JP2020004914A - Stationary induction apparatus - Google Patents

Abstract

To obtain a stationary induction apparatus that can improve cooling efficiency of a winding.SOLUTION: A stationary induction apparatus 100 includes a cylindrical winding 3-1 configured by laminating an electric wire and an insulating member wound around a core leg 1c1 so as to surround an outer peripheral surface of the core leg 1c1, and a columnar member 5 provided between insulating members adjacent in a radial direction of the winding 3-1 such that a refrigerant flow path 6 penetrating from a lower end to an upper end of the winding 3-1 is formed. The insulating member in contact with a radial inner surface of the columnar member 5 protrudes from the lower end of the winding 3-1 to a lower side of the winding 3-1, and a first insulating portion 4-31 is provided so as to surround a second surface 12 other than a first surface 11 facing the core leg 1c2 in a C-shape.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a stationary inductor including an iron core and a winding provided on the iron core.

  Patent Literature 1 discloses a technique for improving cooling efficiency of a winding provided in a stationary inductor installed inside a casing filled with a cooling medium. In the stationary inductor disclosed in Patent Literature 1, a plurality of columnar members extending from the lower end to the upper end of the winding are provided inside a cylindrical winding provided around the iron core leg of the iron core. Is arranged, a gap is formed between the columnar members. The lower end of the columnar member protrudes below the winding from the lower end of the winding, and a strip is provided at the protruding portion. By providing the columnar member and the strip, a coolant flow path is formed in the winding from the lower end to the upper end of the winding. Since the coolant passage extends only at the protruding portion of the columnar member, low-temperature coolant existing near the bottom plate of the housing is taken into the coolant passage, and the winding is effectively cooled.

Japanese Utility Model Laid-Open No. 57-022219

  However, in the technology disclosed in Patent Literature 1, since the column-shaped members and the strips form a duct-shaped refrigerant passage protruding toward the lower end side of the winding, the housing is cooled by the side plate of the housing and Even when the low-temperature cooling medium descending toward the bottom plate reaches the lower end of the winding, the strip prevents the cooling medium from entering the refrigerant flow path. Therefore, the technique disclosed in Patent Literature 1 has a problem that the cooling efficiency of the winding cannot be improved using a low-temperature cooling medium cooled by the side plate of the housing.

  The present invention has been made in view of the above, and an object of the present invention is to provide a stationary inductor that can improve the cooling efficiency of a winding.

  In order to solve the above-described problems and achieve the object, a stationary inductor according to the present invention includes a first core yoke and a second core yoke disposed below the first core yoke at a certain distance from the first core yoke. An iron core yoke, a first iron leg extending from the first iron yoke toward the second iron yoke, and a first iron leg extending from the first iron yoke toward the second iron yoke and spaced a certain distance from the first iron leg And a second iron core disposed in parallel with the iron core. The stationary inductor includes a cylindrical winding formed by laminating an electric wire wound around the first core leg and an insulating member so as to surround the outer peripheral surface of the first core leg, and a diameter of the winding. And a flow path forming member provided between the insulating members adjacent in the direction and forming a refrigerant flow path penetrating from the lower end to the upper end of the winding. The insulating member that is in contact with the radially inner surface of the flow path forming member protrudes below the winding from the lower end of the winding and faces the second core leg of the outer peripheral surface of the first core leg. A first insulating portion surrounding a surface other than the one surface in a C-shape is provided.

  ADVANTAGE OF THE INVENTION According to this invention, there exists an effect that the cooling efficiency of a winding can be improved.

The figure which shows the stationary inductor which concerns on embodiment of this invention, and the housing | casing in which a stationary inductor is provided. Perspective view of the iron core shown in FIG. 1 The figure which shows the state in which the winding was provided in each of the three iron core legs shown in FIG. IV-IV arrow sectional drawing shown in FIG. VV arrow sectional drawing shown in FIG. FIG. 2 is a diagram for explaining a flow of a cooling medium generated when power is supplied to the winding shown in FIG. 1. The figure which shows the stationary inductor which concerns on a comparative example, and the housing | casing in which the said static inductor is provided. Partial enlarged view of a stationary inductor according to a first modification of the embodiment of the present invention. The figure which shows the stationary inductor which concerns on the 2nd modification of embodiment of this invention, and the housing | casing in which a stationary inductor is provided. The figure which shows the state in which the winding was provided in each of the three iron core legs shown in FIG. FIG. 9 is a cross-sectional view of the XZ plane including the windings and the third insulating portion illustrated in FIG. 9. FIG. 9 is a view for explaining a flow of a cooling medium generated when power is supplied to the windings shown in FIG. 9. The figure which shows the stationary inductor which concerns on the comparative example of the 2nd modification shown in FIG. 9, and the housing | casing in which the said stationary inductor is provided inside. Partial enlarged view of a stationary inductor according to a third modification of the embodiment of the present invention.

  Hereinafter, a stationary inductor according to an embodiment of the present invention will be described in detail with reference to the drawings. It should be noted that the present invention is not limited by the embodiment.

