic flux. , relates to a transformer impedance control device capable of adjusting the impedance of a transformer without replacing the installed transformer.

In general, a transformer is an inductive device that converts the voltage of the other winding when an alternating current voltage of the same frequency is applied to one winding through electromagnetic induction. It is composed of at least two windings, one or more iron cores, and insulators.

Figure 1 is an exemplary diagram showing a general transformer. Referring to Figure 1, most transformers 10 apply a three-phase four-wire type that can simultaneously supply single-phase and three-phase loads, and have a fixing structure 20. It is fixed through

Figure 2 is an example diagram shown to explain the transforming action of a general transformer.

Referring to Figure 2, when the primary coil 12 and the secondary coil 13 are wound around the core 11 of the transformer 10 and a voltage is supplied to the primary coil 12, the primary coil 12 And electromotive force (e1, e2) is generated in the secondary coil 13 according to Faraday's law.

At this time, the electromotive force (e1) of the primary coil 12 becomes a voltage opposite to the supply voltage, and the electromotive force (e2) of the secondary coil 13 becomes the secondary voltage of the transformer.

이고,Here, electromotive force (e) according to Faraday's law is

ego,

,

이다.

,

am.

Here, e1 is the primary electromotive force, e2 is the secondary electromotive force, N1 is the number of primary windings, N2 is the secondary winding number, and d _ϕ /d _t is the temporal change in magnetic flux.

In addition, the main magnetic force flux 14 created by the primary coil 12 through the transforming action of boosting or lowering the voltage does not pass directly to the secondary coil 13, but part of it is Leakage flux (15) that leaks to other places is generated, and this leakage flux (15) generates reactance.

Meanwhile, magnetomotive force generates magnetic flux (ϕ) when a current flows in a coil, and can be expressed as the product of the number of turns (N) of the coil and the current (I) flowing through the coil.

At this time, the size of the magnetic flux is determined depending on the size of the magnetic resistance. If the core material is a material with high magnetic resistance, the magnetic flux generation is reduced due to resistance to the flow of the magnetic flux. If the core material is a material with low magnetic resistance, the magnetic flux generation is reduced. As the magnetic flux flows smoothly, magnetic flux generation increases.

Here, magnetic resistance varies depending on the material of the core. In general, materials with high magnetic resistance are non-magnetic materials, such as stainless steel, aluminum, paper, air, etc., to which magnets do not attract easily, and materials with low magnetic resistance are non-magnetic materials, such as stainless steel, aluminum, paper, air, etc. is a ferromagnetic material, for example, a material that attracts magnets well, such as iron or silicon steel plate.

Although the leakage magnetic flux is directly related to the size of the reactance among the transformer impedances, the transformer according to the prior art has a problem in that the impedance of the transformer cannot be changed when installed at a specific location.

In other words, the number of windings of an already installed transformer cannot be changed, so when the system capacity increases, the short-circuit current increases, requiring replacement of the breaker accordingly.

In addition, when replacing already installed electrical equipment to respond to increased short-circuit current, maintenance costs increase, power outages inevitably occur due to replacement of electrical equipment, and the power outage time increases depending on the replacement work time. there is.

Korean Registered Patent Publication No. 10-0775508 (Name of invention: Transformer)

In order to solve this problem, the present invention controls the amount of leakage magnetic flux by installing one or more ferromagnetic materials that facilitate the passage of leakage magnetic flux on the outside of the transformer to control the amount of leakage magnetic flux of the already installed transformer, thereby avoiding replacing the installed transformer. The purpose is to provide a transformer impedance control device capable of adjusting the impedance of the transformer without any problems.

In order to achieve the above object, an embodiment of the present invention is a transformer impedance control device, which is installed at a certain distance from a transformer having a core, a primary coil and a secondary coil wound on the core, and generates impedance in the transformer. It includes an impedance control module that controls the transformer impedance based on the variation of the leakage magnetic flux by operating to increase or decrease the amount of leakage magnetic flux of the transformer by forming a path for the leakage magnetic flux to pass through.

In addition, the impedance control module according to the above embodiment is characterized in that it operates to vary the amount of leakage magnetic flux by stacking an additional impedance control module on one side of the transformer.

In addition, the impedance control module according to the above embodiment includes an impedance control unit that forms a path for the leakage magnetic flux generated in the transformer to pass through; and an adjusting unit that supports the impedance control unit to be installed at a predetermined distance away from the transformer.

In addition, the impedance control module according to the above embodiment has one side connected to a structure that fixes the transformer, and the other side connected to the adjustment unit, so that the impedance control unit and the adjustment unit are fixed at a position spaced a certain distance from the transformer. It is characterized by further including ;.

