JP2003324871A - Electric appliance - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric appliance capable of globally suppressing nonuniform thermal conduction. <P>SOLUTION: The electric appliance comprises a stator (1), a rotor (6) that rotates by magnetic interaction received from the stator (1), and a case (2) that covers the stator (1). In the stator (1) or the case (2), through-holes (1a, 2a) are formed which penetrate the stator (1) or the case (2) and spirally extend around a rotating shaft of the rotor (6). A cooling medium (10) for cooling the stator (1) flows to the through-holes (1a, 2a). The flow of the cooling medium (10) is not rectified, since the cooling medium (10) spirally flows to the stator (1), and thus nonuniform thermal conduction is suppressed globally in the electric appliance. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to an electric device,
In particular, the present invention relates to an electric device that suppresses a temperature rise of a magnetic path former.

[0002]

2. Description of the Related Art FIG. 14 is a perspective view showing a conventional electric device (example: electric motor). As shown in FIG. 14, a conventional electric device includes a magnetic path forming body 10 that is a stationary stator.
1 (hereinafter, referred to as a stator 101), an opposed magnetic path forming body 106 (hereinafter, referred to as a rotor 106) that is a rotating rotor, and a casing 102. The rotor 106 is provided concentrically with the stator 101. The rotor 106 includes a main shaft 107 and an opposed magnetic path forming body main body 108 (hereinafter referred to as the rotor main body 108). The main shaft 107 is a rotating shaft of the rotor 106, and is concentrically joined to the rotor body 108. Rotor body 1
Reference numeral 08 has a facing surface facing the stator 101, and a permanent magnet and a field coil (not shown) are joined to the facing surface.

The stator 101 has three teeth. The stator 101 includes a circumferential magnetic path forming portion 103 and a radial magnetic path forming portion 104 coupled to the circumferential magnetic path forming portion 103 and extending in the radial direction. The radial direction magnetic path forming portions 104 are held on the same circumference side by side at equal intervals and face the rotor 106 with a minute gap therebetween. The radial magnetic path forming portion 104 includes one of the three teeth, and a coil (not shown) for forming a magnetic field path is wound around the rotor 106. A coil (not shown) is supplied with an electric current to generate a rotating magnetic field. Rotational force is applied to the rotor 106 by the magnetic interaction between the generated rotating magnetic field and the field magnetic flux generated by the permanent magnet and the field coil (not shown).

The casing 102 is a case that covers the stator 101, and includes the stator 101 and the casing 102.
Are combined concentrically (concentric circles or concentric polygons). The stator 101 generates heat due to eddy current and hysteresis loss. The casing 102 is the stator 101.
It is also used to radiate the temperature rise due to the heat generation of the stator 101, and the heat generated by the stator 101 is conducted to the casing 102. However, when the contact area between the stator 101 and the casing 102 is small, it is difficult to radiate the temperature rise due to the heat generation of the stator 101.

Therefore, in order to cool (suppress) the temperature rise due to heat generation of the stator 101, as shown in FIG. 15, on the inner peripheral surface 102b of the casing 102, the main shaft 107 of the main shaft 107 is parallel to the main shaft 107. A linear through hole 102a extending in the direction (axial direction) is formed. The through hole 102a is composed of a groove formed on the inner peripheral surface of the casing 102. The through holes 102a are held side by side at equal intervals on the same circumference and are used as cooling passages for passing the cooling medium 110 in the axial direction.

Further, as shown in FIG. 16, the surface 10 on the outer peripheral side of the circumferential magnetic path forming portion 103 of the stator 101.
A linear through hole 101a extending in the axial direction parallel to the main shaft 107 is formed in the 1b. This through hole 10
1a denotes a stator 101 (circumferential magnetic path forming portion 10
3) The groove is formed on the outer peripheral surface. The through holes 101a are held side by side at equal intervals on the same circumference and are used as cooling passages for passing the cooling medium 110 in the axial direction.

Further, as shown in FIG. 17, the main shaft 107 is formed in the circumferential magnetic path forming portion 103 of the stator 101.
A linear through-hole 103a extending in the axial direction is formed in parallel with. The through holes 103a are held side by side at equal intervals on the same circumference, and the cooling medium 11 is arranged in the axial direction.
Used as a cooling passage for passing zero.

[0008]

However, the inner peripheral side of the casing 102, the outer peripheral side of the stator 101 (circumferential magnetic path forming portion 103), and the stator 101 (circumferential magnetic path forming portion 103) are provided. Through holes 102a, 10
In 1a and 103a, since the flow of the cooling medium 110 is rectified, it is difficult to suppress nonuniform flow (nonuniform heat conduction). Therefore, in the conventional electric device, the cooling medium 110 cannot efficiently cool the stator 101.

