KR20220114725A - Planar coil for reactor and reactor having the same - Google Patents

Abstract

The present invention relates to a planar coil for a reactor and a reactor having the same. The reactor comprises a coil assembly manufactured so that planar coils are manufactured in a structure in which a thin and long plate-shaped material is wound at least twice from the outside to the inside on a plane, these planar coils are stacked, the respective planar coils are electrically connected in line with each other, so that a current flows from the top planar coil to the bottom planar coil, and an insulating member is interposed between the planar coils. The reactor is manufactured, and thus that a high current is provided by the number of times the coils are wound compared with an existing "["-shaped plate-shaped material. In the case of providing the same high current, the number of stacked coils is reduced compared with the existing "["-shaped plate-shaped material, and thus the overall height of the reactor is reduced, and ultimately, the size of the reactor can be reduced.

Description

Planar coil for reactor and reactor having the same

The present invention relates to a reactor, and more particularly, a plate-shaped coil is manufactured in which a thin and wide plate-shaped material is wound twice or more from the outside to the inside, and a plurality of the plate-shaped coils are stacked and electrically connected It relates to a plate-type coil for a reactor and a reactor having the same, in which a cooler is disposed around the flat-type coils and manufactured, so that the number of stacked flat-type coils is reduced in proportion to the number of turns, thereby enabling miniaturization.

In general, reactors are used for various purposes. Typical reactors include series reactors that are connected in series to a motor circuit to limit the current at the time of a short circuit, a parallel reactor that stabilizes the current distribution between parallel circuits, and a current limiter ( Positive reactor, starting reactor connected in series to the motor circuit to limit the starting current, shunt reactor connected in parallel to the transmission line to compensate for phase-leading reactive power or suppress abnormal voltage, neutral and A neutral point reactor connected between the earths and used to limit the ground fault current flowing in the event of a ground fault in the power system, and an arc extinguishing reactor that automatically extinguishes the arc that occurs in the case of a 1-wire ground fault in a 3-phase power system. have.

Such a reactor provides a large inductive reactance with respect to an alternating current or a sudden change in current due to accumulation of electromagnetic energy, and may have a structure in which a coil is wound around an iron core. At this time, the existing shape of the coil may be a winding type in which the material of the round bar is wound from top to bottom.

In the case of a reactor having such a winding type coil, in order to increase the magnetomotive force, the number of windings is further increased, and thus the size is inevitably increased.

In consideration of this, in Korean Patent Registration No. 10-1948480 (Title of the Invention: Ferromagnetic magnetic field reactor device and manufacturing method thereof), as shown in FIG. The ferromagnetic material 3 is inserted into the empty space of the winding portion 2, and the ferromagnetic material 3 is extended to surround the winding portion 2 to form a magnetic path; and the winding portion 2 A reactor including a; a support part (not shown) that applies pressure to the top and bottom of Here, the plate-shaped material 1 has an approximately 'C' shape.

In the case of a reactor having such a winding part 2 , compared to a reactor having a winding coil, the size is reduced based on the same large current, the space factor is improved, and the magnetomotive force per unit area can be increased.

However, in order to make the size of the reactor smaller, the development of technology for making the size of the winding part 2 also smaller is required.

Republic of Korea Patent Registration No. 10-1925216 (Notice on Dec. 4, 2018) Republic of Korea Patent No. 10-1948479 (announced on Jan. 14, 2019)

An object of the present invention, devised in view of the above requirements, is to increase the number of windings of the coil compared to the conventional 'C'-shaped plate-shaped material by manufacturing a plate-shaped material into a flat coil with a structure wound two or more times from the outside to the inside of the reactor. An object of the present invention is to provide a flat plate coil having a reduced size.

Another object of the present invention is to provide a reactor in which a plurality of coil structures having a smaller structure than in the prior art are stacked in parallel to minimize heat generation due to the skin effect occurring when a large current is applied by current distribution. .

In order to achieve the above object, the flat coil for a reactor according to the present invention may be a reactor having a flat coil, and the flat coil may have a structure in which a thin plate material is wound at least twice from outside to inside on a plane.

In this case, in the case of the two-wind structure, the outermost sides, the car outer sides, and the innermost sides are provided, and in the case of the structure wound three or more times, the intermediate sides wound at least once before the innermost sides may be additionally provided.

Accordingly, by increasing the number of windings by manufacturing the flat coil in a structure wound two or more times, it is possible to provide a larger inductance than a one-wind structure or a 'C'-shaped structure.

In addition, the flat coil is a quadrangle or a chamfered quadrangle in plan view, and extends from the connection terminal and the connection terminal to the outermost dominant side, the outermost lower street side, the outermost left vertical side, the outermost shopping street side, and the car outer side dominant side. It may be a (A)-type flat plate coil having a side, an outer side lower street side, a vehicle outer side vertical side and an innermost shopping street side, optionally further comprising middle sides, and having a different width according to each side.

