JP2020053510A - Reactor and outdoor equipment - Google Patents

Abstract

To provide a reactor and outdoor equipment capable of improving the heat radiation performance of a core portion while suppressing an increase in cost.SOLUTION: A reactor includes a core portion 32 including a pair of recesses 32A and 32B, which is configured such that a plurality of first and second electromagnetic steel sheets 41 and 42 are laminated, and a coil portion 33 disposed in the pair of recesses 32A and 32B, and the surface of the core portion 32 that contacts the coil portion 33 is a flat surface, and the end of the core portion 32 in the X direction orthogonal to the Y direction in which the plurality of first and second electromagnetic steel sheets 41 and 42 are stacked includes a plurality of recesses and projections 32C and 32D arranged in the Y direction.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a reactor and an outdoor unit.

  An outdoor unit of an air conditioner includes an inverter device that drives a motor such as a compressor and a fan, a high-frequency suppression device generated by the inverter, and the like. One of the electrical components that constitutes these devices is a reactor. The reactor suppresses a large current from flowing and causing noise to adversely affect other electric products.

The reactor has a core portion composed of a plurality of laminated electromagnetic steel sheets, and a coil portion wound around the core portion.
Since the reactor is a heating element, a reactor having excellent heat dissipation properties is desired (for example, see Patent Document 1).

  Patent Literature 1 discloses a coil unit that is laminated while spirally winding a rectangular wire having a rectangular cross section orthogonal to the longitudinal direction.

JP 2011-249490 A

  By the way, in the case where the coil portion is formed by a spirally wound rectangular wire as in Patent Literature 1, the manufacturing process is complicated, which may increase the cost. A similar problem occurs when the technology 3 of Patent Document 1 is applied to the core portion and the core portion is formed into a spiral shape.

In addition, for example, when it is desired to improve the heat dissipation of the core portion, as described in Patent Document 1, when a plurality of electromagnetic steel plates are helically laminated, contact between the coil portion and the helically shaped core portion is prevented. The area decreases.
This makes it difficult for the heat of the coil portion to be conducted to the core portion, so that the heat radiation performance of the core portion may be reduced.

  Therefore, an object of the present invention is to provide a reactor and an outdoor unit capable of improving heat radiation performance of a core portion while suppressing an increase in cost.

  In order to solve the above-described problem, a reactor according to one embodiment of the present invention is configured by stacking a plurality of electromagnetic steel sheets, and includes a core including a pair of recesses, and a part wound around the core. A coil portion disposed in the pair of recesses, and a surface of the core portion that is in contact with the coil portion is a flat surface, and is orthogonal to a stacking direction in which the plurality of electromagnetic steel sheets are stacked. An end of the core in the width direction includes a plurality of irregularities arranged in the laminating direction.

ADVANTAGE OF THE INVENTION According to this invention, since the surface of the core part which contacts a coil part is made into a plane, it becomes possible to increase the contact area between the surface of a core part and a coil part. Thereby, heat generated in the coil portion can be efficiently conducted to the core portion.
In addition, by making the surface of the core portion that is in contact with the coil portion a flat surface, a plurality of electromagnetic steel sheets can be easily laminated, thereby suppressing an increase in cost.
In addition, the end of the core portion in the width direction orthogonal to the stacking direction in which the plurality of electromagnetic steel sheets are stacked includes a plurality of irregularities arranged in the stacking direction, so that the plurality of protrusions function as radiation fins. Therefore, heat conducted from the coil portion and heat from the core portion can be efficiently radiated.
That is, it is possible to improve the heat radiation performance of the core portion while suppressing an increase in cost.