Embodiment.
FIG. 1 is a diagram showing a stationary inductor according to an embodiment of the present invention and a housing in which the stationary inductor is provided. The stationary inductor 100 according to the embodiment is provided inside the housing 200. Stationary inductor 100 is a three-phase transformer including iron core 1 and three windings 3-1, 3-2, and 3-3. In FIG. 1, in the left-handed XYZ coordinates, the vertical direction of the stationary inductor 100 is the X-axis direction, the arrangement direction of the three windings 3-1, 3-2, 3-3 is the Z-axis direction, and the X-axis A direction orthogonal to both the direction and the Z-axis direction is defined as a Y-axis direction. The X-axis direction is equal to the vertical direction of the stationary inductor 100 and the iron core 1 and is equal to the vertical direction of each of the three windings 3-1, 3-2, and 3-3. The vertical direction is equal to the vertical direction. The above-described axial directions are the same in each of FIGS. Hereinafter, when it is not necessary to distinguish each of the three windings 3-1, 3-2, and 3-3, they are simply referred to as windings 3.

  The inside of the housing 200 is filled with a cooling medium 201 for cooling the winding 3. The cooling medium 201 is an insulating oil or an insulating oil that convects inside the housing 200. The insulating oil or the oil for insulation is one to seven kinds of oils described in JIS2320, for example, insulating oil mainly composed of mineral oil, alkylbenzene, polybutene, alkylnaphthalene, alkyldiphenylalkane, silicone oil and the like. Oil. The housing 200 includes a top plate 202 provided above the stationary inductor 100, a bottom plate 203 provided below the stationary inductor 100, and a side plate 204 provided on a side surface of the stationary inductor 100. One end of the side plate 204 in the vertical direction is fixed to the top plate 202. The other end in the vertical direction of the side plate 204 is fixed to the bottom plate 203. Examples of the material of the top plate 202, the bottom plate 203, and the side plate 204 include metals such as copper alloy, cast iron, steel, iron alloy, aluminum alloy, and austenitic stainless alloy. The housing 200 only needs to have a structure capable of radiating the temperature of the cooling medium 201 heated by the heat generated in the windings 3 to the outside of the housing 200 and preventing the cooling medium 201 from leaking outside. The shape of the housing 200 is not limited to the shape shown in the illustrated example.

  A first insulating portion 4-31 and a second insulating portion 4-32 are provided below the winding 3-1. A first insulating portion 4-31 and a second insulating portion 4-32 are also provided below the winding 3-3. A first insulating portion 4-31 'and a second insulating portion 4-32 are provided below the winding 3-2. In the stationary inductor 100, at least one of the winding 3-1 and the winding 3-3 may be provided with the first insulating portion 4-31 and the second insulating portion 4-32.

  Hereinafter, the structure of the winding 3, the first insulating portion 4-31, and the like will be described in detail with reference to FIGS. FIG. 2 is a perspective view of the iron core shown in FIG. FIG. 3 is a diagram showing a state in which windings are provided on each of the three iron legs shown in FIG. FIG. 4 is a sectional view taken along the line IV-IV shown in FIG. FIG. 5 is a sectional view taken along the line VV shown in FIG.

  The iron core 1 may be, for example, a combination of an E core formed by stacking a plurality of steel sheets formed in an “E” shape in the Y-axis direction and an I core formed in an “I” shape. A plurality of steel plates having two through holes may be stacked in the Y-axis direction. The core 1 includes a core yoke 1a1, a core yoke 1a2, and three core legs 1c1, 1c2, and 1c3. Each of the core yokes 1a1 and 1a2 extends in the Z-axis direction and is arranged apart from each other in the X-axis direction. Three iron core legs 1c1, 1c2, 1c3 are provided between the iron core yokes 1a1 and 1a2. Each of the three iron legs 1c1, 1c2, 1c3 extends in the X-axis direction and is arranged apart from each other in the Z-axis direction. One end of the iron core leg 1c1 in the X-axis direction is connected to the iron core yoke 1a1. The other end in the X-axis direction of the iron core leg 1c1 is connected to the iron core yoke 1a2. Thereby, the three iron core legs 1c1, 1c2, 1c3, the iron core yokes 1a1, and the iron core yokes 1a2 are magnetically connected. Hereinafter, when it is not necessary to distinguish each of the three iron core legs 1c1, 1c2, and 1c3, they are simply referred to as iron core legs 1c.

  The winding 3-1 is provided on the iron core leg 1c1. As shown in FIG. 5, the winding 3-1 includes the electric wire 2, the columnar member 5 as a flow path forming member, and the plurality of insulating members 4-1, 4-2, 4-3, 4-4. Prepare. Hereinafter, when it is not necessary to distinguish each of the plurality of insulating members 4-1, 4-2, 4-3 and 4-4, they are simply referred to as insulating members 4. The electric wire 2 is a conductive wiring such as a copper wire, an aluminum wire, and an aluminum alloy wire. The insulating member 4 is, for example, insulating paper. The thickness of the insulating paper is set, for example, to a dimension from 0.1 mm to 0.8 mm. Note that the insulating member 4 may be a film-shaped member manufactured using an insulating material, and is not limited to insulating paper.

  The winding 3-1 is formed by laminating an electric wire 2 wound around the iron core leg 1c1 and an insulating member in multiple layers so as to surround the outer peripheral surface 1c11 of the iron core leg 1c1, and is formed in a cylindrical shape. In the example illustrated in FIG. 5, the electric wire 2, the columnar member 5, and the plurality of insulating members 4 are arranged such that the insulating member 4-1, the electric wire 2, and the insulating member 4 extend from the inner surface 3 </ b> I of the winding 3-1 toward the outer surface 30. 4-2, the columnar member 5, the insulating member 4-3, the electric wire 2, and the insulating member 4-4 are arranged in this order. The inner side surface 3I of the winding 3-1 is a surface facing the iron core 1c1 of the winding 3-1. Facing means that the two objects are in a state of seeing each other.