An object of the present invention is to provide an electric device capable of suppressing uneven heat conduction globally.

[0010]

[Means for Solving the Problems] Means for solving the problems will be described below with reference to the numbers and symbols used in the embodiments of the present invention. These numbers and signs are added to clarify the correspondence between the description in [Claims] and the description in [Embodiment of the Invention], but in [Claims] It should not be used to interpret the technical scope of the described invention.

The electric equipment of the present invention comprises a stator (1),
A rotor (6) rotating by magnetic interaction received from the stator (1) and a case (2) covering the stator (1).
It has and. Examples of the electric device include a motor and a generator. The stator (1) or the case (2) is provided with through holes (1a, 2a) penetrating the stator (1) or the case (2) and spirally extending around the rotation axis of the rotor (6). There is. The through holes (1a, 2a) are used as cooling passages for passing the cooling medium (10) in the rotation axis direction. A cooling medium (10) for cooling the stator (1) flows through the through holes (1a, 2a). As described above, in the electric device of the present invention, the flow of the cooling medium (10) is unrectified by spirally flowing the cooling medium (10) in the stator (1), thereby suppressing uneven heat conduction globally. be able to. Thus, in the electric device of the present invention, the cooling medium (10) can efficiently cool the stator (1).

The electric equipment of the present invention comprises a stator (1),
A rotor (6) that rotates by magnetic interaction received from the stator (1). Examples of the electric device include a motor and a generator. The stator (1) is provided with a through hole (3a) penetrating the stator (1) and extending in the rotation axis direction of the rotor (6). The through hole (3a) is
It is used as a cooling passage for passing the cooling medium (10) in the direction of the rotation axis. A cooling medium (10) for cooling the stator (1) flows through the through hole (3a). Through hole (3
At least a part of a) is provided with protrusions (3c, 3d) for non-rectifying the flow of the cooling medium (10). The protrusion (3c) narrows down a part of the cooling passage. That is, by providing a throttle in the middle of the cooling passage, when the cooling medium (10) flows into the through hole (3a), the flow of the cooling medium (10) becomes non-rectified. The protrusions (3d) are arranged at equal intervals on the same circumference of the through hole (3a) and form spiral fins in the cooling passage. By forming the fins in the cooling passage, when the cooling medium (10) flows through the through hole (3a), the flow of the cooling medium (10) becomes non-rectified. As described above, in the electric device of the present invention, the flow of the cooling medium (10) is not rectified, so that the uneven heat conduction can be suppressed globally. Thus, in the electric device of the present invention, the cooling medium (10) can efficiently cool the stator (1).

The electric equipment of the present invention comprises a stator (1),
A rotor (6) rotating by magnetic interaction received from the stator (1) and a case (2) covering the stator (1).
It has and. Examples of the electric device include a motor and a generator. The stator (1) and the case (2) are joined,
It has an uneven shape. As the concavo-convex shape, the projection (11a) (projection) provided on the case (2) and the stator (1) are provided.
And the groove (11b) (recess) provided in the. The stator (1) and the case (2) are joined by the protrusions (11a) and the grooves (11b), so that the contact area between the stator (1) and the case (2) is increased. Therefore, the heat generated by the stator (1) is efficiently conducted to the case (2). Thus, in the electric device of the present invention,
By utilizing efficient heat conduction, it is possible to suppress uneven heat conduction globally. Further, in the electric device of the present invention, the further effect of preventing the displacement in the rotation axis direction can be realized by the protrusion (11a) and the groove (11b).

Further, the stator (1) or the case (2) penetrates the stator (1) or the case (2), and a through hole (1) spirally extending around the rotation axis of the rotor (6).
a, 2a) are provided. Through holes (1a, 2a)
Are used as cooling passages for passing the cooling medium (10) in the direction of the rotation axis. A cooling medium (10) for cooling the stator (1) flows through the through holes (1a, 2a).
As described above, in the electric device of the present invention, the flow of the cooling medium (10) is unrectified by spirally flowing the cooling medium (10) in the stator (1), thereby suppressing uneven heat conduction globally. be able to. Thus, in the electric device of the present invention, the cooling medium (10) can efficiently cool the stator (1).

Further, the stator (1) is provided with a through hole (3a) which penetrates the stator (1) and extends in the rotation axis direction of the rotor (6). The through hole (3a) is used as a cooling passage for passing the cooling medium (10) in the rotation axis direction. A cooling medium (10) for cooling the stator (1) flows through the through hole (3a). Through hole (3
At least a part of a) is provided with protrusions (3c, 3d) for non-rectifying the flow of the cooling medium (10). The protrusion (3c) narrows down a part of the cooling passage. That is, by providing a throttle in the middle of the cooling passage, when the cooling medium (10) flows into the through hole (3a), the flow of the cooling medium (10) becomes non-rectified. The protrusion (3d) forms a spiral fin in the cooling passage. By forming fins in the cooling passage, the cooling medium (1
0) flows, the flow of the cooling medium (10) becomes unrectified. As described above, in the electric device of the present invention, the flow of the cooling medium (10) is not rectified, so that the uneven heat conduction can be suppressed globally. Thus, in the electric device of the present invention, the cooling medium (10) can efficiently cool the stator (1).