In this case, the connection terminal may protrude by extending from the outermost right-hand side. In addition, the outermost right side, the outermost lower street side, the outermost left vertical side, the outer right vertical side, the outer side lower street side and the outer left side vertical side may have the same width. In addition, the innermost shopping street side may be narrower than the outermost dominant street side.

In addition, the flat coil is rectangular in plan view and extends from the connecting portion and the connecting portion, so that the outermost shopping street side, the outermost right side street, the outermost lower side street side, the outermost left side street side, the car outer side shopping street side, the car outer right vertical side, It may be a (B)-type flat plate coil 20 having a lower side of the vehicle, a vertical side of an outer side of the vehicle, and an innermost side of the shopping street, optionally further including intermediate sides, and having a different width according to each side.

In this case, the connection part may have a shape protruding outward from the outermost shopping street. In addition, the width of the outermost shopping street side, the outermost right side street, the outermost lower side street side, the outermost left side street side, the car outer side shopping street side, the car outer side right side street side, the outer side lower side street side and the outer left side vertical side can be the same have. In addition, the innermost shopping street side may be narrower than the outermost shopping street side.

In addition, the flat coil is rectangular in plan view, and extends from the connection part and the connection part, so that the outermost left vertical side, the outermost lower street side, the outermost right vertical side, the outermost shopping street side, the outer left side vertical side, the car outer lower side, It may be a (c)-type flat plate coil having an outer dominant street side and an innermost shopping street side, optionally further comprising intermediate sides, and having a different width according to each side.

In this case, the connection part may be extended and refracted from the outermost seat longitudinal side to protrude outward. In addition, the outermost left vertical side, the outermost lower street side, the outermost right vertical side, the outer left side vertical side, the outer lower side street side and the outer right vertical side of the vehicle may have the same width. In addition, the innermost shopping street side may be narrower than the outermost seat vertical side. Also, the middle sides may be the same as the width of the first dominant road side.

On the other hand, in the reactor having a flat-plate coil according to the present invention, the above-described flat-plate coils are stacked, and each flat-type coil is electrically connected to each other in a line so that a current flows from the uppermost flat-type coil to the lowest flat-type coil, It may include; a coil assembly manufactured by interposing an insulating member between the flat coils.

Here, the coil assembly may include (A)-type flat plate coils disposed on the uppermost and lowermost positions, and (B)-type plate-type coils and (C)-type plate-type coils disposed in the middle.

Such a coil assembly may be formed by providing an upper coil assembly and a lower coil assembly that are stacked and electrically connected to each other in parallel.

In addition, the coil assembly includes a first sleeve installed to electrically connect the connection terminals of the uppermost (A) type flat coil of the upper coil assembly and the uppermost (A) type flat coil of the lower coil assembly, and the upper coil assembly. A second sleeve installed to electrically connect the lowermost (A)-type flat coil and the lowermost (A)-type flat coil of the lower coil assembly may be further provided. Accordingly, the upper coil assembly and the lower coil assembly may have a parallel structure by the first sleeve and the second sleeve.

In addition, in the case of the upper coil assembly or the lower coil assembly, when four flat plate coils are stacked, the uppermost (A) type flat plate coil and the second upper (C) type flat plate coil are electrically connected to the innermost street sides, The connection parts are electrically connected between the (C) type flat plate coil of the second upper level and the (B) type flat coil of the second lower level, and the (B) type flat plate coil of the second lower level and the (A) type flat coil of the lowest level are the lowest. The inner shopping streets are electrically connected so that all the flat coils are electrically connected in series to each other.

In addition, in the upper coil assembly or the lower coil assembly, the topmost (A) type flat plate coil is arranged so that the connection terminal is located on the left, and the (C) type flat plate coil and (B) type flat coil below it are connected The sub is arranged to be located on the same line on the right side, and the lowermost (A) type flat plate coil may be arranged such that the connection terminal is located on the right side. At this time, the connection part of the (C) type flat plate coil and the (B) type flat coil coil may be positioned to the left by a certain length so as not to be located on the same line as the connection terminal of the lowest (A) type flat plate coil.

In addition, as for the upper coil assembly or the lower coil assembly, when eight flat coils are stacked from top to bottom, the first (A) type flat coil and the second (C) type flat coil are electrically connected to the innermost side of the shopping street. The connection parts are electrically connected to No. 2 (C) type flat plate coil and No. 3 (B) type flat plate coil, and the number 3 (B) flat plate coil and No. The innermost shopping streets are electrically connected, and the connecting parts of No. 4 (B) type flat plate coil and No. 5 (C) flat plate coil are electrically connected, and No. 5 (C) type flat plate coil and No. 6 ( The innermost street sides of the C) type flat plate coil are electrically connected, and the connecting parts of the No. 6 (C) type flat plate coil and No. 7 (B) type flat plate coil are electrically connected, and the 7 (B) type flat coil is electrically connected. The flat coil and the innermost street sides of the (A) type flat coil of No. 8 may be electrically connected to each other.

