JP2010165796A - Toroidal core, toroidal core case, toroidal coil and controller of air-conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a toroidal core whose winding wire is easily wound and whose core body is easy to manufacture. <P>SOLUTION: In the toroidal core 141 annular in plan view, each of two cross sections obtained by cutting the toroidal core at a diameter position has rectangular cross section shape with corners R at corner portions 141a. In another embodiment, the cross section has a shape in which two sides linearly extending along the height direction are linear, an upper bottom is convex upward and a lower bottom is convex downward. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a toroidal core and a toroidal core case, the toroidal core and a toroidal coil using the toroidal core case, and an air conditioner controller using the toroidal coil.

  For example, a choke coil may be mounted on an electric circuit incorporated in a controller or the like of an air conditioner for the purpose of a noise filter or the like. Since there are advantages such as high inductance stability and reproducibility, a toroidal coil is often used as the choke coil.

  In an electric circuit through which a large current flows, the toroidal coil that is a component incorporated in the circuit also needs to cope with the large current. That is, it is necessary to increase the cross-sectional area of the toroidal core by increasing the winding of the toroidal coil.

  However, if the winding is thick, it cannot be wound manually, so a device for winding the winding is required. As such an apparatus, for example, an apparatus disclosed in Patent Document 1 is conventionally known.

JP 2004-327461 A

  In the case of a conventional toroidal core 149 in which the shape of two cross sections appearing when a core body in a ring shape in plan view is cut at the diameter position is a rectangular shape (a perspective view of FIG. 14A and FIG. A) XIV-XIV cross-sectional view of FIG. 14 (B)), the winding is difficult to advance in the circumferential direction of the toroidal core 149 at the time of winding, so that measures are required for the device (Patent Document 1, paragraphs 0020 to 0021). And FIG. 4). Therefore, the shape of the toroidal core is preferably such that the cross-sectional shape is close to a circle or an ellipse. However, it is difficult to manufacture a toroidal core whose cross-sectional shape is a circle or an ellipse due to restrictions on the mold shape.

  The present invention has been made in view of such a conventional problem, and an object of the present invention is to provide a toroidal core capable of achieving both ease of winding and easy manufacture.

  The toroidal core according to claim 1 of the present invention is a toroidal core used for a choke coil, and two cross sections appearing when the core body in a state of being annular in a plan view is cut at its diameter position, The cross-sectional shape is a rectangle having an angle R at the corner.

  A toroidal core according to claim 2 of the present invention is a toroidal core used for a choke coil, and two cross sections appearing when the core body in a state of being annular in a plan view is cut at its diameter position, The cross-sectional shape of the two sides extending in the height direction is a straight line, the upper base is a convex shape upward, and the lower base is a convex shape downward.

  According to the first and second aspects of the invention, since the winding is wound along the curved surface formed by the curved portion having the cross-sectional shape, the winding can be easily wound. Furthermore, since the two sides extending in the height direction of the cross section are linear, the restriction on the mold shape that occurs when the cross section is a circle or an ellipse is avoided. Therefore, manufacture becomes easy compared with the toroidal core whose cross-sectional shape is a circle or an ellipse.

  A toroidal core according to a third aspect of the present invention is the toroidal core according to the first or second aspect, wherein the core body is integrally formed without a seam. When this core is used for a toroidal coil, the inductance at the same frequency is larger than that of a split core having the same cross-sectional area. That is, the performance of the toroidal coil is improved.

  The toroidal core case according to claim 4 of the present invention is a toroidal core case that covers and stores the toroidal core that is annular in a plan view, and the outer shape of the case is a curved surface having at least a corner portion having an angle R. It is made into a shape.

  A toroidal core case according to claim 5 of the present invention is a toroidal core case that covers an annular toroidal core in a plan view and stores it inside, at least the upper surface is convex upward and the lower surface is downward. The outer shape of the curved surface is a convex shape.

  According to the inventions according to claims 4 and 5, when winding the winding, the winding is wound along the curved surface formed by the curved portion having the cross-sectional shape. can do.

  The toroidal core case according to claim 6 of the present invention is a toroidal in which the cross-sectional shape of two cross sections appearing when cut at a diameter position in a ring shape in plan view is a rectangle having an angle R at a corner portion A toroidal core case having a shape capable of storing the core therein, and having an inner wall shape that is in contact with the outer shape of the toroidal core and is formed by an angle R of the rectangular corner portion, and the outer shape of the case is , At least a corner portion has a curved surface shape having an angle R.