  The columnar member 5 is provided between the insulating member 4-2 and the insulating member 4-3. Each of the plurality of columnar members 5 is a rod-shaped member extending from the lower end 3D of the winding 3-1 toward the upper end 3U. The plurality of columnar members 5 are arranged apart from each other in the direction in which the electric wire 2 extends. The direction in which the electric wire 2 extends is equal to the direction indicated by the arrow D1 in FIG. The columnar member 5 is a member for forming a plurality of refrigerant channels 6 for passing the cooling medium 201 inside the winding 3-1. The columnar member 5 may be manufactured in a rod shape by die casting using an insulating resin such as silicone rubber, polyisobutylene rubber, or acrylic rubber, or may be made of aluminum alloy, austenitic stainless alloy, copper alloy, cast iron, steel, or iron. It may be manufactured in a rod shape by die casting using a metal such as an alloy. Each of the plurality of refrigerant channels 6 penetrates from the lower end 3D of the winding 3-1 toward the upper end 3U.

  Note that the position of the columnar member 5 is not limited to the position shown in the illustrated example as long as the refrigerant flow path 6 can be provided inside the winding 3-1. Further, the length of the columnar member 5 in the X-axis direction is shorter than the length from the upper end 3U to the lower end 3D of the winding 3-1 if the refrigerant flow path 6 can be provided inside the winding 3-1. And may be longer than the length. The number of layers of the electric wire 2 and the insulating member 4 is not limited to the illustrated example as long as the columnar member 5 can be provided inside the winding 3-1.

  The insulating member 4-2 is in contact with the inner side surface 5I of the columnar member 5 in the radial direction of the winding 3-1. The radial direction is equal to the direction in which the imaginary line D2 connecting the inner surface 3I and the outer surface 30 of the winding 3-1 extends on the YZ plane. A first insulating part 4-31 is provided on the insulating member 4-2. The first insulating portion 4-31 protrudes from the lower end 3D of the winding 3-1 to the lower side of the winding 3-1 and, among the outer peripheral surfaces 1c11 of the iron core 1c1, the iron core leg serving as the second iron core leg. The YZ section is a C-shaped member so as to surround the second surface 12 which is a surface other than the first surface 11 facing 1c2. The C shape means a shape in which a part of the annular member is opened, and includes an arc shape, a U shape, and the like. Since the core leg 1c1 shown in FIG. 4 has a square YZ section, one first surface 11 and three second surfaces 12 are formed on the iron core leg 1c1. The first insulating portion 4-31 is arranged so as to face the three second surfaces 12. The first insulating portion 4-31 only needs to be arranged so that at least a part thereof faces the three second surfaces 12. For example, the upper region of the first insulating portion 4-31 above the iron core yoke 1a2. May be present on a normal line perpendicular to the second surface 12 of the iron core leg 1c1.

  The insulating member 4-2 is provided with a second insulating portion 4-32 as shown in FIGS. The second insulating portion 4-32 is a member provided between an end of the first insulating portion 4-31 on the YZ plane and the side surface 22 of the iron core yoke 1a2. The side surface 22 of the iron core yoke 1a2 is an end surface on the Y axis direction side of the iron core yoke 1a2. The second insulating portion 4-32 may be formed integrally with the insulating member 4-2 and the first insulating portion 4-31, or may be manufactured separately from the insulating member 4-2 and the first insulating portion 4-31. It may be attached after being done. Similarly to the first insulating portion 4-31, the second insulating portion 4-32 projects below the lower end 3D of the winding 3-1 and below the winding 3-1. Further, the second insulating portion 4-32 extends from the first insulating portion 4-31 toward the iron core yoke 1a2 along the direction in which the electric wire 2 extends, and faces the first surface 11 of the iron core leg 1c1. The second insulating portion 4-32 only needs to be arranged so that at least a part thereof faces the first surface 11 of the iron core leg 1c1. For example, the second insulating portion 4-32 of the iron core yoke 1a2 of the second insulating portion 4-32 may be used. Even if the tip on the side surface 22 side does not exist on the normal perpendicular to the first surface 11 of the iron core leg 1c1, it is sufficient that the tip exists at a position where the first surface 11 of the iron core leg 1c1 can be seen.

  The winding 3-2 is provided on the iron core 1c2. The winding 3-2 is formed by laminating the electric wire 2 and the insulating member 4 in a multi-layered form, like the winding 3-1. The winding 3-2 is provided with a plurality of columnar members 5, a first insulating portion 4-31 ', and a second insulating portion 4-32. The first insulating portion 4-31 'provided on the winding 3-2 faces the second surface 14 other than the first surface 13 facing the iron core 1c1 or the iron core 1c3 in the outer peripheral surface 1c21 of the iron core 1c2. Is provided. The second insulating portion 4-32 provided on the winding 3-2 extends from the first insulating portion 4-31 'provided on the winding 3-2 toward the core yoke 1a2 along the direction in which the electric wire 2 extends. At the same time, it faces the first surface 13 of the iron core leg 1c2.