  Further, in the reactor according to one embodiment of the present invention, the plurality of magnetic steel sheets include a first magnetic steel sheet and a second magnetic steel sheet, and the first magnetic steel sheet includes a pair of concave portions. A first recess forming one of the recesses, a second recess forming the other of the pair of recesses and having the same width as the first recess, and the first recess and the second recess in the width direction. A first portion sandwiched between the first and second concave portions; a second portion disposed outside the first concave portion and facing the first portion in the width direction; and a second concave portion. And a third portion facing the first portion in the width direction and having the same width as the second portion, wherein the second electromagnetic steel sheet is A first concave portion, the second concave portion, and the first portion, and disposed outside the first concave portion; A fourth portion facing the first portion in the width direction and wider than the second portion; and a fourth portion disposed outside the second recess, and the first portion in the width direction. And a fifth portion wider than the third portion, and the core portion is formed by alternately stacking the first electromagnetic steel sheet and the second electromagnetic steel sheet. May be adopted.

As described above, by forming the core portion by alternately laminating the first electromagnetic steel plate and the second electromagnetic steel plate having the above-described configuration, the fourth electromagnetic steel plate is disposed outside the second portion (one side in the width direction). A part of the fifth part protrudes, and a part of the fifth part protrudes outside the third part (the other side in the width direction).
Thereby, a plurality of irregularities can be formed on both ends of the core portion arranged in the width direction.

  Further, in the reactor according to one embodiment of the present invention, the plurality of electromagnetic steel sheets are formed only of electromagnetic steel sheets having the same shape, and the first magnetic steel sheet forms one of the pair of recesses. , A second recess forming the other of the pair of recesses, a first portion sandwiched between the first recess and the second recess in the width direction, A second portion disposed outside the concave portion and facing the first portion in the width direction; and a second portion disposed outside the second concave portion and facing the first portion in the width direction. And a third portion having a width wider than the width of the second portion, wherein the core portion is configured such that a front surface and a back surface of the electromagnetic steel sheets adjacent to each other in the laminating direction are in contact with each other. Then, the plurality of electromagnetic steel sheets may be laminated.

As described above, the second portion is provided by providing a plurality of the electromagnetic steel sheets configured as described above and stacking the plurality of the electromagnetic steel sheets so that the front surface and the back surface of the electromagnetic steel sheets adjacent to each other in the stacking direction are in contact with each other. A portion of the fourth portion protrudes outside (one side in the width direction) of the third portion, and a portion of the fifth portion protrudes outside the third portion (the other side in the width direction).
Thereby, a plurality of irregularities can be formed on both ends of the core portion arranged in the width direction.
In addition, by forming the core portion only with a plurality of magnetic steel sheets having the same shape, manufacturing of the magnetic steel sheets is facilitated, so that the cost of the reactor can be reduced.

  In order to solve the above problems, an outdoor unit according to one embodiment of the present invention includes the reactor, an inverter circuit electrically connected to the reactor, and a compressor electrically connected to the reactor. The reactor may be provided in a machine room, and the reactor may be arranged between the inverter circuit and the compressor.

  In this way, by providing a reactor having excellent heat dissipation performance in the machine room of the outdoor unit, it is possible to suppress the temperature rise in the machine room and to make the reactor itself smaller, thereby improving the degree of freedom of installation. Can be.

  ADVANTAGE OF THE INVENTION According to this invention, the heat dissipation performance of a core part can be improved, suppressing an increase in cost.

It is a perspective view showing the schematic structure of the outdoor unit concerning a 1st embodiment of the present invention. It is a front view of the reactor shown in FIG. FIG. 3 is a top view of a structure in which a lid is removed from the reactor shown in FIG. 2. FIG. 4 is a top view of a core part excluding a coil part from the structure shown in FIG. 3. It is a front view of the core part shown in FIG. FIG. 5 is a front view of a first electromagnetic steel sheet constituting a core part shown in FIG. 4. FIG. 5 is a front view of a second electromagnetic steel sheet constituting the core shown in FIG. 4. It is a front view of the reactor concerning a 2nd embodiment of the present invention. FIG. 9 is a top view of the structure in a state where a lid is removed from the reactor shown in FIG. 8. It is the figure which looked at the electromagnetic steel sheet shown in FIG. 9 from the surface side by plane. It is the figure which looked at the electromagnetic steel sheet shown in FIG. 9 from the back surface side by plane.