  According to the sixth aspect of the present invention, when winding the winding, the winding is wound along the curved surface formed by the cross-sectional angle R, so that the winding is easily wound. be able to. Furthermore, since the said inner wall shape is provided, when the toroidal core of Claim 1 is stored, compared with the case where the toroidal core with a rectangular cross section is stored, the toroidal core is in the space in the toroidal core case. The proportion occupied is increased. Since the performance of the toroidal coil is determined by the cross-sectional area of the toroidal core, when the toroidal core according to claim 1 is combined with the toroidal core case according to claim 6, the toroidal core having a rectangular cross section is used. The toroidal coil can be reduced in size.

  In the toroidal core case according to claim 7 of the present invention, two cross-sectional shapes appearing when cut at a diameter position in an annular state in a plan view, and two sides extending in the height direction are linear. A toroidal core case having a shape in which an upper base is convex upward and a lower base is convex in a downward direction, and is in contact with the outer shape of the toroidal core. And an inner wall shape along a curved surface formed by the upper and lower bases, and the outer shape of the case is a curved surface formed by at least the upper and lower bases.

  According to the seventh aspect of the present invention, when winding the winding, the winding is wound along the curved surface formed by the curved portion having the cross-sectional shape, so that the winding is easily wound. be able to. Furthermore, since the said inner wall shape is provided, when the toroidal core of Claim 2 is stored, compared with the case where the cross section of a rectangular toroidal core is stored, a toroidal core is in the space in a toroidal core case. The proportion occupied is increased. Since the performance of the toroidal coil is determined by the cross-sectional area of the toroidal core, when the toroidal core according to claim 2 is combined with the toroidal core case according to claim 7, the toroidal core having a rectangular cross section is used. The toroidal coil can be reduced in size.

  A toroidal coil according to an eighth aspect of the present invention is the toroidal core according to the first aspect and a toroidal core case having a shape capable of storing the toroidal core therein, and is in contact with the outer shape of the toroidal core. A toroidal core case having an inner wall shape along a curved surface formed by a corner R of a rectangular corner portion, the outer shape of the case being a curved shape having at least a corner portion having a corner R, and edgewise wound around the case. A flat wire.

  A toroidal coil according to a ninth aspect of the present invention is the toroidal core according to the second aspect, and a toroidal core case having a shape capable of storing the toroidal core therein, in contact with the outer shape of the toroidal core. It has an inner wall shape along the curved surface formed by the upper base and the lower base, and the outer shape of the case is a toroidal core case having curved shapes of at least the upper surface and the lower surface of the toroidal core, and a flat angle that is edgewise wound around the case A line.

  A toroidal coil according to a tenth aspect of the present invention is the toroidal core according to the first aspect and a toroidal core case having a shape capable of storing the toroidal core therein, and is in contact with the outer shape of the toroidal core. A toroidal core case having an inner wall shape along a curved surface formed by a corner R of a rectangular corner portion, the outer shape of the case being a curved shape having at least a corner portion having a corner R, and an aligned winding around the case A round wire.

  A toroidal coil according to an eleventh aspect of the present invention is the toroidal core according to the second aspect, and a toroidal core case having a shape capable of storing the toroidal core therein, and is in contact with the outer shape of the toroidal core. A toroidal core case having an inner wall shape along a curved surface formed by an upper bottom side and a lower bottom side, the outer shape of the case having at least the curved shape of the upper surface and the lower surface of the toroidal core, and a round line wound in alignment with the case And comprising.

  In the toroidal coil according to claims 8 to 11, since a round wire or a rectangular wire wound edgewise is wound in an aligned manner, a wider frequency band on a higher frequency side than in the case of multiple winding of a plurality of windings. Inductance can be kept large. Therefore, the toroidal coil can be reduced in size.

  In a controller for an air conditioner according to a twelfth aspect of the present invention, the toroidal coil according to any one of the eighth to eleventh aspects is incorporated in a circuit board.

  According to the invention described in claim 12, since the miniaturized toroidal coil is used, the controller of the air conditioner can be miniaturized.