The electric equipment of the present invention comprises a magnetic path forming body (21,
41). Examples of electrical equipment include transformers and actuators. In the magnetic path former (21, 41),
The magnetic path former (21, 41) is penetrated and the magnetic path former (2
A through hole (3a) extending from one end surface of the (1, 41) toward the opposite end surface is provided. The through hole (3a) is
In the direction perpendicular to the magnetic path of the magnetic path former 21, the cooling medium (1
0) used as a cooling passage. Through hole (3
A cooling medium (10) for cooling the magnetic path formers (21, 41) flows in a). At least a part of the through hole (3a) is provided with protrusions (3c, 3d) for non-rectifying the flow of the cooling medium (10). The protrusion (3c) narrows down a part of the cooling passage. That is, by providing a throttle in the middle of the cooling passage, when the cooling medium (10) flows into the through hole (3a), the flow of the cooling medium (10) becomes non-rectified. The protrusions (3d) are arranged at equal intervals on the same circumference of the through hole (3a) and form spiral fins in the cooling passage. By forming the fins in the cooling passage, when the cooling medium (10) flows through the through hole (3a), the flow of the cooling medium (10) becomes non-rectified. As described above, in the electric device of the present invention, the flow of the cooling medium (10) is not rectified, so that the uneven heat conduction can be suppressed globally. Thus, in the electric device of the present invention, the cooling medium (10) can efficiently cool the stator (1).

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of electric equipment according to the present invention will be described below with reference to the accompanying drawings. The electric device of the present invention suppresses the temperature rise of the magnetic path former,
This magnetic path forming body is used for an electric motor, a generator, a transformer and an actuator.

(First Embodiment) FIG. 1 shows the first embodiment.
It is an inclination view which shows the electric equipment (motor or generator) which concerns on. As shown in FIG. 1, the electric device according to the first embodiment includes a magnetic path forming body 1 (hereinafter referred to as a stator 1) that is a stationary stator and an opposing magnetic path that is a rotating rotor. Forming body 6 (hereinafter referred to as rotor 6) and casing 2
It has and. The rotor 6 is provided concentrically with the stator 1. The rotor 6 includes a main shaft 7 and an opposed magnetic path forming body 8 (hereinafter referred to as a rotor body 8).
The main shaft 7 is a rotating shaft of the rotor 6 and is concentrically joined to the rotor body 8. The rotor body 8 has a facing surface facing the stator 1, and a permanent magnet and a field coil (not shown) are joined to the facing surface.

The stator 1 has N teeth (N is a positive number of 2 or more).
Have. The stator 1 includes a circumferential magnetic path forming portion 3 and
And a radial magnetic path forming portion 4 which is coupled to the circumferential magnetic path forming portion 3 and extends in the radial direction. The radial magnetic path forming portions 4 are held side by side at equal intervals on the same circumference and face the rotor 6 with a minute gap.
The radial magnetic path forming portion 4 includes at least one of N teeth, and a coil (not shown) for forming a magnetic field path is wound around the rotor 6. A coil (not shown) is supplied with an electric current to generate a rotating magnetic field. The generated rotating magnetic field,
Rotational force is applied to the rotor 6 by magnetic interaction with a field magnetic flux generated by a permanent magnet and a field coil (not shown).

The casing 2 is a case that covers the stator 1, and the stator 1 and the casing 2 are concentrically combined (concentric circles or concentric polygons). The casing 2 is formed with a through hole 2 a which penetrates the casing 2 and extends spirally around the main shaft 7. Through hole 2a
Are held side by side at equal intervals on the same circumference of the casing 2 and are used as cooling passages for passing the cooling medium 10. The cooling medium 10 is a medium for cooling the stator 1 that has generated heat due to eddy current and hysteresis loss.

FIG. 2 is a sectional view taken along the line AA 'of FIG. As shown in FIG. 2, the stator 1 (circumferential direction magnetic path forming portion 3, radial direction magnetic path forming portion 4) includes a plurality of element steel plates 9.
(Example: silicon steel sheet) is laminated. The plurality of element steel plates 9 are sequentially arranged adjacent to each other. On the inner peripheral surface 2b of the casing 2, the stator 1
When the casing and the casing 2 are combined, the through hole 2a
The groove 2c is formed (provided) so that The cooling medium 10 flows through the through holes 2a (grooves 2c). That is, the stator 1 (circumferential magnetic path forming portion 3)
The cooling medium 10 flows in a spiral manner.