(First embodiment)
An outdoor unit 10 according to a first embodiment of the present invention will be described with reference to FIG.
The outdoor unit 10 includes a machine room 12, a housing 14, a heat exchanger 16, and a plurality of fans 21.

  The machine room 12 includes a housing 22, a compressor 24, an inverter circuit 27, a reactor 30, a water heat exchanger (not shown), a water pipe (not shown), and an expansion valve (not shown). ), A refrigerant pipe (not shown), and a water circulation pump (not shown).

  The housing 22 houses a compressor 24, an inverter circuit 27, a reactor 30, a water heat exchanger, an expansion valve, a refrigerant pipe, a water pipe, and a water circulation pump.

  The compressor 24 is connected to a four-way switching valve, a water heat exchanger, and an expansion valve via a refrigerant pipe. The compressor 24 has a motor. The compressor 24 adjusts the amount of refrigerant discharged to the refrigerant pipe by controlling the number of rotations of the motor. The compressor 24 is electrically connected to the reactor 30.

  The inverter circuit 27 drives the motor of the compressor 24. Inverter circuit 27 is electrically connected to reactor 30. The inverter circuit 27 is electrically connected to the compressor 24 via the reactor 30.

The reactor 30 will be described with reference to FIGS. 2 to 7, the X direction is a width direction orthogonal to the laminating direction (the Y direction shown in FIGS. 3 to 5) in which the plurality of first and second electromagnetic steel sheets 41 and 42 are laminated, and the Z direction. Indicates the height direction of the reactor 30 orthogonal to the X direction. The Y direction shown in FIGS. 3 to 5 indicates the lamination direction in which the plurality of first and second electromagnetic steel sheets 41 and 42 are laminated as described above.
2 and 3, the coil part 33 configured by winding an electric wire is illustrated in a simplified manner.

In FIG. 6, O ₁ is a center line (hereinafter, referred to as “center line O ₁ ”) of the connecting portion 45, the first portion 46, and the first electromagnetic steel sheet 41, and W 1 is an X direction of the second portion 47 in the X direction. The width (hereinafter, referred to as “width W1”), W2 is the width of the third portion 48 in the X direction (hereinafter, referred to as “width W2”), and W3 is the width of the first recess 51 (hereinafter, referred to as “width W3”). ) And W4 indicate the width of the second concave portion 52 (hereinafter referred to as “width W4”).

In FIG. 7, O ₂ indicates a center line (hereinafter, referred to as “center line O ₂ ”) of the connecting portion 45, the first portion 46, and the second electromagnetic steel sheet 42.

The reactor 30 has a core part 32, a coil part 33, and a lid part 35.
The core part 32 includes a plurality of first and second electromagnetic steel sheets 41 and 42 (a plurality of electromagnetic steel sheets), concave parts 32A and 32B (a pair of concave parts) that extend in the Y direction and in which the coil part 33 is disposed, and a winding part. And a turning part 43.

  The first electromagnetic steel plate 41 has a connecting portion 45, a first portion 46, a second portion 47, a third portion 48, a first concave portion 51, and a second concave portion 52. .

  The connecting portion 45 is a rectangular plate portion extending in the X direction. The connecting portion 45 is disposed on one side in the Z direction, and has a surface 45a extending in the X direction.

The first portion 46 is provided on a surface 45 a at a central portion of the connecting portion 45. The first portion 46 is a rectangular plate portion extending from the surface 45a of the connecting portion 45 to one side in the Z direction. The center line O ₁ of the first portion 46 matches the center line of the connecting portion 45. The first portion 46 is formed integrally with the connecting portion 45.
The first portion 46 is sandwiched between the first concave portion 51 and the second concave portion 52 in the X direction.

The second portion 47 is provided on a surface 45a of an end located on one side in the X direction among both ends of the connecting portion 45 arranged in the X direction. The second portion 47 is a rectangular plate portion extending from the surface 45a of the connecting portion 45 to one side in the Z direction.
The length of the second portion 47 in the Z direction with respect to the surface 45a is configured to be equal to the length of the first portion 46. The second portion 47 is arranged to be separated from the first portion 46 on one side in the X direction.