  A winding 3-3 is provided on the iron core leg 1c3. The winding 3-3 is formed in a cylindrical shape by laminating the electric wire 2 and the insulating member 4 in multiple layers, similarly to the winding 3-1. The winding 3-3 is provided so as to surround the outer peripheral surface 1c31 of the iron core leg 1c3. Can be Similarly to the winding 3-1, the winding 3-3 includes a plurality of columnar members 5, a first insulating portion 4-31, and a second insulating portion 4-32. The first insulating portion 4-31 provided in the winding 3-3 is provided at a position facing the second surface 16 other than the first surface 15 facing the iron core 1c2 in the outer peripheral surface 1c31 of the iron core 1c3. The second insulating portion 4-32 provided on the winding 3-3 extends from the first insulating portion 4-31 toward the iron core yoke 1a2 along the direction in which the electric wire 2 extends, and the first surface of the iron core leg 1c3. Facing 15

  Next, a flow of the cooling medium 201 generated when the winding 3 of the stationary inductor 100 is energized will be described with reference to FIG. FIG. 6 is a diagram for explaining the flow of the cooling medium generated when the winding shown in FIG. 1 is energized. In FIG. 6, the cooling medium 201 flowing in the coolant channel 6 formed in the winding 3-1 will be described for simplicity. In addition, FIG. 6 shows only two refrigerant flow paths 6 among the plurality of refrigerant flow paths 6 provided in the winding 3-1 shown in FIG. One of the two refrigerant flow paths 6 shown in FIG. 6 is provided at a position facing the second surface 12 in the Z-axis direction of the iron core leg 1c1 shown in FIG. 4, and the other is provided in FIG. The iron core leg 1c1 is provided at a position facing the second surface 12 in the Y-axis direction. The flow of the cooling medium 201 to the refrigerant flow path 6 formed in the winding 3-3 is the same as the flow of the cooling medium 201 to the refrigerant flow path 6 formed in the winding 3-1. Then, the explanation is omitted.

  When the temperature of the winding 3-1 rises due to energization, the heat of the winding 3-1 is transmitted to the cooling medium 201 existing inside the refrigerant flow path 6, and the temperature of the cooling medium 201 rises. The cooling medium cmh whose temperature has risen to a high temperature is discharged from the upper end 3U of the winding 3-1 to the outside of the winding 3-1. When the heat of the cooling medium cmh is transmitted to the side plate 204 of the housing 200, the temperature of the cooling medium cmh decreases. The cooling medium cmh whose temperature has been lowered by the temperature drop in this way descends toward the bottom plate 203 of the housing 200 as the cooling medium cml. The cooling medium cml that has reached the lower end 3D of the winding 3-1 is drawn into the inside of the refrigerant flow path 6 by the chimney effect of the refrigerant flow path 6, and is used for cooling the winding 3-1.

  Also, a first insulating portion 4-31 having a C-shaped cross section is formed on the high-temperature cooling medium 201 existing radially inside the first insulating portion 4-31 and the lower end 3D of the winding 3-1. It becomes a wall that partitions between the inlet of the refrigerant flow path 6 and the high-temperature cooling medium 201 existing inside the first insulating portion 4-31 in the radial direction and is prevented from being introduced into the refrigerant flow path 6. it can.

  FIG. 7 is a diagram illustrating a stationary inductor according to a comparative example and a housing in which the stationary inductor is provided. The stationary inductor 100A illustrated in FIG. 7 includes a third insulating unit 4-31A instead of the first insulating unit 4-31 and the second insulating unit 4-32. The third insulating portion 4-31A is a member having a C-shaped cross section provided on the insulating member 4-3 shown in FIG. The insulating member 4-3 shown in FIG. 5 is in contact with the outer side surface 50 of the columnar member 5 in the radial direction of the winding 3-1. The imaginary line extended in the direction is provided radially outward. In the stationary inductor 100A configured as described above, even when the cooling medium cml cooled by the side plate 204 of the housing 200 and having a low temperature reaches the lower end portion 3D of the winding 3-1, the third insulating portion is provided. 4-31A is a wall that partitions between the cooling medium cml and the inlet of the refrigerant channel 6 formed at the lower end 3D of the winding 3-1. Is not drawn into.

  In the stationary inductor 100A, the third insulating portion 4-31A is formed on the high-temperature cooling medium 201 existing inside the third insulating portion 4-31A in the radial direction and the lower end 3D of the winding 3-1. The high-temperature cooling medium 201 existing inside the third insulating portion 4-31A in the radial direction is introduced into the refrigerant flow path 6 because the high-temperature cooling medium 201 does not function as a partition between the refrigerant flow path 6 and the inlet of the refrigerant flow path 6. .

  On the other hand, since the stationary inductor 100 according to the embodiment includes the first insulating portion 4-31, the low-temperature cooling medium cml that is being lowered is used for cooling the winding 3-1. Therefore, the cooling efficiency of the winding 3-1 is improved as compared with the stationary inductor 100A shown in FIG.

  In the stationary inductor 100 according to the present embodiment, the second insulating portion 4-32 is provided between the end of the first insulating portion 4-31 on the YZ plane and the side surface 22 of the iron core yoke 1a2. ing. Therefore, the second insulating portion 4-32 is configured such that the high-temperature cooling medium 201 existing inside the second insulating portion 4-32 in the radial direction and the refrigerant flow formed outside the second insulating portion 4-32 in the radial direction. It functions as a wall that separates the road 6 from the inlet. Therefore, compared to the case where the second insulating portion 4-32 is not provided, the amount of the high-temperature cooling medium 201 existing inside the radial direction of the second insulating portion 4-32 into the refrigerant flow path 6 is smaller. As a result, the temperature rise of the winding 3 is suppressed.