In addition, in the upper coil assembly or the lower coil assembly, the connection terminal of No. 1 (A) flat plate coil is located on the left, and No. 2 (C) flat plate coil and No. 3 (B) flat plate coil have a connection part. It is located on the right side, and for No. 4 (B) type flat plate coil and No. 5 (C) type flat plate coil, the connection part is located on the left, and No. 6 (C) type flat plate coil and No. 7 (B) type flat plate type coil are located on the right. As for the coil, the connection part is located on the right, and the connection terminal may be located on the right side of the (A) type flat coil of No. 8.

In addition, the connection part of the (c) type flat coil of No. 2 and 6 and the (b) type flat coil of No. 3 and 7 is set so as not to be located on the same line as the connection terminal of the (A) type flat coil of No. 8 It can be positioned to the left by the length.

And the connection part of No. 4 (B) type flat coil coil and No. 5 (C) type flat coil is located to the right by a certain length so as not to be located on the same line with the connection terminal of No. 1 (A) flat plate type coil. can

As described above, according to the present invention, by manufacturing a flat coil having a structure in which a plate-shaped material of a certain length is wound twice or more from the outside to the inside, it is proportional to the square of the number of coil windings than the conventional 'C'-shaped plate-shaped material. The number of stacks is reduced, thereby reducing the overall height of the coil assembly made of the flat coil, as well as ultimately reducing the size of the reactor.

And by stacking a plurality of coil structures with reduced heights in parallel, heat generation is reduced by current distribution by suppressing the skin effect that occurs during a large current, and current efficiency per coil cross-sectional area can be increased.

And by manufacturing a coil assembly electrically connected by stacking a plurality of single-plate coils having a winding structure of two or more times, when the same large current is provided, the number of stacks is reduced compared to the conventional 'U'-shaped flat plate material, so the overall height is reduced and ultimately the size of the reactor can be reduced.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited only to the matters described in those drawings should not be construed as
1 is an exploded perspective view showing a main part of a conventional reactor.
FIG. 2 is a plan view showing planar coils for a reactor according to a preferred embodiment of the present invention.
3 is a plan view illustrating another example of the single-plate coils of FIG. 2 .
FIG. 4 is a side cross-sectional view schematically illustrating the reactor with the flat coil of FIG. 2 .
FIG. 5 is an abusive view showing the coil assembly shown in FIG. 4 .
6 is an exploded view of FIG. 5 .
7 and 8 are exploded views illustrating a stacked structure of the flat coils of FIG. 6 .

Hereinafter, preferred embodiments will be described in detail so that those of ordinary skill in the art can easily practice the present invention with reference to the accompanying drawings. In addition, among the components mentioned in various embodiments, mutually similar components and related components in each embodiment may be replaced, replaced, or added. However, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention in describing the operating principle of the preferred embodiment of the present invention in detail, the detailed description thereof will be omitted.

<Flat coil>

The flat coil (C) for a reactor according to a preferred embodiment of the present invention can be manufactured in a structure in which a thin plate-shaped material is wound two or more times while being spaced apart from each other on the same plane. As an example, as shown in FIG. 2 , the flat coil (C) is manufactured in (A) type, (B) type and (C) type, and may be manufactured in a two-winding structure. The flat coil (C) may preferably be manufactured in a shape wound in a substantially rectangular shape on a plane, and as another example, may be manufactured in an approximately circular or polygonal wound shape, and in the case of a polygon, corners may be chamfered .

Here, the 'two-winding structure' may be a shape that is wound twice at about 720° on a plane while having a distance from each other based on the outer end in a flat wound state. In more detail, the 'two-winding structure' is a case in which a plate-shaped material is wound in an approximately square shape on a plane, the winding angle is 720°, ), the end point may not reach the starting point, and the end point may be positioned past the starting point as in (B)-type flat plate coil (20). In addition, in the case of circular winding on a plane, the end point does not pass or reach the starting point. It may be of a shape wound around 700 to 750° so as not to be wounded. Therefore, the flat coil (C) having the two-winding structure can provide a larger inductance in proportion to the square of the number of turns than the single-winding structure or the 'C'-shaped winding structure.

Hereinafter, the planar quadrangular flat coil (C) will be described with reference to FIG. 2, and directions including up, down, left, right, horizontal, vertical, etc. are based on each drawing.

First, the (A) type flat plate coil 10 is refracted in a clockwise direction from the upper right corner and has a shape of a two-winding structure. Due to this shape, the connection terminal 11 at the outermost end, the outermost right vertical side 12, the outermost lower side street 13, the outermost side vertical side 14, the outermost shopping street side 15, the outside of the car A dominant road side 16 , a lower side street side 17 , a side side vertical side 18 , and an innermost side street side 19 may be provided.

Here, the connection terminal 11 is located at the right end portion, and may protrude from the adjacent outermost shopping street side 15 so that the first sleeve 130 or the second sleeve 131 is connected as shown in FIG. 5 . The width of the connection terminal 11 may be equal to or greater than that of the outermost dominant side 12 .