The third portion 48 is provided on a surface 45a of an end portion disposed on the other side in the X direction among the both end portions of the connecting portion 45 disposed in the X direction. The third portion 48 is a rectangular plate portion extending from the surface 45a of the connecting portion 45 to one side in the Z direction.
The length of the third portion 48 in the Z direction with respect to the surface 45a is configured to be equal to the length of the first and second portions 46 and 47. The third portion 48 is spaced apart from the first portion 46 on the other side in the X direction.
The width W2 of the third portion 48 is configured to be equal to the width W1 of the second portion 47.

The first recess 51 is formed between the first part 46 and the second part 47.
The second concave portion 52 is formed between the first portion 46 and the third portion 48. The width W4 of the second concave portion 52 is configured to be equal to the width W3 of the first concave portion 51.

First electromagnetic steel plates 41 having the above construction is the center line O ₁ and the shape of line symmetry to the symmetry axis.

The second electromagnetic steel sheet 42 has a fourth part 55 instead of the second part 47 constituting the first electromagnetic steel sheet 41, and has a fifth part 56 instead of the third part 48. Except for this, the configuration is the same as that of the first electromagnetic steel sheet 41.
The fourth portion 55 has a width W5 larger than the width W1 of the second portion 47. The fourth portion 55 has an end 55A arranged on one side in the X direction.
The fifth portion 56 has a width W6 larger than the width W2 of the third portion 48. The fifth portion 56 has an end 56A arranged on the other side in the X direction.

Second electromagnetic steel plates 42 having the above configuration is axisymmetric shape that the center line O ₂ axis of symmetry.

The core part 32 is configured by alternately stacking the first electromagnetic steel sheets 41 and the second electromagnetic steel sheets 42 in the Y direction.
At this time, in the Y direction, the entire first concave portion 51 of the first electromagnetic steel plate 41 and the entire first concave portion 51 of the second electromagnetic steel plate 42 are opposed to each other, and the second concave portion 51 of the first electromagnetic steel plate 41 is The first electromagnetic steel sheet 41 and the second electromagnetic steel sheet 42 are stacked such that the entire concave section 52 faces the entire second concave section 52 of the second electromagnetic steel sheet 42.

By laminating the plurality of first and second electromagnetic steel sheets 41 and 42 in such a state, the end 55A of the fourth portion 55 projects to one side in the X direction of the second portion 47, and the fifth portion An end 56A of the portion 56 projects to the other side in the X direction of the third portion 48.
As described above, since the first and second electromagnetic steel sheets 41 are alternately stacked, a plurality of irregularities 32C are formed on one side wall in the X direction of the core part 32, A plurality of irregularities 32D are formed on the other side wall in the X direction. The ends 55A and 56A of the plurality of second electromagnetic steel sheets 42 function as heat radiation fins.

  As described above, since both ends of the core portion 32 arranged in the X direction include the plurality of irregularities 32C and 32D, the plurality of protrusions (end portions 55A and 55A) function as heat radiation fins. And the heat of the core portion 32 can be efficiently radiated.

The recess 32A is constituted by a plurality of first recesses 51 stacked in the Y direction.
The recess 32A has side surfaces 32Aa and 32Ab and a bottom surface 32Ac. The side surfaces 32Aa and 32Ab and the bottom surface 32Ac are flat surfaces.

The concave portion 32B is configured by a plurality of second concave portions 52 stacked in the Y direction.
The recess 32B has side surfaces 32Ba and 32Bb and a bottom surface 32Bc. The side surfaces 32Ba and 32Bb and the bottom surface 32Bc are flat surfaces.
A part of the coil portion 33 is arranged in the recesses 32A, 32B having the above-described configuration so as to contact the side surfaces 32Aa, 32Ab, 32Ba, 32Bb and the bottom surfaces 32Ac, 32Bc.

