JP2013227867A - Blower - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a structure which can easily and precisely secure the rotatory balance of a rotor, and efficiently radiates heat generated from a driving coil in a motor to the outside, in a motor integral-type blower.SOLUTION: A hub 119 includes a boss 114, a radiator plate 115, and a cylindrical part 118, and a blade 117 is disposed at the periphery of the hub 119. The radiator plate 115 has one face exposing to the stator coil 107 side, and the other face exposing to the axial outside. Heat generated in the stator coil 107 and a stator core 105 is absorbed to the radiator plate 115 as radiation heat, and furthermore, the heat is radiated from the radiator plate 115 to the outside.

Description

  The present invention relates to a blower having a structure in which heat generated from a motor is radiated to the outside in a motor-integrated blower.

  The blower with a built-in motor has a problem that the lubricant of the bearing is deteriorated due to heat generated from the motor, and the service life is shortened. Patent Document 1 discloses a structure in which a metal plate serving as a heat dissipation layer is attached to the surface of the impeller in order to dissipate heat from the motor built in the blower from the surface of the resin impeller.

JP 2004-316505 A

  The structure in which the metal plate is attached to the surface of the impeller disclosed in Patent Document 1 has a weak heat dissipation effect because the contact portion between the metal plate and the shaft is only the top end portion of the shaft. Further, there is a problem that it takes time and effort to balance the rotation of the rotor when the attaching position of the metal plate is shifted. In addition, the drive coil has the largest amount of heat generation, followed by the core, then the bearings and the circuit board. In the structure in which the metal plate is attached to the impeller surface described above, the heat dissipation function of the metal plate is from the shaft. It only functions to dissipate the heat conducted to the impeller, and does not contribute much to the heat dissipation generated by the drive coil and core.

  In such a background, the present invention can easily secure the rotation balance of the rotor with high accuracy and efficiently radiate the heat generated from the drive coil inside the motor to the outside in the motor-integrated blower. The purpose is to provide a structure.

  The invention according to claim 1 is a motor-integrated blower, in which a rotatable shaft, the shaft is fixed at the center, one surface is exposed to the drive coil side, and the other surface is exposed to the outside. It is characterized by comprising an exposed heat radiating plate, a cylindrical portion fixed to an outer edge of the heat radiating plate, and a blade provided on the outer periphery of the cylindrical portion. According to the first aspect of the present invention, the radiant heat radiated from the drive coil is absorbed by the surface of the heat radiating plate exposed to the drive coil side, and the heat is radiated to the outside from the other surface of the radiating plate. The That is, the heat generated from the drive coil is radiated to the outside through the heat radiating plate. For this reason, in addition to the heat dissipation effect of the heat conducted from the shaft to the heat sink, a path for radiating the heat generated from the drive coil is secured, the heat from the drive coil that generates a large amount of heat is trapped inside, and the bearing lubricant is retained. Deteriorating problems are alleviated.

  The invention according to claim 2 is the invention according to claim 1, wherein the shaft and the heat radiating plate are formed by a resin boss formed by an injection molding method using the shaft and the heat radiating plate as an insert material. It is characterized by being connected. According to the second aspect of the present invention, a high productivity is obtained, the positional relationship between the shaft and the heat sink is accurately determined, and a structure in which the weight balance is not lost during the rotation of the shaft is obtained.

  The invention according to claim 3 is the invention according to claim 2, wherein the cylindrical part is made of resin, the cylindrical part and the boss part are connected via a connecting part, and the connecting part is The heat radiating plate is exposed at another part of the heat radiating plate that is provided on a part of at least one of the one surface and the other surface, and the connection portion is not provided. An exposed surface on the side and an exposed surface on the side opposite to the drive coil side are secured.

  According to the third aspect of the present invention, the cylindrical portion, the boss portion, and the heat radiating plate (that is, the entire hub) in which the blades are arranged on the outer periphery can be integrated. For this reason, a manufacturing process is simplified. Even if the manufacturing process is simplified, the area occupied by the connecting portion on the heat sink is partial, and the exposed portion of the heat sink is secured, so the heat dissipation effect of the heat sink is not impaired.

  According to a fourth aspect of the present invention, in the invention according to any one of the first to third aspects, a rotor yoke and a rotor magnet are disposed inside the cylindrical portion, and the heat radiating plate is more than the rotor yoke. It is a metal having a high thermal conductivity. The rotor yoke needs to be made of a magnetic material because the function of forming a magnetic circuit is emphasized. However, since the heat sink does not need a function as a magnetic material, the material can be selected with priority on the heat radiation effect. .