  It is desirable that the second insulating portion 4-32 be configured such that the front end surface 21 in the direction in which the electric wire 2 extends is in contact with the side surface 22 of the iron core yoke 1a2. With this configuration, a gap between the side surface 22 of the iron core yoke 1a2 and the distal end surface 21 of the second insulating portion 4-32 can be eliminated. Therefore, as compared with the case where the gap exists, the flow rate of the high-temperature cooling medium 201 existing inside the second insulating portion 4-32 in the radial direction into the refrigerant flow path 6 further decreases, and the winding 3 is further suppressed.

  Note that it is desirable to use insulating paper widely used as an insulating member for the winding 3-1 for the first insulating portion 4-31 and the second insulating portion 4-32. By using the insulating paper, the manufacturing cost of the first insulating portion 4-31 and the second insulating portion 4-32 can be reduced as compared with the case where a member manufactured by die casting using an insulating resin is used. Can be.

  FIG. 8 is a partially enlarged view of a stationary inductor according to a first modification of the embodiment of the present invention. In the stationary inductor 100B shown in FIG. 8, a columnar member 5A having a dimension in the X-axis direction longer than the columnar member 5 is used instead of the columnar member 5 shown in FIG. The upper end 5A2 of the columnar member 5A is located near the upper end 3U of the winding 3-1. The lower end 5A1 of the columnar member 5A is located near the lower end 18 of the first insulating portion 4-31. In this manner, the lower end 5A1 of the columnar member 5A protrudes below the winding 3-1 from the lower end 3D of the winding 3-1. By using the columnar member 5A configured as described above, the columnar member 5A functions as a reinforcing member that prevents the first insulating portion 4-31 from being bent when the cooling medium 201 flows. Therefore, even when insulating paper or the like having a small thickness is used for the first insulating portion 4-31, the first insulating portion 4-31 can be prevented from being bent by the flow of the cooling medium 201. Therefore, the introduction of the cooling medium 201 into the coolant flow path 6 is not obstructed by the first insulating portion 4-31, and the cooling efficiency of the winding 3-1 can be prevented from lowering.

  FIG. 9 is a diagram showing a stationary inductor according to a second modification of the embodiment of the present invention and a housing in which the stationary inductor is provided. FIG. 10 is a diagram showing a state in which windings are provided on each of the three iron core legs shown in FIG. FIG. 11 is a cross-sectional view on the XZ plane including the windings and the third insulating portion shown in FIG. A stationary inductor 100C is provided inside the housing 200A shown in FIG. 9 instead of the stationary inductor 100 shown in FIG. The stationary inductor 100C includes a third insulating section 4-31B and a third insulating section in addition to the first insulating section 4-31, the first insulating section 4-31 ', and the second insulating section 4-32 shown in FIG. 4-31B ′ and a fourth insulating portion 4-32B. The third insulating portion 4-31B and the fourth insulating portion 4-32B are provided above the winding 3-1. A third insulating portion 4-31B and a fourth insulating portion 4-32B are also provided above the winding 3-3. A third insulating portion 4-31'A and a fourth insulating portion 4-32B are provided above the winding 3-2. In the stationary inductor 100C, at least one of the winding 3-1 and the winding 3-3 may be provided with the third insulating portion 4-31B and the fourth insulating portion 4-32B.

  FIG. 11 shows a cross section of the third insulating portion 4-31B provided in the winding 3-1. The insulating member 4-3 is provided with a third insulating portion 4-31B. As shown in FIG. 11, the third insulating portion 4-31B protrudes above the winding 3-1 from the upper end 3U of the winding 3-1. Similarly to the first insulating portion 4-31, the third insulating portion 4-31B is a member having a C-shaped YZ section so as to surround the second surface 12 of the iron core leg 1c1 shown in FIG. . The C shape means a shape in which a part of the annular member is opened, and includes an arc shape, a U shape, and the like. Note that the third insulating portion 4-31B may be arranged so that at least a part thereof faces the three second surfaces 12 of the iron core leg 1c1 shown in FIG. For example, a part of the lower region of the iron core yoke 1a1 of the third insulating portion 4-31B may be present on a normal line perpendicular to the second surface 12 of the iron core leg 1c1.

  The insulating member 4-3 shown in FIG. 11 is provided with a fourth insulating portion 4-32B shown in FIG. The fourth insulating portion 4-32B is a member provided between the end of the third insulating portion 4-31B on the YZ plane and the side surface 22 of the core yoke 1a1. The side surface 22 of the iron core yoke 1a1 is an end surface on the Y axis direction side of the iron core yoke 1a1. The fourth insulating portion 4-32B may be formed integrally with the insulating member 4-3 and the third insulating portion 4-31B, or may be manufactured separately from the insulating member 4-3 and the third insulating portion 4-31B. It may be attached after being done. The fourth insulating portion 4-32B protrudes above the winding 3-1 from the upper end 3U of the winding 3-1 similarly to the third insulating portion 4-31B. Further, the fourth insulating portion 4-32B extends from the third insulating portion 4-31B toward the iron core yoke 1a1 along the direction in which the electric wire 2 extends, and is connected to the first surface 11 of the iron core leg 1c1 shown in FIG. Face each other. The fourth insulating portion 4-32B only needs to be disposed so that a part thereof faces the first surface 11 of the iron core leg 1c1, and for example, the side surface of the iron core yoke 1a1 of the fourth insulating portion 4-32B. Even if the tip on the 22 side does not exist on a normal line perpendicular to the first surface 11 of the iron core leg 1c1, it is sufficient if it exists at a position where the first surface 11 of the iron core leg 1c1 can be seen.