  As described above, by making the side surfaces 32Aa, 32Ab, 32Ba, 32Bb and the bottom surfaces 32Ac, 32Bc of the core portion 32 in contact with the coil portion 33 (the surface of the core portion 32 in contact with the coil portion 33) flat, the core portion 32 is formed. It is possible to increase the contact area between the coil portion 33 and the side surfaces 32Aa, 32Ab, 32Ba, 32Bb and the bottom surfaces 32Ac, 32Bc. Thereby, the heat generated in the coil part 33 can be efficiently conducted to the core part 32.

  In addition, by making the side surfaces 32Aa, 32Ab, 32Ba, 32Bb and the bottom surfaces 32Ac, 32Bc of the core portion 32 in contact with the coil portion 33 flat, a plurality of electromagnetic steel plates are arranged in a spiral shape. Since the first and second electromagnetic steel sheets 41 and 42 can be easily laminated, an increase in the cost of the reactor 30 can be suppressed.

  The winding part 43 is constituted by a plurality of first parts 46 arranged in the Y direction.

  The electric wire forming the coil part 33 is wound around the winding part 43. The shape of the coil part 33 is a ring shape. A part of the coil part 33 is accommodated in the concave parts 32A and 32B, and the remaining part protrudes from the core part 32 to one side in the Y direction and the other side in the Y direction.

The lid 35 is disposed so as to cover the concave ends 32A and 32B of the core 32 around which the coil 33 is wound, at the open end which is the upper end. The lid 35 is formed by stacking a plurality of rectangular and uniform electromagnetic steel sheets (not shown) in the Y direction.
The lid 35 is fixed to the core 32 by a method such as welding.

The water heat exchanger causes heat exchange between the refrigerant flowing through the refrigerant pipe and water flowing through the water pipe.
The water pipe includes a first water pipe (not shown) for supplying water to the water heat exchanger from outside the outdoor unit 10 and a second water pipe for discharging water from the water heat exchanger to the outside of the outdoor unit 10. Piping (not shown).
The expansion valve is connected to the heat exchanger 16. The water circulation pump supplies water to the water heat exchanger.
The outdoor unit 10 performs both the cooling operation and the heating operation by switching the four-way switching valve.

The housing 14 is provided on the machine room 12. The housing 14 has a side wall 14A in which an outside air suction port 14B is formed, and a plurality of openings 14D formed in a top plate 14C.
The outside air suction port 14B is used when taking outside air into the housing 14.
The plurality of openings 14 </ b> D are openings for drawing outside air that has been sucked into the housing 14 and contributed to heat exchange to the outside of the housing 14.

The heat exchanger 16 is housed in the housing 14. The heat exchanger 16 is a pneumatic heat exchanger.
The heat exchanger 16 has a plurality of heat transfer tubes that can come into contact with outside air (air) sucked through the outside air suction port 14 </ b> B and that is connected to the compressor 24.
The refrigerant supplied from the compressor 24 flows in the plurality of heat transfer tubes. In the heat exchanger 16, the refrigerant flowing in the plurality of heat transfer tubes exchanges heat with the outside air.

  The plurality of fans 21 are arranged below each opening 14D. The plurality of fans 21 face one opening 14D in the height direction of the outdoor unit 10. The plurality of fans 21 cause the outside air to be sucked into the housing 14 and discharge the heat-exchanged outside air to the outside of the housing 14.

  According to the reactor 30 of the first embodiment, the side surfaces 32Aa, 32Ab, 32Ba, 32Bb and the bottom surfaces 32Ac, 32Bc (the surfaces of the core portion 32 contacting the coil portion 33) of the core portion 32 contacting the coil portion 33 are flat. By doing so, it is possible to increase the contact area between the side surface 32Aa, 32Ab, 32Ba, 32Bb and the bottom surface 32Ac, 32Bc of the core portion 32 and the coil portion 33. Thereby, the heat generated in the coil part 33 can be efficiently conducted to the core part 32.

  In addition, by making the side surfaces 32Aa, 32Ab, 32Ba, 32Bb and the bottom surfaces 32Ac, 32Bc of the core portion 32 in contact with the coil portion 33 flat, a plurality of electromagnetic steel plates are arranged in a spiral shape. Since the first and second electromagnetic steel sheets 41 and 42 can be easily laminated, an increase in the cost of the reactor 30 can be suppressed.