As described above, in the electric device according to the first embodiment, the flow of the cooling medium 10 spirally flows in the stator 1 so that the flow of the cooling medium 10 is not rectified and the uneven heat conduction is suppressed globally. can do. As a result, in the electric device according to the first embodiment, the cooling medium 10 can efficiently cool the stator 1.

(Second Embodiment) FIG. 3 shows the second embodiment.
It is an inclination view which shows the electric equipment (motor or generator) which concerns on. In the second embodiment, the same constituents as those in the first embodiment are designated by the same reference numerals, and the duplicated description of the first embodiment will be omitted.

In the electric device according to the second embodiment, the stator 1 is replaced with the through hole 2a described in the first embodiment.
The (circumferential direction magnetic path forming portion 3) is formed with a through hole 1a penetrating the stator 1 (circumferential direction magnetic path forming portion 3) and spirally extending around the main shaft 7. The through hole 1a is
It is held on the same circumference of the stator 1 side by side at equal intervals,
In addition, it is used as a cooling passage for passing the cooling medium 10.

FIG. 4 is a sectional view taken along line BB 'of FIG. As shown in FIG. 4, a through hole 1a is formed in the outer peripheral surface 1b of the stator 1 (circumferential magnetic path forming portion 3) when the stator 1 and the casing 2 are combined. , The groove 1c is formed (provided).
This groove 1c is provided in the plurality of element steel plates 9, and when the plurality of element steel plates 9 are arranged adjacent to each other, the groove 1c spirally extending around the main shaft 7 is provided in the stator 1 (circumferential magnetic field). It is formed on the outer peripheral surface 1b of the path forming portion 3). Through hole 1a
The cooling medium 10 flows in the (groove 1c). That is, the cooling medium 10 spirally flows through the stator 1 (circumferential magnetic path forming portion 3).

As described above, in the electric device according to the second embodiment, the flow of the cooling medium 10 spirally flows in the stator 1 so that the flow of the cooling medium 10 is not rectified and the non-uniform heat conduction is suppressed globally. can do. Thereby, in the electric device according to the second embodiment, the cooling medium 10 can efficiently cool the stator 1.

(Third Embodiment) FIG. 5 shows the third embodiment.
It is an inclination view which shows the electric equipment (motor or generator) which concerns on. In the third embodiment, the same components as those in the first and second embodiments are designated by the same reference numerals, and the duplicated description of the first and second embodiments will be omitted.

In the electric device according to the third embodiment, the through hole 3a penetrating the circumferential magnetic path forming portion 3 of the stator 1 is formed.
Are formed. The through hole 3a extends in the rotation axis direction. The rotation axis direction is the direction of the main shaft 7 (rotation axis),
It is also a direction orthogonal to the magnetic path of the stator 1. Through hole 3a
Are held side by side at equal intervals on the same circumference of the stator 1 and are used as cooling passages for passing the cooling medium 10 in the direction of the rotation axis.

FIG. 6 is an enlarged sectional view of a portion C in FIG. As shown in FIG. 6, the plurality of element steel plates 9 (circumferential direction magnetic path forming portions 3) are provided with through holes provided with protrusions when the plurality of element steel plates 9 are arranged adjacent to each other. Through holes 3b are formed (provided) so that 3a is formed. In this case, the through hole 3b formed in at least one element steel plate 9 of the plurality of element steel plates 9 is provided with a protrusion 3c extending from the circumference of the through hole 3b in the radial direction of the through hole 3b. ing. The protrusion 3c does not rectify the flow of the cooling medium. A part of the cooling passage is narrowed by the protrusion 3c. That is, by providing a throttle in the middle of the cooling passage, when the cooling medium 10 flows into the through hole 3a (through hole 3b), the flow of the cooling medium 10 becomes non-rectified.

As described above, in the electric device according to the third embodiment, non-rectification of the flow of the cooling medium 10 makes it possible to suppress uneven heat conduction globally. Thus, in the electric device according to the third embodiment, the cooling medium 1
With 0, the stator 1 can be efficiently cooled.

(Fourth Embodiment) FIG. 7 is an enlarged sectional view of a portion C in FIG. In the fourth embodiment, the first embodiment
The same constituents as those of the first to third embodiments are designated by the same reference numerals, and the description overlapping with those of the first to third embodiments is omitted.