In addition, the impedance control unit and adjustment unit according to the above embodiment are characterized in that they are made of different sizes depending on the capacity of the transformer.

In addition, the impedance control unit and adjustment unit according to the above embodiment are characterized by being made of a ferromagnetic material.

The present invention controls the amount of leakage magnetic flux by installing one or more ferromagnetic materials through which leakage magnetic flux can easily pass on the outside of the transformer in order to control the amount of leakage magnetic flux of an already installed transformer, making it possible to adjust the impedance of the transformer without replacing the installed transformer. There is an advantage.

Figure 1 is an example diagram showing a general transformer.
Figure 2 is an example diagram showing the transforming action of a general transformer.
Figure 3 is a perspective view showing a transformer impedance control device according to an embodiment of the present invention.
Figure 4 is an exploded perspective view showing the configuration of a transformer impedance control device according to the embodiment of Figure 3.
Figure 5 is an exemplary diagram showing the use state of the transformer impedance control device according to the embodiment of Figure 3.
Figure 6 is a cross-sectional view showing the use state of the transformer impedance control device according to the embodiment of Figure 5.
Figure 7 is a cross-sectional view showing a transformer impedance control device according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to preferred embodiments of the present invention and the accompanying drawings, assuming that the same reference numerals in the drawings refer to the same components.

Before describing specific details for implementing the present invention, it should be noted that configurations that are not directly related to the technical gist of the present invention have been omitted to the extent that they do not distract from the technical gist of the present invention.

In addition, the terms or words used in this specification and claims have meanings and concepts that are consistent with the technical idea of the invention, based on the principle that the inventor can define the concept of appropriate terms to explain his or her invention in the best way. It should be interpreted as

In this specification, the expression that a part “includes” a certain element does not mean excluding other elements, but means that it may further include other elements.

In addition, terms such as "‥unit", "‥unit", and "‥module" refer to a unit that processes at least one function or operation, which can be divided into hardware, software, or a combination of the two.

In addition, the term "at least one" is defined as a term including singular and plural, and even if the term "at least one" does not exist, each component may exist in singular or plural, and may mean singular or plural. This can be said to be self-evident.

Hereinafter, a preferred embodiment of a transformer impedance control device according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

(First Example)

Figure 3 is a perspective view showing the transformer impedance control device according to an embodiment of the present invention, Figure 4 is an exploded perspective view showing the configuration of the transformer impedance control device according to the embodiment of Figure 3, and Figure 5 is the embodiment of Figure 3 It is an exemplary diagram showing the state of use of the transformer impedance control device according to the embodiment, and Figure 6 is a cross-sectional view shown to explain the state of use of the transformer impedance control device according to the embodiment of Figure 5.

As shown in Figures 3 to 6, the transformer impedance control device according to an embodiment of the present invention includes one or more ferromagnetic materials through which leakage magnetic flux can easily pass outside the transformer so as to control the amount of leakage magnetic flux of the already installed transformer. It may be configured to include an impedance control module 100 that is installed to control the amount of leakage magnetic flux.

The impedance control module 100 may be installed at a certain distance from the transformer 200 including the core 210 and the primary coil 220 and secondary coil 230 wound on the core 210.

In addition, the impedance control module 100 operates to increase or decrease the amount of leakage magnetic flux of the transformer 200 by forming a path for the leakage magnetic flux generated in the transformer 200 to pass through, thereby adjusting the transformer impedance based on the variation of the amount of leakage magnetic flux. Control.

To this end, the impedance control module 100 may be configured to include an impedance control unit 110, an adjustment unit 120, and a fixing stand 130.

The impedance control unit 110 is a component that forms a path for the leakage magnetic flux generated in the transformer 200 to pass through, and includes an impedance control unit body 111 and an impedance control coupling groove 112 formed at both ends of the impedance control unit body 111. ) and an impedance control coupling hole 113 formed in the impedance control coupling groove 112.

The impedance control unit body 111 may be composed of a plate-shaped member with a rectangular shape corresponding to the longitudinal size of the transformer 200.

Additionally, the impedance control unit body 111 may be made of a ferromagnetic material with low magnetic reluctance, such as iron or silicon steel plate, and may preferably be made of a silicon steel plate with a thickness of 0.5 mm to 1.0 mm.

That is, the impedance control unit body 111 is installed on one side of the transformer 200 and smoothes the flow of leakage magnetic flux so that the leakage magnetic flux generated from the transformer 200 passes well, thereby increasing the amount of leakage magnetic flux.

In addition, the impedance control body 111 changes the longitudinal size, width direction size, or installed number of the impedance control body 111 according to the capacity of the transformer 200, thereby reducing the amount of leakage magnetic flux. can also be adjusted.