In addition, the outermost right vertical side (12), the outermost lower street side (13), the outermost left vertical side (14), the outermost right vertical side side (16), the outer side lower side street side (17) and the car outer side left side vertical side The width of (18) may be the same. For example, the width of these sides may be 8.5 mm, the thickness may be 0.7 mm, and the cross-sectional area may be 5.95 mm ² . For a side having a cross-sectional area of this size, the design allowable current can be approximately 30A (ampere). Here, the width may be 8.2 ~ 8.7mm and the thickness may be 9.7 ~ 9.9mm.

And the innermost shopping street side 19 may have a smaller width than the outermost dominant street side 12 . For example, since the width of this side is 6 mm and the thickness is 0.7 mm, the cross-sectional area may be 4.2 mm ² . Here, since the innermost shopping street side 19 is electrically connected to the innermost shopping street side 30 having the same cross-sectional area in the (B) type flat plate coil 20 stacked below as in FIG. 7 , the innermost shopping street side ( 19) and the innermost shopping street 30 may have an approximate design allowable current of 50A. Here, the width of the outermost shopping street side 15 may be substantially wider than the widths of other sides in order to match the overall size of the (B)-type flat plate coil 20 and the (C)-type flat plate coil 40 . In addition, the width may be 5.7 ~ 6.3mm, and the thickness may be 9.7 ~ 9.9mm.

Next, the (B)-type flat plate coil 20 is refracted in a clockwise direction from the upper left side to have a shape of a two-winding structure. Due to this shape, the connection part 21 of the outermost end, the outermost shopping street side 22, the outermost dominant street side 23, the outermost lower street side 24, the outermost seat vertical side 25, the car outer side top It may include a roadside 26 , a right side of the vehicle 27 , a side below the vehicle side 28 , a vertical side of the vehicle exterior side 29 and an innermost side of the shopping street 30 .

Here, the connection part 21 is not located on the same line as the connection terminal 11 in the form in which the coils are stacked as in the lower part of FIG. It may be positioned inwardly by a certain length from the end to be connected. Referring to FIG. 2 , it may be positioned from the left end to the right by a predetermined length. In addition, as shown in FIG. 5 , the connection part 21 protrudes outward than the outermost shopping street side 22 for electrical connection of the connection units 41 , and may have the same or different width as the outermost shopping street side 22 .

In addition, the width of the outermost shopping street side 22 to the outer seat side vertical side 29 is 8.5 mm, the thickness is 0.7 mm, and the cross-sectional area may be 5.95 mm ² . For a side having a cross-sectional area of this size, the design allowable current can be approximately 30A (ampere). Here, the width may be 8.2 ~ 8.7mm and the thickness may be 9.7 ~ 9.9mm.

And the innermost shopping street side 30 may have a smaller width than the outermost shopping street side 22 . For example, the width of this side may be 6 mm, the thickness may be 0.7 mm, and the cross-sectional area may be 4.2 mm ² . Here, since the innermost shopping street side 30 is electrically connected to the innermost shopping street side 19 having the same cross-sectional area in the (A) type flat plate-type coil 10 stacked thereon as in FIG. 7 , the innermost shopping street side 30 ) and the innermost shopping street 19 may have an approximate design allowable current of 50A. In addition, the width may be 5.7 ~ 6.3mm, and the thickness may be 9.7 ~ 9.9mm.

Finally, the (c)-type flat plate coil 40 is refracted counterclockwise starting from the upper left corner to have a double-winding structure. Due to this shape, the connection part 41 of the outermost end, the outermost seat vertical side 42, the outermost lower street side 43, the outermost right vertical side 44, the outermost shopping street side 45, the car outer seat A vertical side 46 , a lower side street side 47 , an outside side side street side 48 , and an innermost side street side 49 may be provided.

Here, the connection part 41 is positioned inward by a certain length from the end so that it is connected on the same line with the other connection part 21 without being located on the same line as the connection terminal 11 in the form of stacked coils as in the lower part of FIG. 7 . can be Referring to FIG. 2 , it may be positioned from the left end to the right by a predetermined length. In addition, as shown in FIG. 5 , the connection part 41 protrudes outward than the outermost shopping street side 45 for electrical connection of the connection parts 21 , and may have the same or different width as the outermost vertical side 42 .

In addition, the outermost left vertical side 42, the outermost lower street side 43, the outermost right side street 44, the car outer side seat vertical side 46, the car outer side lower street side 47 and the car outer right vertical side 48 may have a width of 8.5 mm, a thickness of 0.7 mm, and a cross-sectional area of 5.95 mm ² . For a side having a cross-sectional area of this size, the design allowable current can be approximately 30A. Here, the width may be 8.2 ~ 8.7mm and the thickness may be 9.7 ~ 9.9mm.