As shown in FIG. 7, a plurality of element steel plates 9
, When a plurality of element steel plates 9 are arranged adjacent to each other,
The through hole 3b is formed (provided) so that the through hole 3a extending in the rotation axis direction and provided with the spiral fin therein is formed. In this case, multiple element steel plates 9
In the through hole 3b formed in, there is formed a protrusion 3d extending from the circumference of the through hole 3b in the radial direction of the through hole 3b. The protrusions 3d are held side by side at equal intervals on the same circumference of the through hole 3b and form spiral fins in the cooling passage. The protrusion 3d forms a spiral fin in the cooling passage to make the flow of the cooling medium non-rectified. For example, the first element steel plate 9 among the plurality of element steel plates 9
The projections 3d are formed on the same circumference of the through holes 3b formed in the first element steel plate 9 and are arranged side by side at equal intervals. In order to form a spiral fin in the cooling passage,
The second element steel plate 9 among the plurality of element steel plates 9 is arranged at equal intervals on the same circumference of the through holes 3b provided in the second element steel plate 9 so that the first element steel plate 9 is formed. The protrusion 3d is formed so as to be held out of phase with respect to the formed protrusion 3d. That is, by forming the spiral fin in the cooling passage, when the cooling medium 10 flows through the through hole 3a (through hole 3b), the flow of the cooling medium 10 becomes non-rectified.

As described above, in the electric device according to the fourth embodiment, the non-rectified flow of the cooling medium 10 makes it possible to globally suppress uneven heat conduction. As a result, in the electric device according to the fourth embodiment, the cooling medium 1
With 0, the stator 1 can be efficiently cooled.

(Fifth Embodiment) FIG. 8 shows a fifth embodiment.
It is an inclination view which shows the electric equipment (motor or generator) which concerns on. In the fifth embodiment, the same components as those in the first to fourth embodiments are designated by the same reference numerals, and the description overlapping with those in the first to fourth embodiments will be omitted. In the electric device according to the fifth embodiment, the circumferential magnetic path forming portion 3 of the stator 1 and the casing 2 are joined together and have an uneven shape. The uneven shape includes a protrusion 11a as a protrusion and a groove 11b as a recess.

FIG. 9 is a sectional view taken along the line DD ′ of FIG. For example, the protrusion 11a is provided on the inner peripheral surface 2b of the casing 2.
The groove 11b is formed on the outer peripheral surface 1b of the stator 1 (circumferential magnetic path forming portion 3). The stator 1 and the casing 2 are joined together by the protrusions 11a and the grooves 11b, so that the contact area between the stator 1 and the casing 2 is increased. Therefore, the heat generated by the stator 1 is efficiently conducted to the casing 2. As described above, in the electric device according to the fifth embodiment, it is possible to suppress uneven heat conduction globally by utilizing efficient heat conduction. In addition, in the electric device according to the fifth embodiment, the protrusion 11a and the groove 11b can achieve a further effect of preventing deviation in the rotation axis direction.

Although not shown in order to explain the protrusion 11a and the groove 11b, in the electric device according to the fifth embodiment, the casing 2 has the through hole 2 described in the first embodiment.
It is also possible to provide a. In the electric device according to the fifth embodiment, the through hole 1a described in the second embodiment can be provided in the stator 1. In the electric device according to the fifth embodiment, the through hole 3a described in the third and fourth embodiments can be provided in the stator 1. As described above, in the electric device according to the fifth embodiment, the through hole 2a described in the first embodiment, the through hole 1a described in the second embodiment,
Providing at least one of the through holes 3a described in the third and fourth embodiments can be expected to further suppress global uneven heat conduction. In this case, the through hole 2a described in the first embodiment, the through hole 1a described in the second embodiment, the through hole 3a described in the third embodiment (the through hole 3b, the protrusion 3).
c), the through hole 3a described in the fourth embodiment (through hole 3
b, the protrusion 11a, so as not to contact the protrusion 3d).
It is preferable to form the groove 11b.

(Sixth Embodiment) FIG. 10 is an oblique view showing an electric device (transformer) according to the sixth embodiment. The electric device according to the sixth embodiment includes a magnetic path forming body 21, as shown in FIG. 10.

The magnetic path forming body 21 constitutes a magnetic circuit. The magnetic path forming body 21 includes a direction magnetic path forming portion 23 (first and second direction magnetic path forming portions 23) and a plurality of direction magnetic path forming portions 24 (third direction magnetic path forming portion 24). There is. A plurality of third direction magnetic path forming portions 24 are provided on the second direction magnetic path forming portions 23, and a first direction magnetic path forming portion 23 is provided on the plurality of third direction magnetic path forming portions 24. Has been. The third direction magnetic path forming portion 24 is coupled so as to intersect the magnetic paths of the first direction magnetic path forming portion 23 and the second direction magnetic path forming portion 23. A coil 25 for forming a magnetic field path in the magnetic circuit is wound around at least one third direction magnetic path forming portion 24 of the plurality of third direction magnetic path forming portions 24.