  The invention according to claim 5 is the invention according to claim 4, wherein the heat radiating plate is made of an alloy mainly composed of copper or aluminum. By selecting an alloy mainly composed of copper or aluminum as the material of the heat dissipation plate, a high heat dissipation effect can be obtained.

  A sixth aspect of the invention is characterized in that, in the invention according to any one of the first to fifth aspects, the heat radiating plate includes a cylindrical portion that contacts the outer periphery of the shaft on the inner periphery. According to the invention described in claim 6, the contact area between the heat sink and the shaft is ensured by the inner periphery of the cylindrical portion of the heat sink contacting the outer periphery of the shaft, and the heat conducted through the shaft is efficiently obtained. Can escape to the heat sink well. Further, the strength of the coupling between the shaft and the heat sink can be increased.

  According to the present invention, in the motor-integrated blower, the rotation balance of the rotor can be easily secured with high accuracy, and heat generated from the drive coil inside the motor can be efficiently radiated to the outside.

It is sectional drawing of the axial-flow fan of embodiment. It is the front view and sectional drawing of the member which comprise an impeller. They are the figure (a) which looked at the heat sink from the axial direction, and the sectional view (b) seen from the direction perpendicular to the axis. It is a front view of the member which comprises the impeller of a modification. It is sectional drawing which looked at the heat sink of the modification from the direction perpendicular | vertical to an axis | shaft.

1. First embodiment (configuration)
FIG. 1 shows a cross-sectional view as viewed from a direction perpendicular to the axis of the axial blower 100 of the embodiment. FIG. 2 shows a front view (a) of the impeller included in the axial flow fan of FIG. 1 as viewed from the axial direction and a cross-sectional view (b) as viewed from the direction perpendicular to the axis.

  The axial blower 100 includes a casing 101. The casing 101 has a substantially cylindrical shape, and a rotor 123 (described later) is disposed inside the casing 101 so as to be rotatable. The casing 101 holds the motor base 103 by a motor base support member 102 that is a support column extending in the direction of the axial center, and the motor base 103 is a bearing having a substantially cylindrical shape extending in the axial direction. A housing 104 is provided. The casing 101, the motor base support member 102, the motor base 103, and the bearing housing 104 are integrally molded products made of resin.

  A stator core 105 is fixed to the outer periphery of the bearing housing 104. The stator core 105 is configured by laminating steel plates, and includes a plurality of salient poles (not shown) arranged in a radial pattern when viewed from the axial direction. Although a detailed description is omitted, the shape of the stator core 105 is the same as that of a stator core of a general outer rotor type brushless motor. A resin insulator 106 is attached to the stator core 105. A stator coil (drive coil) 107 is wound around each of the plurality of salient poles of the stator core 105 via the insulator 106. The stator core 105, the insulator 106, and the stator coil 107 constitute an outer rotor type motor stator 108. A metal terminal pin 109 is embedded in the insulator 106. The terminal pins 109 are connected to the ends of the windings constituting the stator coil 107, and the tips of the terminal pins 109 are connected to the circuit board 110. On the circuit board 110, a drive circuit for flowing a drive current through the stator coil 107 is formed.

  Bearings 111 and 112 are attached to the inside of the bearing housing 104. The bearings 111 and 112 hold a shaft 113 serving as a rotating shaft member in a rotatable state. The bearings 111 and 112 are sliding bearings or rolling bearings, and hold a lubricant for reducing friction associated with the rotation of the shaft 113. The shaft 113 is made of metal, and a resin boss portion 114 is attached to the upper portion thereof. The boss 114 is fixed to the end of the shaft 113 and is fixed to the rotation center of the metallic and substantially disk-shaped heat sink 115. FIG. 3 shows a front view (a) of the heat sink 115 viewed from the axial direction and a cross-sectional view (b) viewed from the direction perpendicular to the axis. As shown in FIG. 3, the heat radiating plate 115 is provided with a fitting hole 115 a into which the shaft 113 is fitted and a through hole 115 b for mutual fixation with the boss portion 114. As for the heat sink 115, one surface (the lower surface in FIG. 1) is exposed to the stator coil 107 side, and the other surface (the upper surface in the drawing) is exposed to the outside in the axial direction (the direction outside the axial fan 100). Yes.