  According to the toroidal core according to the present invention, since the winding is wound along the curved surface formed by the curved portion having the cross-sectional shape, the winding can be easily wound. Furthermore, since the two sides extending in the height direction of the cross section are linear, it is easier to manufacture a mold for manufacturing the toroidal core as compared with the case where the cross section is a circle or an ellipse. Therefore, a toroidal coil suitable for an electric circuit through which a large current flows can be manufactured at low cost.

It is a figure which shows an example of the board | substrate for noise filters for the controller of the air conditioner which concerns on one Embodiment of this invention, (A) is a top view, (B) is a front view. It is an external view which shows the outline of the toroidal coil which concerns on one Embodiment of this invention. It is a figure which shows the relationship between a frequency and an inductance about the toroidal coil by which the coil | winding was wound in alignment, and the toroidal coil by which the coil | winding was multiply wound. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the outline in the state except the winding of the toroidal coil which concerns on one Embodiment of this invention, (A) is an external view, (B) divides a toroidal core case up and down, It is the figure shown so that the toroidal core stored in the inside of a case could be seen. FIG. 5 is a diagram showing a positional relationship with the toroidal core case according to one embodiment of the present invention stored in the toroidal core case according to one embodiment of the present invention, and is a VV in FIG. It is sectional drawing. FIG. 6 is a diagram showing only the toroidal core except for the toroidal core case from FIG. 5. It is a figure which shows the positional relationship with this toroidal core case when storing the toroidal core shown in FIG. 6 in the toroidal core case which concerns on other embodiment of this invention different from the toroidal core case shown in FIG. It is a figure which shows the relationship between a frequency and an inductance about an integral core and a division | segmentation core. It is sectional drawing for demonstrating the shape of the toroidal core which concerns on other embodiment of this invention. It is a figure which shows the positional relationship with this toroidal core case when the toroidal core shown in FIG. 9 is stored in the toroidal core case according to another embodiment of the present invention. It is a figure which shows the positional relationship with this toroidal core case when storing the toroidal core shown in FIG. 9 in the toroidal core case which concerns on other embodiment of this invention different from the toroidal core case shown in FIG. It is an external view which shows the outline of the toroidal coil which concerns on other embodiment of this invention. It is a figure which shows an example of the conventional toroidal coil. It is a figure which shows this toroidal core of the state stored in the toroidal core of the conventional cross-sectional shape, and a toroidal core case, (A) is a perspective view of this toroidal core, (B) is XIV-XIV of (A). Sectional drawing (C) is a sectional view showing the positional relationship between the toroidal core case and the toroidal core case stored in the toroidal core case.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 shows an example of a noise filter substrate 1 (circuit board) for a controller of an air conditioner according to an embodiment of the present invention. FIG. 1A is a plan view of the noise filter substrate 1, and FIG. 1B is a front view of the noise filter substrate 1.

  In the noise filter substrate 1, the toroidal coil 100 according to the embodiment of the present invention is placed on the choke coil base 200 and disposed on the printed circuit board 300. Note that a terminal 190 is connected to the end of the winding of the toroidal coil 100 (see FIG. 2), and the terminal 190 is connected to the printed circuit board 300, but the terminal 190 is not shown in FIG. .

  FIG. 2 is an external view showing an outline of the toroidal coil 100. In the present embodiment, the toroidal coil 100 is a three-phase toroidal coil, and is used as a common mode choke coil for removing common mode noise. The toroidal coil 100 includes a toroidal core 140 (see FIG. 4), a toroidal core case 120 that houses the toroidal core 140 therein, and a winding 130 wound around the toroidal core case 120. In addition, since the toroidal core 140 is stored in the inside of the toroidal core case 120, it is not illustrated in FIG. 2 which is an external view of the toroidal coil 100.

  In order to cope with a large current of, for example, 45 A flowing through the controller of the air conditioner, the winding wire 130 of the toroidal coil 100 is a rectangular wire that is aligned and edgewise wound. The aligned winding means winding the windings uniformly so as not to overlap, and the edgewise winding is winding so that the longitudinal direction of the rectangular cross section of the rectangular wire is perpendicular to the winding core. That is. A terminal 190 for connecting the winding 130 to the printed circuit board 300 is connected to the end of the winding 130.