  The winding 3-2 shown in FIG. 10 is provided with a third insulating portion 4-31B 'and a fourth insulating portion 4-32B. The third insulating portion 4-31B 'provided on the winding 3-2 is provided at a position facing the second surface 14 of the iron core leg 1c2 shown in FIG. The fourth insulating portion 4-32B provided on the winding 3-2 extends from the third insulating portion 4-31B 'provided on the winding 3-2 toward the iron core yoke 1a1 along the direction in which the electric wire 2 extends. At the same time, it faces the first surface 13 of the iron core leg 1c2 shown in FIG.

  A third insulating part 4-31B and a fourth insulating part 4-32B are provided in the winding 3-3 shown in FIG. The third insulating portion 4-31B provided on the winding 3-3 is provided at a position facing the second surface 16 of the iron core leg 1c3 shown in FIG. The second insulating portion 4-32 provided on the winding 3-3 extends from the third insulating portion 4-31B provided on the winding 3-3 toward the iron core yoke 1a1 along the direction in which the electric wire 2 extends. 4 and the first surface 15 of the iron core leg 1c3 shown in FIG.

  Next, the flow of the cooling medium 201 generated when the winding 3 of the stationary inductor 100C is energized will be described with reference to FIG. FIG. 12 is a diagram for explaining the flow of the cooling medium generated when the winding shown in FIG. 9 is energized. In FIG. 12, the cooling medium 201 flowing in the refrigerant flow path 6 formed in the winding 3-1 will be described for simplicity. FIG. 12 shows only two refrigerant flow paths 6 among the plurality of refrigerant flow paths 6 provided in the winding 3-1 shown in FIG. Also, in FIG. 12, for simplicity of description, the illustration of the first insulating portion 4-31 and the second insulating portion 4-32 provided in the winding 3-1 shown in FIG. 9 is omitted.

  One of the two refrigerant flow paths 6 shown in FIG. 12 is provided at a position facing the second surface 12 in the Z-axis direction of the iron core leg 1c1 shown in FIG. 4, and the other is provided in FIG. The core leg 1c1 is provided at a position facing the second surface 12 in the Y-axis direction. The flow of the cooling medium 201 to the refrigerant flow path 6 formed in the winding 3-3 is the same as the flow of the cooling medium 201 to the refrigerant flow path 6 formed in the winding 3-1. Then, the explanation is omitted.

  When the temperature of the winding 3-1 rises due to energization, the heat of the winding 3-1 is transmitted to the cooling medium 201 existing inside the refrigerant flow path 6, and the temperature of the cooling medium 201 rises. The cooling medium cmh whose temperature has risen to a high temperature is discharged from the upper end 3U of the winding 3-1 to the outside of the winding 3-1. When the heat of the cooling medium cmh is transmitted to the side plate 204 of the housing 200A, the temperature of the cooling medium cmh decreases. The cooling medium cmh whose temperature has been lowered as a result of the temperature drop in this way descends toward the bottom plate 203 of the housing 200A as the cooling medium cml. Since the third insulating portion 4-31B having a C-shaped cross section exists between the cooling medium cml descending toward the bottom plate 203 and the cooling medium cmh rising toward the top plate 202, the third insulation The portion 4-31B serves as a partition wall between the cooling medium cml and the cooling medium cmh, and the cooling medium cml is not drawn to the cooling medium cmh. Then, while the cooling medium cml is descending toward the bottom plate 203 of the housing 200A, the heat of the cooling medium cml is transmitted to the side plate 204 of the housing 200A and radiated outside the housing 200A. Temperature further decreases. When the cooling medium cml which has become low in temperature in this way reaches the lower end 3D of the winding 3-1, it is drawn into the refrigerant flow path 6 by the chimney effect of the refrigerant flow path 6, and the winding 3-1. It is used for cooling.

  FIG. 13 is a diagram showing a stationary inductor according to a comparative example of the second modification shown in FIG. 9 and a housing in which the stationary inductor is provided. The stationary inductor 100D illustrated in FIG. 13 includes a third insulating unit 4-31C instead of the third insulating unit 4-31B and the fourth insulating unit 4-32B. The third insulating portion 4-31C is a member having a flat plate-shaped cross section provided only at a position facing the second surface 12 in the Z-axis direction of the iron core leg 1c1 in the outer peripheral surface 1c11 of the iron core leg 1c1. In the stationary inductor 100D, since the third insulating portion 4-31C is not formed in a C-shape, the cooling medium cml cooled by the side plate 204 of the housing 200A and having a low temperature is supplied to the bottom plate 203 of the housing 200A. On the way toward the second surface 12 in the Y-axis direction of the iron core leg 1c1, it is drawn to the high-temperature cooling medium cmh discharged from the refrigerant channel 6 formed at the position facing the second surface 12 in the Y-axis direction. Guided to the top. Therefore, in the stationary inductor 100D shown in FIG. 13, the cooling medium cml continues to circulate near the top plate 202 of the housing 200A and does not reach the lower end 3D of the winding 3-1. Is not introduced inside.