In the electric device according to the sixth embodiment, the through holes 3a described in the third and fourth embodiments have the first and second through holes 3a.
It is formed in the directional magnetic path forming portion 23 and extends from one end surface of the first and second directional magnetic path forming portion 23 toward the opposite end surfaces. In this case, the through hole 3a penetrates in the direction orthogonal to the magnetic path of the first and second direction magnetic path forming portions 23, and
In the longitudinal direction of the second direction magnetic path forming portion 23, the magnetic path forming body 21 (first and second magnetic path forming bodies 21 are held side by side at equal intervals).
It is used as a cooling passage for passing the cooling medium 10 in a direction orthogonal to the magnetic paths of the directional magnetic path forming portion 23 and the third directional magnetic path forming portion 24).

The magnetic path forming body 21 (first and second direction magnetic path forming portions 23, third direction magnetic path forming portion 24) is formed by laminating a plurality of element steel plates (eg, silicon steel plate). It is configured. The plurality of element steel plates are sequentially arranged adjacent to each other. In the case of the through hole 3a described in the third embodiment, when the plurality of element steel plates are arranged adjacent to each other, the first
And the plurality of element steel plates (first and second direction magnetic path forming portions 23) are formed so that the through holes 3a extending in the direction orthogonal to the magnetic path of the second direction magnetic path forming portion 23 are formed. The through hole 3b described in the third embodiment is formed. In this case, the projecting portion 3c described in the third embodiment is formed in the through hole 3b formed in at least one element steel plate of the plurality of element steel plates. A part of the cooling passage is narrowed by the protrusion 3c. That is, by providing a throttle in the middle of the cooling passage, the through hole 3a (through hole 3b)
When the cooling medium 10 flows to the inside, non-rectification occurs.

Also, the through hole 3 described in the fourth embodiment.
In the case of a, when a plurality of element steel plates are arranged adjacent to each other, they extend in the direction orthogonal to the magnetic paths of the first and second direction magnetic path forming portions 23, and the spiral fins are provided therein. The through holes 3b described in the fourth embodiment are formed in the plurality of element steel plates so that the through holes 3a are formed. In this case, the projection 3d described in the fourth embodiment is formed in the through hole 3b formed in the plurality of element steel plates.
The protrusions 3d are held side by side at equal intervals in the longitudinal direction of the first and second direction magnetic path forming portions 23, and form spiral fins in the cooling passage. For example, the first element steel plate of the plurality of element steel plates is provided with protrusions 3d that are held side by side at equal intervals on the same circumference of the through holes 3b formed in the first element steel plate. ing. In order to form the spiral fins in the cooling passage, the second element steel plate of the plurality of element steel plates is formed at equal intervals on the same circumference of the through holes 3b provided in the second element steel plate. Side by side, the protrusions 3d that are held out of phase with respect to the protrusions 3d formed on the first element steel plate are formed. That is, by providing the spiral fin in the cooling passage, when the cooling medium 10 flows into the through hole 3a (through hole 3b), the flow of the cooling medium 10 is not rectified.

As described above, in the electric device according to the sixth embodiment, the non-rectified flow of the cooling medium 10 makes it possible to suppress uneven heat conduction globally. As a result, in the electric device according to the sixth embodiment, the cooling medium 1
When 0, the magnetic path forming body 21 can be efficiently cooled.

(Seventh Embodiment) FIG. 11 is an inclined view showing an electric device (transformer) according to the seventh embodiment. In the seventh embodiment, the same constituents as those in the sixth embodiment are designated by the same reference numerals, and the duplicated description of the sixth embodiment will be omitted.

In the electric device according to the seventh embodiment, the through holes 3a described in the sixth embodiment are formed in the first and second direction magnetic path forming portions 23, and the first and second direction magnetic paths are formed. The formation portion 23 extends from one end surface toward the opposite end surface. In this case, the through hole 3a penetrates in the longitudinal direction of the first and second direction magnetic path forming portions 23, and the first and second directions.
It is used as a cooling passage for passing the cooling medium 10 in the longitudinal direction of the direction magnetic path forming portion 23.

As described above, in the electric device according to the seventh embodiment, the non-rectified flow of the cooling medium 10 makes it possible to suppress uneven heat conduction globally. As a result, in the electric device according to the seventh embodiment, the cooling medium 1
When 0, the magnetic path forming body 21 can be efficiently cooled.

(Embodiment 8) FIG. 12 is an inclined view showing an electric device (actuator) according to Embodiment 8 of the present invention. As shown in FIG. 12, the electric device according to the eighth embodiment includes a magnetic path forming body 41 and an opposed magnetic path forming body 42.