  If electrical noise is mixed in the electrical circuit that constitutes the controller or the like of the air conditioner, problems such as malfunction of the device may occur. Therefore, normally, a noise filter circuit for removing electrical noise is provided in the electrical circuit. In the present embodiment, the noise filter circuit is formed on the noise filter substrate 1 and mounted on the controller of the air conditioner. The target of noise filtering is common mode noise that flows in the electric circuit constituting the controller.

  The advantage of aligning the winding 130 will be described below in comparison with a conventional toroidal coil. FIG. 13 is a diagram illustrating an example of a conventional toroidal coil. In the conventional toroidal coil 110 that is manually wound, it is impossible to manually wind a thick winding. Therefore, the winding cannot be thickened to cope with a large current. Therefore, as shown in FIG. 13, a plurality of (two in FIG. 13) thin windings 139 are wound around the toroidal core case 128 in a multiplex manner (hereinafter referred to as multiplex winding) to ensure the cross-sectional area of the windings. Was.

  FIG. 3 is a diagram showing the relationship between the frequency and the inductance for the toroidal coil in which the windings are wound in an aligned manner and the toroidal coil in which the windings are multiply wound. As shown in FIG. 3, the toroidal coil in which the windings are aligned and wound can maintain a constant inductance in a wider frequency band on the high frequency side than the toroidal coil in which the windings are wound in multiple turns.

  In the case of the conventional multiple winding, a space is naturally multiplied between the overlapping windings 139, so that the space factor of the windings is lowered. Therefore, it is necessary to enlarge the toroidal core in order to wind the winding amount necessary to cope with a large current. In addition, as shown in FIG. 3, when multiple winding is performed, the performance of the toroidal coil is lowered in a high frequency region. In order to make up for this decrease in performance, it was necessary to increase the number of turns further, and the vicious circle of toroidal coils became increasingly larger. As a result, when the toroidal coil is made to have a large current, there is a problem that the processing cost and material cost increase and the cost increases.

  On the other hand, in this embodiment, by using the aligned and wound rectangular wire for the winding 130, the performance of the toroidal coil is improved in the high frequency region and the space factor of the winding is improved as shown in FIG. be able to. Therefore, the toroidal coil can be made smaller than in the case of multiple winding. Moreover, since processing costs and material costs can be reduced, the cost can be reduced.

  Further, by arranging the windings 130 in an aligned manner, the heat dissipation of the windings 130 becomes better than in the case of multiple windings, and the temperature rise inside the controller due to the heat generation of the windings 130 is reduced. Therefore, it becomes easy to take measures against overheating of the controller.

  FIG. 4 is a diagram showing an outline of the toroidal coil 100 with the winding 130 removed. FIG. 4A is an external view, and FIG. 4B is a diagram showing the toroidal core 140 stored inside the toroidal core case 120 so that the toroidal core case 120 can be seen. It is.

  The toroidal core case 120 includes a case main body 120A that houses the toroidal core 140 therein, and a partition plate 120B that separates the three-phase windings 130 from each other. In order to store the toroidal core 140 inside, the toroidal core case 120 can be divided into an upper case 120C and a lower case 120D. The upper case 120C and the lower case 120D have corresponding engagement portions (not shown), and are integrally engaged by the engagement portions.

  FIG. 5 is a diagram showing a positional relationship between the toroidal core 140 stored in the toroidal core case 120 and the toroidal core case 120, and is a cross-sectional view taken along the line VV in FIG. FIG. 6 is a view showing only the toroidal core 140 excluding the toroidal core case 120 from FIG. 5. FIG. 14 is a diagram showing a conventional toroidal core 149 having a rectangular cross-sectional shape and a toroidal core 149 stored in a toroidal core case 129. 14A is a perspective view of the toroidal core 149, FIG. 14B is a sectional view taken along the line XIV-XIV of FIG. 14A, and FIG. 14C is a toroidal core stored in the toroidal core case 129. 149 is a cross-sectional view showing the positional relationship with respect to the toroidal core case 129.

  A toroidal core 140 according to an embodiment of the present invention will be described below in comparison with a conventional toroidal core 149.

  The toroidal core 140 has two cross-sectional shapes that appear when a core body in a ring shape in plan view is cut at the diameter position, and two sides 140b and 140c extending in the height direction are linear. The upper and lower bases 140a have cross-sectional shapes that are convex upward and downward, respectively.