And the innermost shopping street side 49 may have a smaller width than the outermost sitting vertical side 42 . For example, the width of the innermost shopping street 49 may be 6 mm, the thickness may be 0.7 mm, and the cross-sectional area may be 4.2 mm ² . Here, the innermost shopping street side 49 is electrically connected to the innermost shopping street side 19 having the same cross-sectional area in the (A) type flat plate coil 10 stacked below as in FIG. 7 , so the innermost shopping street side ( 49) and the innermost shopping street 19 may have an approximate design allowable current of 50A. In addition, the width may be 5.7 ~ 6.3mm, and the thickness may be 9.7 ~ 9.9mm. In addition, the width of the outermost shopping street side 15 may be wider than the widths of other sides in order to approximately match the overall size of the (B) type flat plate coil 20 and the (C) type flat plate coil 40 .

Meanwhile, as another example, as shown in FIG. 3 , the flat coil C of (A) type 10, (B) type 20 and (C) type 40 may be manufactured in a three-winding structure. The flat coil (C) may preferably be manufactured in a shape wound in a substantially rectangular shape or a chamfered rectangular shape on a plane, and as another example, may be manufactured in an approximately circular or polygonal wound shape, and in the case of polygons, chamfering treatment it might be The width of each side of these flat coils C may be the same as that of FIG. 2 or may be thinner in proportion to that of FIG. 2 . In particular, the width of the outermost shopping street, the width of the innermost shopping street, and other widths may be the same or thinner in proportion to that of FIG. 2 .

Also, in the case of the three-winding flat coil C, compared with the twice-wound shape of FIG. 2 , the intermediate sides may be further provided with one additional winding between the outer side of the vehicle and the innermost side of the vehicle. Of course, the number of intermediate sides may also increase proportionally according to the number of windings of the coil.

Accordingly, the flat coil C of the three-winding structure can provide a larger inductance in proportion to the square of the number of turns than the two-winding structure as well as the single-winding structure or the 'C'-shaped winding structure.

In this way, the flat coil (C) according to the present invention can be wound 2 times and 3 times, as well as more times.

<Reactor>

On the other hand, as shown in FIG. 4 , a reactor having a flat coil according to a preferred embodiment of the present invention includes a coil assembly 100 in which a flat coil C is assembled, and a case in which the coil assembly 100 is incorporated. (200) may be included. In addition, the reactor may further include a ferromagnetic part in which a ferromagnetic material is disposed in the central space of the coil assembly 100 , and a plurality of magnetic paths extending from the ferromagnetic material to surround the coil assembly 100 are disposed. Here, for the cooling of the coil assembly 100, the case 200 and the strong magnetic field, which are made of a cooling material and structure including aluminum, are installed in the same or similar manner to that of the conventional one, and have the same or similar function, so if necessary, simply can be explained Hereinafter, the coil assembly 100 will be described by taking as an example a structure in which the upper coil assembly 110 and the lower coil assembly 120 are arranged in parallel as in FIG. 5 . Of course, it may be arranged to have a serial structure.

As shown in Figs. 4 and 5, the coil assembly 100 is an upper coil assembly 110 and a lower coil assembly 120, for example, each of four plate-type coils C overlapping each other, and arranged in a parallel structure. can In addition, the upper coil assembly 110 or the lower coil assembly 120 may be stacked in which the insulating member 50 and the coil are alternately disposed.

Here, in the upper coil assembly 110 or the lower coil assembly 120 as shown in FIG. 7 , the uppermost (A) type flat plate coil 10 and the second uppermost (C) type flat plate coil 40 are the innermost shopping street side ( 19 and 49) are electrically connected, and the (c)-type flat coil 40 and the (b)-type flat coil 20 of the second upper level are electrically connected to the connecting portions 41 and 21, and the difference The lower (B) type flat plate coil 20 and the lowermost (A) type flat plate coil 10 may have innermost shopping street sides 30 and 19 electrically connected to each other. Due to this, the start point and the end point of the flat coils C are connected to each other, so that the whole can be electrically connected in a line. This may be possible because the shape is wound spaced apart from each other. At this time, the electrical connection may be made by welding, for example, may be soldering welding or brazing welding.

When the flat coils (C) are stacked in this way, the uppermost (A) type flat coil 10 is disposed such that the connection terminal 11 is located on the left, and the (C) type flat coil 40 below it And (B) type flat plate coil 20 is arranged so that the connection parts 41 and 21 are located on the same line on the right side, and the lowest (A) type flat plate type coil 10 has the connection terminal 11 on the right side. It can be arranged to be positioned. At this time, the connection parts 41 and 21 of the (c) type flat plate coil 40 and the (b) type flat plate coil 20 are connected to the connection terminal 11 of the lowermost (A) type flat plate coil 10 and It may be positioned to the left by a predetermined length so as not to be positioned on the same line. At this time, the uppermost (A) type flat plate coil 10 and the lowest (A) type flat coil 10 have the same shape, except that the connection terminals 11 are positioned on the left and right so that they are symmetrical to each other. can be

In addition, in a state in which the upper coil assembly 110 and the lower coil assembly 120 of the same stacked structure are stacked up and down, the uppermost (A)-type flat plate coil 10 and the lower coil assembly of the upper coil assembly 110 The connection terminals 11 and 11 of the uppermost (A)-type plate-type coil 10 at the uppermost part of 120 may be electrically connected to each other by the first sleeve 130 . Next, the connection terminals 11 and 11 of the lowermost (A)-type flat coil 10 of the upper coil assembly 110 and the lowermost (A)-type flat coil 10 of the lower coil assembly 120 are It may be electrically connected by the second sleeve 131 . The first sleeve 130 and the second sleeve 131 may induce an external current to flow into and out of the coil. Due to this, the upper coil assembly 110 and the lower coil assembly 120 may be connected to each other in a parallel structure.