In addition, since both ends of the core portion 32 arranged in the X direction include a plurality of irregularities 32C and 32D, the plurality of protrusions (ends 55A and 55A) function as radiation fins. The heat generated and the heat of the core 32 can be efficiently radiated.
That is, it is possible to improve the heat radiation performance of the core portion 32 while suppressing an increase in the cost of the reactor 30.

  In this way, by providing a reactor having excellent heat dissipation performance in the machine room of the outdoor unit, it is possible to suppress the temperature rise in the machine room and to make the reactor itself smaller, thereby improving the degree of freedom of installation. Can be.

  In the first embodiment, the case where the plurality of irregularities 32C and 32D are provided at one end in the X direction and the other end in the X direction of the core portion 32 has been described as an example. A plurality of concavities and convexities (a plurality of concavities and convexities 32C or a plurality of concavities and convexities) may be provided only at one end of the two ends in the X direction of the 32. Also in this case, the same effect as that of the reactor 30 of the first embodiment can be obtained.

(Second embodiment)
A reactor 60 according to the second embodiment will be described with reference to FIGS. 8 to 11, the same components as those of the structure shown in FIGS. 2 to 7 are denoted by the same reference numerals. 8 to 11, the same components are denoted by the same reference numerals.

The reactor 60 has the same configuration as the reactor 30 except that the reactor 60 has a core portion 61 instead of the core portion 32 constituting the reactor 30 of the first embodiment.
The core part 61 is different from the core part 32 described in the first embodiment in that the core part 61 is configured by a plurality of electromagnetic steel sheets 63 having the same shape.

The electromagnetic steel sheet 63 is the same as the first electromagnetic steel sheet 41 except that the electromagnetic steel sheet 63 has a third portion 65 instead of the third portion 48 configuring the first electromagnetic steel sheet 41 described in the first embodiment. Is configured.
The width W7 of the third portion 65 in the X direction is configured to be wider than the width W1 of the second portion 47. Thus, the electromagnetic steel sheets 63 are not in a line symmetry to the center line O ₁ and axis of symmetry. That is, the electromagnetic steel sheets 63 are asymmetrical shape with respect to the center line O _1.

When the electromagnetic steel sheet 63 is viewed in a plan view from the surface 63a side of the electromagnetic steel sheet 63, the second portion 47 is arranged on the left side of the drawing and the third portion 65 is arranged on the right side of the drawing (see FIG. 10).
On the other hand, when the electromagnetic steel sheet 63 shown in FIG. 10 is turned over right and left and the electromagnetic steel sheet 63 is viewed from the back surface 63b side of the electromagnetic steel sheet 63, the third portion 65 is disposed on the left side of the paper and the second portion is provided on the right side of the paper. 47 are arranged (see FIG. 11).

The core portion 61 is formed by stacking a plurality of electromagnetic steel plates 63 such that the front surface 63a and the back surface 63b of the electromagnetic steel plates 63 adjacent to each other in the Y direction are in contact with each other.
At this time, in the Y direction, the first concave portions 51 formed in the electromagnetic steel plates 63 adjacent to each other face each other, and the second concave portions 52 formed in the electromagnetic steel plates 63 adjacent to each other face each other. A plurality of electromagnetic steel sheets 63 are stacked.

By laminating a plurality of electromagnetic steel sheets 63 in such a state, the width W7 of the third portion 65 in the X direction is wider than the width W1 of the second portion 47, and thus the third portion 65 in the X direction is The end protrudes from the end face of the second portion 47.
Thus, a plurality of irregularities 61C can be formed on one side wall in the X direction of the core portion 61, and a plurality of irregularities 61D can be formed on the other side wall in the X direction of the core portion 61. An end in the X direction of the third portion 65 functions as a radiation fin.