  In the case of the conventional toroidal core 149 having a rectangular cross-sectional shape, the winding is difficult to advance in the circumferential direction of the toroidal core 149 at the time of winding, and thus a countermeasure is required for the device (Patent Document 1, paragraphs 0020 to 0021 and FIG. 4).

  On the other hand, in the case of the toroidal core 140, when the winding 130 is wound directly around the toroidal core 140, the winding 130 is wound along the upper and lower curved surfaces of the toroidal core 140. Can turn. However, in this embodiment, the winding 130 is wound around the toroidal core case 120 that houses the toroidal core 140.

  The inner wall shape of the toroidal core case 120 is in contact with the outer shape of the toroidal core 140 and is shaped to follow the outer shape of the toroidal core 140. Since the toroidal core case 120 is formed with a predetermined constant thickness, the outer wall shape of the toroidal core case 120 is similar to the cross-sectional shape of the toroidal core 140. That is, two cross-sectional shapes that appear when the case main body 120A in an annular state in a plan view is cut at the diameter position, the two sides 120b and 120c extending in the height direction are straight, The base 120a has a cross-sectional shape that is convex upward and downward, respectively. Since the winding 130 is wound along the upper and lower curved surfaces of the toroidal core case 120 at the time of winding, the winding 130 can be easily wound.

  Here, in order to facilitate winding of the winding using the conventional toroidal core 149 having a rectangular cross-sectional shape, the cross-sectional shape of the toroidal core case remains elliptical and the outer cross-section of the toroidal core case is elliptical. Assume that (FIG. 14C).

  In this case, a space S is generated between the toroidal core 149 and the toroidal core case 120 due to the difference in cross-sectional shape between the two. Since the performance of the toroidal coil is determined by the cross-sectional area of the toroidal core, the space S is completely useless. That is, the toroidal coil is enlarged by the space S, and the controller on which the toroidal coil is mounted is also enlarged.

  On the other hand, the toroidal core 140 is in close contact with the inner wall of the toroidal core case 120. Therefore, since no useless space is generated, the toroidal coil can be downsized. As a result, the controller of the air conditioner on which the toroidal coil 100 is mounted can be downsized.

  As shown in FIG. 7, the inner wall shape of the toroidal core case is in contact with the curved surface formed by the upper and lower bases 140a that are convex upward and downward in the cross section of the toroidal core 140. And a shape along the curved surface, with respect to the curved surface formed by the two sides 140b and 140c extending in the height direction of the cross section of the toroidal core 140, and the plane formed by the upper and lower bases 140a. Is non-contact, and may be an ellipse, not a shape along the curved surface and the plane.

  In this case, since the toroidal core case 121 is formed with a predetermined constant thickness, the outer wall shape also has an elliptical cross section. Although the toroidal core case 121 does not completely adhere to the inner wall of the toroidal core case 120, the proportion of the volume of the toroidal core 140 in the volume inside the toroidal core case 121 is larger than that of the conventional toroidal core 149. Therefore, since the useless space is reduced, the toroidal coil can be downsized. As a result, the controller of the air conditioner on which the toroidal coil 100 is mounted can be downsized.

  Furthermore, since the toroidal core case 121 has no straight portion in the cross section of the outer wall, the followability of the winding 130 to the outer wall surface of the toroidal core case is improved, so that the winding 130 is easier than when the toroidal core case 120 is used. Can be wound on.

  By the way, since the winding 130 is wound along the upper and lower curved surfaces of the toroidal core case 120 at the time of winding, the curved surface of the toroidal core case 120 formed by the inner peripheral portion of the winding 130 and the sides 120b and 120c. There is a gap between the two. In order to maximize the volume of the toroidal core and maximize the performance of the toroidal coil, the toroidal core case 121 is used and the cross-sectional shape of the toroidal core is made to coincide with the inner wall shape of the toroidal core case 121 to be an ellipse. Is ideal.