The insulating member 50 is additionally disposed on the uppermost surface and the lowermost surface, and is a thin film having better insulating properties than air, and may be, for example, a film.

Meanwhile, a case in which eight flat coils C of the upper coil assembly 110 or the lower coil assembly 120 are stacked will be described as in FIG. 8 . In this case, for convenience of description, the coils will be described by referring to numbers 1 to 8 from top to bottom in the drawings.

In the upper coil assembly 110 or the lower coil assembly 120, the first (A) type flat plate coil 10 and the second (C) type flat plate coil 40 have the innermost shopping street sides (19, 49) may be electrically connected. In addition, the second (c)-type flat plate coil 40 and the third (b)-type flat plate coil 20 may be electrically connected to the connecting portions 41 and 21 . In addition, the third (B) type flat plate coil 20 and the fourth (B) type flat plate coil 20 may be electrically connected to the innermost shopping streets 30 and 30 . In addition, the connection parts 21 and 41 may be electrically connected to the No. 4 (B) type flat plate coil 20 and the No. 5 (C) type flat plate coil 40 . In addition, No. 5 (c) type flat plate coil 40 and No. 6 (c) type flat plate coil 40 may be electrically connected to innermost shopping streets 49 and 49 . In addition, the connection parts 41 and 21 may be electrically connected to the (c) type flat coil 40 of No. 6 and the (b) type flat coil 20 of No. 7 . In addition, the innermost shopping street sides 30 and 19 of the No. 7 (B) type flat plate coil 20 and the No. 8 (A) type flat plate coil 10 may be electrically connected to each other.

When the flat coils C are stacked in this way, the first (A) type flat coil 10 may be disposed such that the connection terminal 11 is located on the left side. In addition, No. 2 (c)-type flat plate coil 40 and No. 3 (b)-type flat plate coil 20 may be arranged such that the connection parts 41 and 21 are located on the right side. In addition, No. 4 (b)-type flat plate coil 20 and No. 5 (c)-type flat plate coil 40 may be arranged such that the connection parts 21 and 41 are located on the left side. In addition, the No. 6 (c) type flat plate coil 40 and the No. 7 (b) type flat plate coil 20 may be disposed such that the connection parts 41 and 21 are located on the right side. And the (A) type flat coil 10 of No. 8 may be arranged such that the connection terminal 11 is located on the right side. At this time, when the connection terminals 11 are symmetrically disposed left and right or the connection parts 21 and 41 are symmetrically disposed left and right, the flat coil C may be turned over to be symmetrically disposed.

In this way, the coil assembly 100 puts (A)-type flat plate coils 10 at the uppermost and lowermost positions, (A)-type flat-plate coils 10, (B)-type flat-plate coils 20 and (C) )-shaped flat coil 30, the connection parts 21 and 41 or the innermost shopping street sides 30 and 49 are alternately connected, so that the start and end points of the flat coils C are connected to each other so that the whole is electrically in a line It can be a connected structure. If this structure is maintained, the number of (B)-type flat plate coils 20 and (C)-type flat plate coils 30 can be increased or decreased as needed.

On the other hand, ballast water generally filled in the ship can help to enable safe navigation by minimizing the change in the center of gravity of the ship due to loading and unloading of cargo. That is, when cargo is loaded heavily or lightly loaded on a ship, by filling it with an appropriate ballast water, the center of gravity of the ship can be positioned below the sea level so that the ship can safely navigate.

Since the ballast water is filled or discharged in different regions while sailing, various marine organisms or pathogens from one region may be transported to another region, thereby disturbing the environment and ecosystem between regions. Therefore, there is a demand for water purification to sterilize marine organisms and pathogens when filling or discharging ballast water.

In this way, according to the invention, a reactor equipped with a flat coil (C) having a structure of two or more windings is used in a facility (usually referred to as BWTS: Ballast Water Treatment System or BWMS: Ballast Water Management System) for treating ballast water for purified water. can

As described above, those skilled in the art to which the present invention pertains will be able to understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the claims described later rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be interpreted as being included in the scope of the present invention. do.