  Since the stationary inductor 100C shown in FIG. 12 includes the C-shaped third insulating portion 4-31B, the low-temperature cooling medium cml being lowered is guided to the upper portion of the refrigerant flow path 6 by the high-temperature cooling medium cmh. Can be suppressed. Thereby, the low-temperature cooling medium cml reaches the lower end 3D of the winding 3-1 and is used for cooling the winding 3-1. As a result, in the stationary inductor 100C, the cooling efficiency of the winding 3-1 is improved as compared with the stationary inductor 100D shown in FIG.

  When the third insulating portion 4-31B is provided on the insulating member 4-2 in contact with the inner side surface 5I of the columnar member 5 shown in FIG. 11, the refrigerant flow path 6 shown in FIG. It is formed on the outside in the radial direction of 4-31B. Therefore, when the third insulating portion 4-31B is provided on the insulating member 4-2, the third insulating portion 4-31B cannot partition between the cooling medium cml and the cooling medium cmh. On the other hand, in the stationary inductor 100C shown in FIG. 12, the third insulating portion 4-31B is provided on the insulating member 4-3 in contact with the outer side surface 50 of the columnar member 5, so that the third insulating portion 4-3B is provided. -31B serves as a partition wall between the cooling medium cml and the cooling medium cmh, and the cooling medium cml is not drawn to the cooling medium cmh.

  Further, in the stationary inductor 100C shown in FIG. 12, the fourth insulating portion 4-32B is provided between the end on the YZ plane of the third insulating portion 4-31B and the side surface 22 of the iron core yoke 1a1. . Therefore, for example, while the cooling medium cml cooled by the side plate 204 of the housing 200A and having a low temperature is descending toward the bottom plate 203 of the housing 200A, the second surface of the iron core 1c1 on the iron core 1c2 side. It can be suppressed that the refrigerant is attracted to the high-temperature cooling medium cmh discharged from the refrigerant flow path 6 formed at a position facing the cooling medium 12. Therefore, in the stationary inductor 100C shown in FIG. 12, the amount of the low-temperature cooling medium cml introduced into the refrigerant flow path 6 is increased as compared with the case where the fourth insulating portion 4-32B is not provided. Cooling efficiency is further improved.

  It is desirable that the fourth insulating portion 4-32B be configured such that the front end surface in the direction in which the electric wire 2 extends is in contact with the side surface 22 of the iron core yoke 1a1. With this configuration, it is possible to eliminate a gap between the side surface 22 of the iron core yoke 1a1 and the distal end surface of the fourth insulating portion 4-32B. When the gap exists, the cooling medium cml cooled by the side plate 204 of the housing 200A and cooled to a lower temperature toward the bottom plate 203 of the housing 200A leaks from the gap while being lowered toward the bottom plate 203 of the housing 200A. The cooling medium cml can be prevented from being drawn to the cooling medium cmh because the gap is eliminated. Therefore, the introduction amount of the low-temperature cooling medium cml into the refrigerant flow path 6 is increased as compared with the case where the tip end surface of the fourth insulating portion 4-32B is not in contact with the side surface 22 of the iron core yoke 1a1. The cooling efficiency is further improved.

  In addition, it is desirable to use insulating paper widely used as an insulating member of the winding 3-1 for the third insulating portion 4-31B and the fourth insulating portion 4-32B. By using the insulating paper, for example, the manufacturing cost of the third insulating portion 4-31B and the fourth insulating portion 4-32B can be reduced as compared with a case where a member manufactured by die casting using an insulating resin is used. Can be.

  FIG. 14 is a partially enlarged view of a stationary inductor according to a third modification of the embodiment of the present invention. In the stationary inductor 100E shown in FIG. 14, a columnar member 5B having a dimension in the X-axis direction longer than the columnar member 5 is used instead of the columnar member 5 shown in FIG. The lower end 5B1 of the columnar member 5B is located near the lower end 3D of the winding 3-1. The upper end 5B2 of the columnar member 5B is located near the upper end 17 of the third insulating portion 4-31B. As described above, the upper end 5B2 of the columnar member 5B protrudes above the winding 3-1 from the upper end 3U of the winding 3-1. By using the columnar member 5B, the columnar member 5B functions as a reinforcing member that prevents the third insulating portion 4-31B from being bent when the cooling medium 201 flows. Therefore, for example, even when the insulating paper having a small thickness is used for the third insulating portion 4-31B, it is possible to prevent the third insulating portion 4-31B from being bent due to the flow of the cooling medium 201. Therefore, the discharge of the cooling medium 201 from the refrigerant flow path 6 shown in FIG. 4 is not hindered by the third insulating portion 4-31B, and a decrease in the cooling efficiency of the winding 3-1 can be suppressed.

  In the columnar member 5B shown in FIG. 14, the lower end portion 5B1 of the columnar member 5B has a lower end 5B1 than the lower end portion 3D of the winding 3-1 like the columnar member 5A shown in FIG. You may comprise so that it may protrude below. In this case, the lower end 5B1 of the columnar member 5B is located near the lower end 18 of the first insulating portion 4-31. By using the columnar member 5B configured as described above, the columnar member 5B functions as a reinforcing member that prevents the first insulating portion 4-31 from being bent when the cooling medium 201 flows. Therefore, even when insulating paper or the like having a small thickness is used for the first insulating portion 4-31, the first insulating portion 4-31 can be prevented from being bent by the flow of the cooling medium 201.