  However, it is difficult to manufacture a toroidal core whose cross-sectional shape is a circle or an ellipse due to restrictions on the mold shape. Since the two sides of the toroidal core 140 extending in the height direction of the cross section are linear, the toroidal core 140 is free from restrictions on the mold shape that occurs when the cross section is a circle or an ellipse. Since the toroidal core 140 has this cross-sectional shape, the toroidal core 140 can be easily manufactured as compared with a toroidal core having a circular or elliptical cross-sectional shape. That is, by using the toroidal core 140, both ease of manufacturing the toroidal core and downsizing of the toroidal coil can be achieved.

  If the conventional two-phase or three-phase toroidal coil cannot be wound manually, the coil is wound on a toroidal core (divided core) that is divided into two or three to facilitate winding. The divided cores were combined after winding and winding. On the other hand, as shown in FIG. 4B, the toroidal core 140 is integrally formed without a seam (integrated core).

  FIG. 8 is a diagram illustrating the relationship between the frequency and the inductance for the integral core and the split core. As shown in FIG. 8, if the cross-sectional areas are the same, the integral core exhibits a larger inductance than the split core for the same frequency. Therefore, since the toroidal core can be reduced in size, the toroidal coil can be reduced in size.

  As described above, the toroidal cores 140 and 141, the toroidal core cases 120 and 121, the toroidal coil 100, and the controller of the air conditioner according to the embodiment of the present invention have been described. However, the present invention is not limited to this, for example, The following modified embodiment can also be taken.

  (1) In the above-described embodiment, the toroidal core 140 has two sides in which two cross-sectional shapes that appear when a core body in a ring shape in a plan view is cut at its diameter position are opposed to each other in the height direction. 140b and 140c are linear, and the upper and lower bases 140a have cross-sectional shapes that are convex upward and downward, respectively.

  Instead, as shown in the cross-sectional view of FIG. 9, the two cross-sectional shapes that appear when the core body in an annular shape in a plan view is cut at the diameter position are linear heights. The rectangular corner portion 141d may be a toroidal core 141 having a cross-sectional shape having an angle R. The rectangle has a rectangular shape including two sides 141b and 141c and upper and lower bases 141a. When winding the winding 130 directly on the toroidal core 141, the winding 130 is wound along the corner R formed at the corner portion of the toroidal core 140, so that the winding 130 can be easily wound. it can.

  FIG. 10 is a cross-sectional view illustrating the positional relationship between the toroidal core 141 stored in the toroidal core case 122 and the toroidal core case 122.

  The inner wall shape of the toroidal core case 122 is a shape that contacts the outer shape of the toroidal core 141 and that follows the outer shape of the toroidal core 141. Since the toroidal core case 122 is formed with a predetermined thickness, the outer wall shape of the toroidal core case 122 is similar to the cross-sectional shape of the toroidal core 141. That is, two cross-sectional shapes appearing when the case body in a ring shape in plan view is cut at the diameter position are two sides 121a and 121b extending in the height direction that are both linear, and upper and lower It is a rectangle composed of a base 121a, and the corner portion 121d of the rectangle has a cross-sectional shape having an angle R. Since the winding 130 is wound along the corner R of the corner portion of the toroidal core case 122 at the time of winding, the winding 130 can be easily wound.

  As shown in FIG. 11, the inner wall shape of the toroidal core case is in contact with the curved surface formed by the corner portion 141d of the cross section of the toroidal core 141, and has a shape along the curved surface. , The curved surface formed by the two sides 141b and 141c extending in the height direction of the cross section of the toroidal core 141, and the plane formed by the upper and lower bases 141a are non-contacting, and the curved surface and the The toroidal core case 123 having an elliptical shape that is not a shape along the plane is the same as in the case of the toroidal core case 121 of the above embodiment, and the effect is the same as that of the toroidal core case 121.

  (2) In the embodiment described above, the toroidal coil 100 uses a rectangular wire for the winding 130, and the winding 130 is wound edgewise and aligned. Alternatively, as shown in FIG. 12, a toroidal coil 101 including a winding 131 in which round wires are aligned and wound may be used.

  (3) In the above embodiment, the toroidal coil 100 is a three-phase toroidal coil, but the toroidal coil is not limited to a three-phase, for example, a single-phase, two-phase, or four-phase The present invention is also applicable. In addition, the partition plate 120B of the toroidal core case 120 is not provided when the toroidal coil is a single phase, but is provided when the toroidal coil is a single phase, two when it is a two-phase, and four when a four-phase.