10: (A) type flat plate coil
11: Connection terminal 12: Outermost right side
13: outermost lower street side 14: outermost left street side
15: On the outermost shopping street 16: On the outer side of the car
17: Outside the car side down the street 18: Outside the car side the vertical side
19: By the innermost shopping street
20: (B) type flat plate coil
21: Connection part 22: Outermost shopping street side
23: Outer most dominant road side 24: Outermost lower street side
25: On the outermost side of the vertical road 26: On the side of the shopping street on the outside of the car
27: On the side of the right side of the car 28: On the side of the side of the lower side of the vehicle
29: On the side of the seat on the outside of the car 30: On the side of the innermost shopping street
40: (C) type flat plate coil
41: connection part 42: outermost seat vertical side
43: Outermost lower street side 44: Outermost dominant street side
45: Outermost shopping street side 46: Outside car seat vertical side
47: On the outside of the car, on the side of the road 48: On the side of the right side of the car
49: By the innermost shopping street
50: insulating member
100: coil assembly
110: upper coil assembly 120: lower coil assembly
130: first sleeve 131: second sleeve
200: case.
C: Flat coil.

Claims (15)

In a reactor equipped with a flat coil (C),
The flat coil (C) is provided with outermost sides, car outer sides and innermost sides while the plate-shaped material is wound while being spaced apart from each other on a plane, and optionally additionally provided with intermediate sides wound at least once. It is a structure with two windings,
A plate-type coil for a reactor, characterized in that it provides a larger inductance than a single-wound structure or a 'C'-shaped structure in proportion to the square of the number of turns in the flat-plate coil (C) of the at least two-winding structure.
In claim 1,
The flat coil (C) is a quadrangle or a chamfered quadrangle in plan view, and extends from the connection terminal 11 and the connection terminal 11 to the outermost dominant side 12, the outermost lower horizontal side 13, and the most The outer left vertical side (14), the outermost shopping street side (15), the outer right vertical side of the car (16), the outer side of the lower side of the vehicle (17), the outer side of the left side vertical side (18) and the innermost side of the shopping street side (19) A plate-type coil for a reactor, characterized in that it is a (a)-type flat-plate-type coil (10) that is provided, optionally further provided with intermediate sides, and has a different width along each side.
In claim 2,
The connection terminal 11 extends and protrudes from the outermost vertical side 12,
The outermost right vertical side 12, the outermost lower street side 13, the outermost left vertical side 14, the car outer right vertical side 16, the car outer lower side street side 17 and the car outer left side vertical side ( 18) has the same width,
The innermost shopping street side 19 is narrower than the outermost dominant street side 12,
The middle side is a flat coil for a reactor, characterized in that the same as the width of the outermost dominant side (12).
In claim 1,
The flat coil (C) is a quadrangle or a chamfered quadrangle in plan view, and extends from the connection part 21 and the connection part 21 to the outermost shopping street 22, the outermost dominant side 23, and the outermost lowermost side. Roadside (24), outermost left vertical side (25), car outer side shopping street side (26), car outer side right side street side (27), car outer side lower side street side (28), outer seat side vertical side (29) and innermost side A plate-type coil for a reactor, characterized in that it is a (B)-type flat-plate-type coil (20) having a Sanga-ro side (30), optionally further provided with intermediate sides, and having a different width along each side.
In claim 4,
The connection part 21 has a shape protruding outward from the outermost shopping street side 22,
The outermost shopping street side 22, the outermost right side street 23, the outermost lower side street side 24, the outermost left side street side 25, the car outer side shopping street side 26, the car outer side right side street side (27) ), the width of the lower side of the vehicle (28) and the side of the vehicle side (29) are the same,
The innermost shopping street side 30 is narrower than the outermost shopping street side 22,
The intermediate sides are the same as the width of the outermost dominant side (12).
In claim 1,
The flat coil (C) is a quadrangle or a chamfered quadrangle in plan view, and extends from the connecting portion 41, the connecting portion 41, the outermost left vertical side 42, the outermost lower horizontal side 43, the outermost dominant It has a road side 44, an outermost shopping street side 45, a car outer seat vertical side 46, a car outer side lower street side 47, a car outer right side street side 48 and an innermost shopping street side 49, , optionally further provided with intermediate sides, and a (multi)-type flat-plate-type coil (40) having a different width along each side.
In claim 6,
The connection part 41 protrudes outwardly from the outermost seat longitudinal side 42,
The outermost left vertical side 42, the outermost lower horizontal side 43, the outermost right vertical side 44, the outer left vertical side 46, the outer side lower horizontal side 47 and the outer right vertical side of the vehicle ( 48) is the same width,
The innermost shopping street side 49 is narrower than the outermost seat vertical side 42,