The magnetic path forming member 41 includes the direction magnetic path forming portion 23.
(First direction magnetic path forming portion 23), and a plurality of direction magnetic path forming portions 24 (second direction magnetic path forming portion 24) coupled so as to intersect the magnetic path of the first direction magnetic path forming portion 23 Is equipped with. A coil 25 for forming a magnetic field path in the opposing magnetic path forming body 42 is wound around at least one second direction magnetic path forming portion 24 of the plurality of second direction magnetic path forming portions 24.

In the electric device according to the eighth embodiment, the through hole 3a described in the third and fourth embodiments is formed in the first-direction magnetic path forming portion 23. In this case, the through hole 3a
Penetrates in a direction orthogonal to the magnetic path of the first-direction magnetic path forming portion 23, is held at equal intervals in the longitudinal direction of the first-direction magnetic path forming portion 23, and forms the first-direction magnetic path. Part 23
Is used as a cooling passage for passing the cooling medium 10 in a direction orthogonal to the magnetic path.

Magnetic path forming body 41 (first direction magnetic path forming portion 2)
3. The second direction magnetic path forming portion 24) is configured by laminating a plurality of element steel plates (example: silicon steel plate). The plurality of element steel plates are sequentially arranged adjacent to each other. In the case of the through hole 3a described in the third embodiment, when a plurality of element steel plates are arranged adjacent to each other, the through hole 3a extending in the direction orthogonal to the magnetic path of the first-direction magnetic path forming portion 23 is formed.
So that the through holes 3 described in the third embodiment are formed in the plurality of element steel plates (first-direction magnetic path forming portion 23).
b is formed. In this case, the projecting portion 3c described in the third embodiment is formed in the through hole 3b formed in at least one element steel plate of the plurality of element steel plates. A part of the cooling passage is narrowed by the protrusion 3c. That is, by providing a throttle in the middle of the cooling passage,
When the cooling medium 10 flows into the through hole 3a (through hole 3b), the flow of the cooling medium 10 becomes non-rectified.

Also, the through hole 3 described in the fourth embodiment.
In the case of a, when a plurality of element steel plates are arranged adjacent to each other, the through hole 3a extends in a direction orthogonal to the magnetic path of the first-direction magnetic path forming portion 23 and has a spiral fin therein. Are formed, the through holes 3b described in the fourth embodiment are formed in the plurality of element steel plates. In this case, the projection 3d described in the fourth embodiment is formed in the through hole 3b formed in the plurality of element steel plates. Protrusion 3
In the longitudinal direction of the first-direction magnetic path formation portion 23, d is held side by side at equal intervals, and spiral fins are formed in the cooling passage. For example, the first element steel plate of the plurality of element steel plates is provided with protrusions 3d that are held side by side at equal intervals on the same circumference of the through holes 3b formed in the first element steel plate. ing. In order to form the spiral fin, the second element steel plate of the plurality of element steel plates is arranged at equal intervals on the same circumference of the through holes 3b provided in the second element steel plate, The protrusion 3d formed by shifting the phase with respect to the protrusion 3d formed on the first element steel plate is formed. That is, by providing the fins in the cooling passage, when the cooling medium 10 flows into the through hole 3a (through hole 3b), the flow of the cooling medium 10 is not rectified.

As described above, in the electric device according to the eighth embodiment, the non-rectified flow of the cooling medium 10 makes it possible to suppress uneven heat conduction globally. Accordingly, in the electric device according to the eighth embodiment, the cooling medium 1
When 0, the magnetic path forming body 41 can be efficiently cooled.

(Ninth Embodiment) FIG. 13 is an inclined view showing an electric device (actuator) according to the ninth embodiment. In the ninth embodiment, the same components as those in the eighth embodiment are designated by the same reference numerals, and the duplicated description of the eighth embodiment will be omitted.

In the electric device according to the ninth embodiment, the through hole 3a described in the eighth embodiment is formed in the first-direction magnetic path forming portion 23. In this case, the through hole 3a is
Penetrates in the longitudinal direction of the first-direction magnetic path forming portion 23, and
It is used as a cooling passage for passing the cooling medium 10 in the longitudinal direction of the first-direction magnetic path forming portion 23.

As described above, in the electric device according to the ninth embodiment, the non-rectified flow of the cooling medium 10 makes it possible to suppress uneven heat conduction globally. As a result, in the electric device according to the ninth embodiment, the cooling medium 1
When 0, the magnetic path forming body 41 can be efficiently cooled.

[0055]

As described above, the electric equipment of the present invention can suppress uneven heat conduction globally.

[Brief description of drawings]

FIG. 1 is an inclined view showing an electric device according to a first embodiment.