  The stationary induction devices 100, 100B, and 100C use, for example, the iron core 1 having three iron legs 1c1, 1c2, and 1c3, with the iron core leg 1c1 as the first iron leg, and the iron core leg 1c2 as the second iron leg. However, for example, the iron core 1 having the two iron legs 1c1 and 1c3 may be used with the iron core leg 1c1 as the first iron core leg and the iron core leg 1c3 as the second iron core leg. In this case, the stationary inductors 100, 100B, and 100C function as single-phase transformers. As described above, when the stationary inductors 100, 100B, and 100C are configured as single-phase transformers, the winding 3-1 provided on the iron core 1c1 and the winding 3-3 provided on the iron core 1c3. At least one of them may be provided with the first insulating portion 4-31 and the second insulating portion 4-32. When the stationary inductors 100, 100B, and 100C are configured as a single-phase transformer, the winding 3-1 provided on the iron core leg 1c1 and the winding 3-3 provided on the iron core leg 1c3 are formed. At least one of them may be provided with the third insulating portion 4-31B and the fourth insulating portion 4-32B.

  Further, in the present embodiment, the configuration examples of stationary inductors 100, 100B, and 100C using iron core 1 having iron core 1c having a square YZ cross section have been described, but the shape of iron core 1c is not limited to this. Instead, for example, the YZ cross section may be cylindrical.

  Further, in the present embodiment, the columnar member 5 is used as the flow path forming member, but the member forming the refrigerant flow path 6 forms the refrigerant flow path 6 between the insulating members 4 adjacent in the radial direction. The member is not limited to a columnar member as long as the member can be used. For example, on the surface of the insulating member 4-3 shown in FIG. 5 on the insulating member 4-2 side, a plurality of protrusions arranged apart from each other in the X-axis direction and the Y-axis direction are provided as flow path forming members. Alternatively, the plurality of protrusions may be provided as a flow path forming member on the surface of the insulating member 4-2 on the insulating member 4-3 side.

  The configurations described in the above embodiments are merely examples of the contents of the present invention, and can be combined with other known technologies, and can be combined with other known technologies without departing from the gist of the present invention. Parts can be omitted or changed.

  DESCRIPTION OF SYMBOLS 1 Iron core, 1a1, 1a2 Iron core yoke, 1c, 1c1, 1c2, 1c3 Iron leg, 1c11, 1c21, 1c31 Outer peripheral surface, 2 electric wires, 3,3-1,3-2,3-3 winding, 3D, 5A1, 5B1, 18 lower end, 3I, 5I inner side, 30, 50 outer side, 3U, 5A2, 5B2 upper end, 4,4-1, 4-2, 4-3, 4-4 insulating member, 4-31, 4-31 ′, 4-31A first insulating section, 4-31B, 4-31B ′, 4-31C third insulating section, 4-32 second insulating section, 4-32B fourth insulating section, 5, 5A, 5B columnar member, 6 refrigerant flow path, 11, 13, 15 first surface, 12, 14, 16 second surface, 21 tip surface, 22 side surface, 100, 100A, 100B, 100C, 100D, 100E stationary inductor, 200 , 200A housing, 201 cooling medium, 02 top plate, 203 a bottom plate, 204 the side plates.

Claims (9)

A first core yoke, a second core yoke disposed below the first core yoke at a predetermined distance from the first core yoke, and a second core yoke extending from the first core yoke toward the second core yoke. An iron core comprising: a first iron leg; and a second iron leg extending from the first iron yoke toward the second iron yoke and arranged at a predetermined distance from the first iron leg and parallel to the first iron leg. When,
A cylindrical winding formed by laminating an electric wire and an insulating member wound around the first iron leg so as to surround the outer peripheral surface of the first iron leg;
A flow path forming member that is provided between the insulating members adjacent to each other in the radial direction of the winding and that forms a refrigerant flow path that penetrates from a lower end to an upper end of the winding.
With
The insulating member in contact with the radial inner surface of the flow path forming member,
A first projecting from the lower end of the winding to a lower side of the winding and surrounding a surface other than the first surface facing the second iron core in a C-shape among the outer peripheral surfaces of the first iron core. A stationary inductor provided with an insulating part. The insulating member in contact with the radial inner surface of the flow path forming member,
2. The stationary device according to claim 1, further comprising a second insulating portion extending from the first insulating portion toward the first core yoke along a direction in which the electric wire extends and facing the first surface. 3. Inductor.   The stationary inductor according to claim 2, wherein the second insulating part contacts a side surface of the first core yoke.   The stationary inductor according to any one of claims 1 to 3, wherein the flow path forming member is a columnar member extending to a lower end of the first insulating portion. The insulating member in contact with the radially outer surface of the flow path forming member,
5. A third insulating portion, which protrudes above the winding from an upper end of the winding and surrounds a surface other than the first surface in a C-shape, is provided. A stationary inductor according to claim 1. The insulating member in contact with the radially outer surface of the flow path forming member,
The stationary device according to claim 5, wherein a fourth insulating portion extending from the third insulating portion toward the first core yoke along the direction in which the electric wire extends and facing the first surface is provided. Inductor.   The stationary inductor according to claim 6, wherein the fourth insulating portion contacts a side surface of the first core yoke.   The stationary inductor according to any one of claims 5 to 7, wherein the flow path forming member is a columnar member extending to an upper end of the third insulating portion.   The stationary inductor according to any one of claims 1 to 8, wherein the insulating member is made of insulating paper.

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