  (4) In the above embodiment, the toroidal coil 100 is used as a common mode choke coil that removes common mode noise. However, the toroidal coil removes normal mode noise by winding the winding in a normal mode. It may be used as a normal mode choke coil, and the use of the toroidal coil is not limited to a noise filter.

1 Noise filter substrate (circuit board)
100, 101 Toroidal coil 120-123 Toroidal core case 130 Winding (flat wire)
131 Winding (round wire)
140, 141 toroidal core

Claims (12)

Toroidal core used for choke coil,
Two cross-sections that appear when the core body (141) in an annular shape in plan view is cut at the diameter position are toroidal cores whose cross-sectional shape is a rectangle having an angle R at the corner (141d). Toroidal core used for choke coil,
The two cross sections appearing when the core body (140) in an annular shape in a plan view is cut at the diameter position are two sides (140b, 140c) in which the cross-sectional shape extends facing the height direction is a straight line. A toroidal core in which the upper base (140a) is convex upward and the lower base (140a) is convex downward.   The toroidal core according to claim 1 or 2, wherein the core body (140, 141) is integrally formed without a seam.   A toroidal core case that covers a toroidal core that is annular in plan view and stores the toroidal core inside, the outer shape of the case being a curved shape with at least a corner portion having an angle R.   A toroidal core case that covers a toroidal core that is annular in a plan view and stores it inside, at least having a curved outer shape with an upper surface convex upward and a lower surface convex downward .   A toroidal shape in which a cross-sectional shape of two cross sections appearing when cut at a diameter position in a ring shape in plan view can store therein a toroidal core (141) having a rectangular shape with an angle R at the corner portion. A core case having an inner wall shape along a curved surface formed by an angle R of the rectangular corner portion (141d) in contact with the outer shape of the toroidal core (141), and the outer shape of the case includes at least a corner portion A toroidal core case having a curved shape with an angle R.   The two sides (140b, 140c) extending in the height direction of the cross-sectional shape of the two cross sections appearing when cut at a diameter position in a ring shape in plan view are straight and the upper base (140a) Is a toroidal core case having a shape in which a toroidal core (140) having a convex shape in the upward direction and a bottom bottom side (140a) in a convex shape in the downward direction can be stored therein, and is in contact with the outer shape of the toroidal core. And an inner wall shape along a curved surface formed by the upper base (140a) and the lower base (140a), and the outer shape of the case is a curved surface formed by at least the upper base (140a) and the lower base (140a). Shaped toroidal core case. Toroidal core (141) according to claim 1,
A toroidal core case (122) having a shape capable of storing the toroidal core (141) therein, and is formed by an angle R of the rectangular corner portion (141d) in contact with the outer shape of the toroidal core (141). A toroidal core case (122) having an inner wall shape along the curved surface, and an outer shape of the case (122) having a curved shape in which at least a corner portion has an angle R;
A toroidal coil comprising a rectangular wire (130) wound edgewise around the case (122). Toroidal core (140) according to claim 2,
A toroidal core case (120) having a shape capable of storing the toroidal core (140) therein, and is formed by the upper base (140a) and the lower base (140a) in contact with the outer shape of the toroidal core (140). A toroidal core case (120) having a curved shape of at least the upper surface and the lower surface of the toroidal core (140).
A toroidal coil comprising a rectangular wire (130) wound edgewise around the case (120). Toroidal core (141) according to claim 1,
A toroidal core case (122) having a shape capable of storing the toroidal core (141) therein, and is formed by an angle R of the rectangular corner portion (141d) in contact with the outer shape of the toroidal core (141). A toroidal core case (122) having an inner wall shape along the curved surface, and an outer shape of the case (122) having a curved shape in which at least a corner portion has an angle R;
A toroidal coil comprising: a round wire (131) wound around the case; Toroidal core (140) according to claim 2,
A toroidal core case (120) having a shape capable of storing the toroidal core (140) therein, and is formed by the upper base (140a) and the lower base (140a) in contact with the outer shape of the toroidal core (140). A toroidal core case (120) provided with a curved shape on at least the upper surface and the lower surface of the toroidal core (140).
A toroidal coil comprising: a round wire (131) wound around the case (120);   The controller of the air conditioner by which the toroidal coil (100, 101) in any one of Claims 8-11 was integrated in the circuit board (1).