In other words, the leakage magnetic flux is directly related to the size of the reactance (L) among the transformer impedances, and can be expressed as the following equation.

Here, N is the number of turns, ϕ ₁₁ is the leakage magnetic flux, and I ₁₁ is the current that generates the leakage magnetic flux. It can be seen that the reactance varies depending on the leakage magnetic flux.

In addition, the impedance control body 111 is made of a ferromagnetic material with low magnetic resistance, so that it can easily pass magnetic flux. In order to increase or decrease the amount of leakage magnetic flux, the amount of installation of the impedance control body 111 is varied to increase or decrease the amount of leakage magnetic flux. can also be adjusted.

The impedance control unit coupling groove 112 is installed at both ends of the impedance control unit body 111 and coupled to the adjustment unit 120, and can be fitted with the adjustment unit 120 through a plurality of grooves and coupling parts.

The impedance control unit coupling hole 113 is formed in the impedance control unit coupling groove 112, and the impedance control unit body 111 is fixed to the adjustment unit 120 while being coupled to the adjustment unit 120 through the fastening parts 140 and 140a. make it possible

The adjustment unit 120 is a component that supports the impedance control unit 110 to be installed at a certain distance from the transformer 200, and includes an adjustment unit body 121, an adjustment unit coupling groove 122, and a coupling groove coupling hole 123. ) and an adjustment unit coupling hole 124.

The control body 121 may be composed of a plate-shaped member with a rectangular shape corresponding to the radial size of the transformer 200.

That is, the adjusting unit body 121 supports the impedance control unit 110 so that it can be arranged and fixed at a position spaced a certain distance away from the outer surface of the transformer 200.

In addition, the control body 121 may be made of a ferromagnetic material with low magnetic reluctance, such as iron or silicon steel plate, and may preferably be made of a silicon steel plate with a thickness of 0.5 mm to 1.0 mm, and may be made of a plurality of silicon steel plates. It may also be configured in a laminated form.

Additionally, the adjustment unit body 121 may be configured to have a different length depending on the capacity of the transformer 200.

That is, if the capacity of the transformer 200 is small, the distance between the transformer 200 and the impedance control unit 110 is small so that the separation distance is narrowed, for example, 2/3 of the preset unit adjustment unit body length, 1/ It can be configured in 2 sizes or 1/3 sizes.

The adjustment unit coupling groove 122 is installed on one side of the adjustment unit body 121 and coupled to the impedance control unit 110, and can be fitted and coupled to the impedance control unit 110 through a plurality of grooves and coupling parts.

The coupling groove coupling hole 123 is formed in the adjustment unit coupling groove 122, and the adjustment unit body 121 is fixed to the impedance control unit 110 while being coupled to the impedance control unit 110 through the fastening parts 140 and 140a. make it possible

The adjustment unit coupling hole 124 is installed on the other side of the adjustment unit body 121 so that the adjustment unit body 121 is coupled to the fixing stand 130 through the fastening part 141.

The fixing stand 130 is a component that is combined with the adjusting unit 120 and supports the adjusting unit 120 and the impedance control unit 110 combined with the adjusting unit 120 to be fixed to the outside of the transformer 200. The fixing stand body 131 It may be configured to include a fixed stand coupling hole 132.

The fixed stand body 131 has one side coupled to the adjustment portion 120, and the structure 300 and support portion 310 for fixing the external housing of the transformer 200 and the transformer 200 through a flange 131a formed on the other side. It can be connected to any one of the following.

That is, the fixed stand body 131 is installed around the outside of the transformer 200, for example, at the rear of the transformer 200, at a position where the impedance control unit 110 and the adjustment unit 120 are spaced a certain distance away from the transformer 200. and ensure that it is fixed.

In addition, the fixed stand coupling hole 132 allows the fixed stand body 131 and the adjusting unit 120 to be fixed in a coupled state through the fastening part 141.

In addition, the fixing base coupling hole 132a formed in the flange 131a allows the fixing base 131 to be fixed to the structure 300 that fixes the transformer 200 through a fastening part.

Therefore, by individually installing the impedance control modules (100, 100a, 100b) outside the plurality of transformers (200, 200a, 200b) fixed through the structure 300, the transformer impedance for each transformer (200, 200a, 200b) can be controlled.

(Second Embodiment)

First, the same reference numerals are used for the same components, and repetitive descriptions are omitted.

Figure 7 is a cross-sectional view showing a transformer impedance control device according to another embodiment of the present invention.

As shown in FIG. 7, the impedance control module 100' according to the second embodiment differs in that an additional impedance control module 100' is stacked and installed on one side of the impedance control module 100.