2 is a cross-sectional view taken along the line A-A ′ of FIG.

FIG. 3 is a perspective view showing an electric device according to a second embodiment.

FIG. 4 is a sectional view taken along the line B-B ′ of FIG. 3.

FIG. 5 is an inclined view showing an electric device according to a third embodiment.

6 is an enlarged cross-sectional view of a C portion of FIG.

FIG. 7 is an enlarged cross-sectional view of a portion C of FIG. 5 in the electric device according to the fourth exemplary embodiment.

FIG. 8 is an inclined view showing an electric device according to the fifth embodiment.

9 is a cross-sectional view taken along the line D-D 'of FIG.

FIG. 10 is an inclined view showing an electric device according to a sixth embodiment.

FIG. 11 is a perspective view showing an electric device according to a seventh embodiment.

FIG. 12 is an inclined view showing an electric device according to the eighth embodiment.

FIG. 13 is a perspective view showing an electric device according to the ninth embodiment.

FIG. 14 is a perspective view showing a conventional electric device.

FIG. 15 is a perspective view showing a conventional electric device.

FIG. 16 is a perspective view showing a conventional electric device.

FIG. 17 is a perspective view showing a conventional electric device.

[Explanation of symbols]

1 Magnetic path forming body (stator) 1a through hole 1b side 1c groove 2 casing 2a through hole 2b side 2c groove 3 Circumferential magnetic path formation part 3a, 3b through hole 3c, 3d protrusion 4 Radial magnetic path forming part 6 Opposing magnetic path forming body (rotor) 7 spindle 8 Opposing magnetic path forming body (rotor body) 9 element steel plate 10 Cooling medium 11a protrusion 11b groove 21 Magnetic path former 23, 24 direction magnetic path forming part 25 coils 41 Magnetic path former 42 Opposing magnetic path former 101 Magnetic path forming body (stator) 101a through hole 101b side 101c groove 102 casing 102a through hole 102b side 102c groove 103 Circumferential magnetic path forming part 103a through hole 104 Radial magnetic path forming part 106 Opposing magnetic path forming body (rotor) 107 spindle 108 main body of opposed magnetic path forming body (main body of rotor) 110 Cooling medium

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Yoshimi Komatsu             3-5-1, 717-1, Fukahori-cho, Nagasaki-shi, Nagasaki             Hishi Heavy Industries Ltd. Nagasaki Research Center (72) Inventor Yukio Yamashita             3-5-1, 717-1, Fukahori-cho, Nagasaki-shi, Nagasaki             Hishi Heavy Industries Ltd. Nagasaki Research Center (72) Inventor Takashi Mikogami             3,000 Tana, Sagamihara-shi, Kanagawa Mitsubishi Heavy Industries             General-purpose machine / special vehicle business division F-term (reference) 5H002 AA10 AB04 AD04 AD05                 5H609 BB01 PP02 PP06 PP08 PP09                       QQ02 QQ03 QQ04 QQ05 QQ08                       QQ12 RR26 RR33 RR37 RR40                       RR44

Claims (6)

[Claims] 1. A stator, a rotor that rotates by a magnetic interaction received from the stator, and a case that covers the stator, wherein the stator or the case penetrates the stator or the case, An electric device in which a through hole spirally extending around the rotation axis is provided, and a cooling medium for cooling the stator flows in the through hole. 2. A stator, and a rotor that rotates by a magnetic interaction received from the stator, the stator being provided with a through hole that penetrates the stator and extends in a rotation axis direction of the rotor. A cooling medium for cooling the stator flows through the through hole, and at least a part of the through hole is provided with a protrusion for non-rectifying the flow of the cooling medium. 3. An electric device comprising a stator, a rotor that rotates by a magnetic interaction received from the stator, and a case that covers the stator, wherein the stator and the case are joined and have an uneven shape. 4. The electric device according to claim 3, wherein the stator or the case is provided with a through hole penetrating the stator or the case and spirally extending around a rotation axis of the rotor, An electric device in which a cooling medium for cooling the stator flows in the through hole. 5. The electric device according to claim 3, wherein the stator is provided with a through hole that penetrates the stator and extends in a rotation axis direction of the rotor, and the through hole cools the stator. An electric device in which a cooling medium for flowing the cooling medium flows, and at least a part of the through hole is provided with a protrusion for non-rectifying the flow of the cooling medium. 6. A magnetic path forming body, wherein the magnetic path forming body is provided with a through hole penetrating the magnetic path forming body and extending from one end surface of the magnetic path forming body toward an end surface facing the magnetic path forming body. A cooling medium for cooling the magnetic path forming body flows through the through hole, and at least a part of the through hole is provided with a protrusion for non-rectifying the flow of the cooling medium. Electrical equipment.