The intermediate sides are the same as the width of the outermost dominant side (12).
in the reactor,
The flat plate coil (C) of any one of claims 1 to 7 is stacked, and each flat plate coil (C) is electrically connected to each other in a line, so that the lowest plate coil (C) in the uppermost plate coil (C) ), and the coil assembly 100 is manufactured by interposing an insulating member 50 between the flat coils (C). A reactor including a flat coil.
In claim 8,
The coil assembly 100 includes (A)-type flat plate coils 10 disposed at the uppermost and lowermost positions, (B)-type flat plate coils 20 and (C)-type flat plate coils 30 disposed in the middle. A reactor including a plate-type coil made of a.
In claim 8,
The coil assembly 100 is a reactor including a plate-type coil comprising an upper coil assembly 110 and a lower coil assembly 120 that are stacked and electrically connected in parallel.
In claim 10,
The coil assembly 100 is a connection terminal 11 of the uppermost (A) type flat coil 10 of the upper coil assembly 110 and the uppermost (A) type flat coil 10 of the lower coil assembly 120, 11), the first sleeve 130 installed to be electrically connected, the lowermost (A)-type flat plate coil 10 of the upper coil assembly 110, and the lowermost (A)-type flat plate of the lower coil assembly 120 Further comprising a second sleeve 131 installed to connect the connection terminals 11 and 11 of the mold coil 10 to electrically connect,
A reactor including a flat coil in which the upper coil assembly 110 and the lower coil assembly 120 have a parallel structure by the first sleeve 130 and the second sleeve 131 .
In claim 9,
The upper coil assembly 110 or the lower coil assembly 120, when four flat coils (C) are stacked, the uppermost (A)-type flat-plate coil 10 and the second uppermost (C)-type flat-type coil (40) is the innermost shopping street sides (19, 41) are electrically connected, the (c) type flat coil 40 of the second upper and the (B) type flat coil 20 of the lower level are the connection parts 41, 21) are electrically connected, and the lowermost (B) type flat plate coil 20 and the lowest (A) type flat plate coil 10 are electrically connected to the innermost shopping street sides 30 and 19, so that all A reactor including a plate-type coil formed by electrically connecting the plate-type coils (C) in series.
In claim 12,
In the upper coil assembly 110 or the lower coil assembly 120, the uppermost (A)-type flat plate coil 10 is disposed so that the connection terminal 11 is located on the left, and the (C)-type flat plate-type coil 10 below it The coil 40 and the (B)-type flat-plate-type coil 20 are arranged so that the connection parts 41 and 21 are located on the same line on the right side, and the lowermost (A)-type flat-plate-type coil 10 has a connection terminal 11 ) is placed to the right,
The connection parts 41 and 21 of the (c) type flat plate coil 40 and the (b) type flat plate coil 20 are the same as the connection terminals 11 of the lowermost (A) type flat plate coil 10 A reactor including a flat coil, which is positioned to the left by a certain length so as not to be positioned on a ship.
In claim 9,
The upper coil assembly 110 or the lower coil assembly 120, when eight flat coils C are stacked from top to bottom, the first (A) type flat plate coil 10 and the second (C) type The flat coil 40 is electrically connected to the innermost street sides 19 and 49, and the second (c) type flat plate coil 40 and the third (b) type flat plate coil 20 are connected to the connecting part ( 41 and 21) are electrically connected, and the innermost shopping street sides 30 and 30 of the third (B) type flat plate coil 20 and the fourth (B) type flat plate coil 20 are electrically connected and , the connecting portions 21 and 41 of the (b)-type flat plate coil 20 of No. 4 and the (c)-type flat plate coil 40 of No. 5 are electrically connected, and the No. 5 (c)-type flat plate coil 40 ) and the innermost street sides 49 and 49 of the (c) type flat plate coil 40 of No. 6 are electrically connected, and the (c) type flat plate coil 40 of No. 6 and (b) type flat plate of No. 7 The connection parts 41 and 21 of the type coil 20 are electrically connected, and the innermost shopping street 30 of the (B) type flat plate coil 20 of No. 7 and the (A) type flat plate coil 10 of No. 8 , 19) are electrically connected to a reactor including a plate-type coil.
In claim 14,
In the upper coil assembly 110 or the lower coil assembly 120, No. 1 (A) type flat plate coil 10 has a connection terminal 11 located on the left, and No. 2 (C) type flat plate coil 40 ) and No. 3 (B) type flat plate coil 20, the connection parts 41 and 21 are located on the right, and No. 4 (B) type flat plate coil 20 and No. 5 (C) type flat plate coil ( 40), the connection parts 21 and 41 are located on the left, and the 6 (c) type flat coil 40 and 7 (b) type flat coil 20 have the connection parts 41 and 21 on the right. is located, and in the (A) type flat coil 10 of No. 8, the connection terminal 11 is located on the right side,
The connection parts 41 and 21 of the (c) type flat coil 40 of No. 2 and 6 and the (b) type flat coil 20 of No. 3 and 7 are the (A) type flat coil of No. 8 ( 10) is located on the left by a certain length so as not to be located on the same line as the connection terminal 11,
The connection parts 21 and 41 of the No. 4 (B) type flat plate coil 20 and No. 5 (C) type flat plate coil 40 are the connection terminals of the No. 1 (A) type flat plate coil 10 ( 11) A reactor including a flat coil, which is positioned to the right by a certain length so that it is not located on the same line.

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