That is, when the grid capacity increases or decreases and the impedance of the transformer 200 needs to be adjusted, an additional impedance control module 100' is stacked on one side of the already installed impedance control module 100, or a stacked additional impedance control module is installed. By removing (100'), the transformer impedance can be controlled.

To this end, the additional impedance control module 100' may be configured to include an impedance control unit 110' and an adjustment unit 120' so that it can be stacked on the already installed impedance control module 100.

The impedance control unit 110' and the adjustment unit 120' according to the second embodiment may be configured to have a size increased by a certain amount compared to the impedance control unit 110 and the adjustment unit 120 according to the first embodiment, or the opposite first embodiment. It may be of a smaller size than the impedance control unit 110 and adjustment unit 120 according to the embodiment.

That is, if the load increases during operation of the transformer 200, the voltage drop of the transformer 200 increases. At this time, if the voltage drop is lower than the preset reference value, an additional impedance control module 100 is added to the already installed impedance control module 100. ') are installed in a stacked manner to increase the amount of leakage magnetic flux.

In addition, if the voltage drop of the transformer 200 is higher than the preset reference value, the additional impedance control module 100' is removed to reduce the amount of leakage magnetic flux, thereby reducing the voltage drop of the transformer through a reduction in the transformer impedance.

Therefore, in order to control the amount of leakage magnetic flux of an already installed transformer, the amount of leakage magnetic flux is controlled by installing one or more ferromagnetic materials through which the leakage magnetic flux passes outside the transformer. Impedance adjustment of the transformer can be performed without replacing the installed transformer. .

As described above, the present invention has been described with reference to preferred embodiments, but those skilled in the art may make various modifications and changes to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You will understand that you can do it.

In addition, the drawing numbers described in the claims of the present invention are only used for clarity and convenience of explanation and are not limited thereto. In the process of explaining the embodiment, the thickness of the lines shown in the drawings, the size of the components, etc. may be exaggerated for clarity and convenience of explanation.

In addition, the above-described terms are terms defined in consideration of the functions in the present invention, and may vary depending on the intention or custom of the user or operator, so interpretation of these terms should be made based on the content throughout the present specification. .

In addition, even if not explicitly shown or explained, a person skilled in the art to which the present invention pertains can make various modifications including the technical idea of the present invention from the description of the present invention. It is self-evident, and it still falls within the scope of the present invention.

In addition, the above embodiments described with reference to the accompanying drawings are described for the purpose of explaining the present invention, and the scope of the present invention is not limited to these embodiments.

100, 100a, 100b, 100': Impedance control module
110, 110': Impedance control unit 111: Impedance control unit body
112: Impedance control unit coupling groove 113: Impedance control unit coupling hole
120, 120': Control unit 121: Control unit body
122: Control unit coupling groove 123: Coupling groove coupling hole
124: Adjustment unit coupling hole 130: Fixed stand
131: fixed stand body 131a: flange
132, 132a: Fixed stand coupling hole 140, 141, 140a: Fastening part
200, 200a, 200b: Transformer 210: Core
220: primary coil 230: secondary coil
300: Structure 310: Support

Claims (6)

It is installed at a certain distance from the transformer 200 on the outside of the transformer 200, which includes a core 210, a primary coil 220, and a secondary coil 230 wound on the core 210. An impedance control unit 110 that operates to increase or decrease the amount of leakage magnetic flux of the transformer 200 by forming a path for the leakage magnetic flux generated in the transformer 200 to pass through, and the impedance control unit 110 controls the transformer 200. An impedance control module 100 including an adjustment unit 120 that supports the installation at a certain distance away from the module; and
An additional impedance control module (100') stacked on one side of the impedance control module (100) and installed to vary the amount of leakage magnetic flux of the transformer (200) passing through the impedance control unit (110). A transformer impedance control device comprising a. . delete According to claim 1,
The additional impedance control module 100' includes an impedance control unit 110' that forms a path for the leakage magnetic flux generated in the transformer 200 to pass through; and
A transformer impedance control device comprising an adjusting unit (120') that supports the impedance control unit (110') to be installed at a predetermined distance from the transformer (200). According to claim 3,
One side of the impedance control module 100 and the additional impedance control module 100' is connected to the structure 300 that fixes the transformer 200, and the other side is connected to the adjusting units 120 and 120' to operate the impedance control unit. A transformer impedance control device further comprising a fixing stand (130) that supports the (110, 110') and the adjusting units (120, 120') to be fixed at a position spaced a certain distance away from the transformer (200). According to claim 4,
A transformer impedance control device, characterized in that the impedance control units (110, 110') and adjustment units (120, 120') have different sizes depending on the capacity of the transformer (200). According to claim 5,
A transformer impedance control device, characterized in that the impedance control units (110, 110') and adjustment units (120, 120') are made of a ferromagnetic material.

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