  According to the reactor 60 of the second embodiment, by configuring the core portion 61 by using a plurality of electromagnetic steel plates 63 having the same shape, a case in which the core portion is configured by using electromagnetic steel plates having different shapes is used. In comparison, the manufacture of the electromagnetic steel sheet 63 becomes easier. This makes it possible to reduce the manufacturing cost of the electromagnetic steel sheet 63, so that the cost of the reactor 60 can be reduced.

  In addition, the reactor 60 having the above configuration can obtain the same effect as the reactor 30 of the first embodiment described above.

  As described above, the preferred embodiments of the present invention have been described in detail, but the present invention is not limited to such specific embodiments, and various modifications may be made within the scope of the present invention described in the claims. Deformation and modification are possible.

DESCRIPTION OF SYMBOLS 10 ... Outdoor unit 12 ... Machine room 14, 22 ... Housing 14A ... Side wall 14B ... Outside air suction port 14C ... Top plate 14D ... Opening 16 ... Heat exchanger 21 ... Fan 24 ... Compressor 27 ... Inverter circuit 30, 60 ... Reactors 32, 61: Core portions 32A, 32B, 61A, 61B: Recesses 32Aa, 32Ab, 32Ba, 32Bb: Side surfaces 32Ac, 32Bc: Bottom surface 32C, 32D, 61C, 61D: Multiple irregularities 33: Coil portion 35: Lid portion 41 ... first electromagnetic steel sheet 42 ... second electromagnetic steel sheet 43 ... winding part 45 ... connecting part 45a ... surface 46 ... first part 47 ... second part 48,65 ... third part 51 ... first recess 52 ... second concave portion 55 ... fourth portion 55A, 56A ... end 56 ... fifth portion 63a ... surface 63 b ... backside O ₁ ~ O 3 _... center line W1 to W6 ... width

Claims (4)

A core portion configured by stacking a plurality of electromagnetic steel sheets and including a pair of concave portions,
A coil part wound around the core part and partially disposed in the pair of recesses,
With
The surface of the core portion that contacts the coil portion is a flat surface,
A reactor in which an end of the core portion in a width direction orthogonal to a laminating direction in which the plurality of electromagnetic steel sheets is laminated includes a plurality of irregularities arranged in the laminating direction. The plurality of electrical steel sheets include a first electrical steel sheet and a second electrical steel sheet,
A first recess forming one of the pair of recesses;
A second recess that forms the other of the pair of recesses and has the same width as the first recess;
A first portion sandwiched between the first concave portion and the second concave portion in the width direction;
A second portion disposed outside the first concave portion and facing the first portion in the width direction;
A third portion disposed outside the second concave portion, facing the first portion in the width direction, and having the same width as the second portion;
Have
The second electromagnetic steel sheet includes the first concave portion, the second concave portion, and the first portion,
A fourth portion disposed outside the first concave portion, facing the first portion in the width direction, and having a width larger than the second portion;
A fifth portion which is arranged outside the second concave portion, faces the first portion in the width direction, and is wider than the third portion;
Have
The reactor according to claim 1, wherein the core portion has a configuration in which the first electromagnetic steel plates and the second electromagnetic steel plates are alternately stacked. The plurality of magnetic steel sheets are formed only of the same shape of the magnetic steel sheets,
The electromagnetic steel sheet, a first recess constituting one of the pair of recesses,
A second recess forming the other of the pair of recesses,
A first portion sandwiched between the first concave portion and the second concave portion in the width direction;
A second portion disposed outside the first concave portion and facing the first portion in the width direction;
A third portion disposed outside the second recess, facing the first portion in the width direction, and having a width larger than the width of the second portion;
Has,
2. The reactor according to claim 1, wherein the core portion includes the plurality of electromagnetic steel plates stacked such that a front surface and a back surface of the magnetic steel plates adjacent to each other in the stacking direction are in contact with each other. A reactor according to any one of claims 1 to 3, and
An inverter circuit electrically connected to the reactor,
A compressor electrically connected to the reactor;
In preparation for the machine room including
An outdoor unit in which the reactor is disposed between the inverter circuit and the compressor.

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