  The boss portion 114 is formed by an injection molding method using resin as a raw material, and the shaft 113 and the heat dissipation plate 115 are integrated by the boss portion 114. Hereinafter, the manufacturing method of this part is demonstrated. First, an unillustrated injection mold for forming the boss 114 will be described. This injection mold (not shown) has a structure that can be placed inside the mold using the shaft 113 and the heat sink 115 as inserts. In manufacturing, an injection mold in which the end of the shaft 113 is inserted and fitted into the fitting hole 115a of the heat radiating plate 115 is placed inside the injection mold, and injection molding using resin as a raw material is performed. By this injection molding, the portion where the shaft 113 and the heat radiating plate 115 are coupled is covered with resin, and the boss portion 114 is formed (see FIGS. 1 and 2). At this time, the resin material constituting the boss portion 114 enters the through hole 115b of the heat radiating plate 115, and a structure in which the shaft 113 and the heat radiating plate 115 are integrated by the boss portion 114 as illustrated is obtained.

  A spring 116 for absorbing backlash in the axial direction of the shaft 113 is disposed between the boss portion 114 and the bearing 112. A cylindrical portion 118 having a plurality of blades 117 is fixed to a peripheral edge portion of the heat sink 115. The blades 117 and the cylindrical portion 118 are integrally molded members made of resin. A hub 119 is constituted by the boss portion 114, the heat sink 115 and the cylindrical portion 118. Further, the shaft 113, the hub 119 and the blades 117 constitute an impeller (impeller) 120.

  A cylindrical rotor yoke 121 made of a magnetic material is arranged inside the cylindrical portion 118, and a cylindrical rotor magnet 122 made of a permanent magnet is arranged inside the rotor yoke 121. The rotor magnet 122 is positioned outside the stator core 105 and the insulator 106 with a gap therebetween. The rotor magnet 122 is provided with a plurality of magnetic poles along the circumferential direction on the inner peripheral surface thereof, and is arranged in a state where the polarities of the magnetic poles facing the axis center are alternately reversed. The impeller 120, the rotor yoke 121, and the rotor magnet 122 constitute a rotor 123.

  As described above, the axial blower 100 has a structure in which the rotor portion of the outer rotor type brushless motor is provided with the blades of the axial flow fan. That is, in the axial blower 100, the rotor 123 rotates around the stator 108 fixed to the bearing housing 104 of the motor base 103. The rotor 123 has a structure in which a hub 119 is fixed to a shaft 113 and blades 117 are disposed on the outer periphery of the hub 119. A rotor magnet 122 is attached to the inside of the hub 118, and the polarity of the drive current that flows through the stator coil 107, which is a drive coil disposed on the stator 108 side, is switched. The magnetic attractive force and the magnetic repulsive force acting between the two are switched, and the rotor 123 rotates about the shaft 113. As the rotor 123 rotates, the blades 117 rotate and air movement (axial flow) occurs in the axial direction.

(Heat dissipation function)
When the axial blower 100 is operated, the stator coil 107, the stator core 105, the bearings 111 and 112, and the circuit board 110 generate heat. Here, the calorific value of the stator coil 107 is the largest, followed by the calorific value of the stator core 105 and the calorific value of other portions. Here, since the bearing housing 104 is made of resin, heat conduction cannot be expected so much. In this situation, heat generated from the bearings 111 and 112 is conducted from the metallic shaft 113 to the heat radiating plate 115 and is radiated from the heat radiating plate 115. Further, the heat generated in the stator coil 107 and the stator core 105 is absorbed by the heat radiating plate 115 as radiant heat, and further radiated from the heat radiating plate 115 in the upward direction in the figure.

  As for the heat sink 115, one surface (the lower surface in FIG. 1) is exposed to the stator coil 107 side, and the other surface (the upper surface in the drawing) is exposed to the outside in the axial direction (the direction outside the axial fan 100). Yes. Therefore, the heat generated in the stator coil 107 and the stator core 105 described above is absorbed by the heat radiating plate 115 as radiant heat and further radiated from the heat radiating plate 115 to the outside. In the case of an axial blower, the heat generation from the circuit board 110 is not so great, and the structure shown in FIG.

(Superiority)
Heat generated in the stator coil 107 and the stator core 105, which are main heat generating sources, is absorbed as radiant heat in the heat radiating plate 115 and further radiated from the heat radiating plate 115 in the upward direction of FIG. According to this structure, the heat generated in the stator coil 107 and the stator core 105 is efficiently radiated to the outside in a state where the inner (inner) sealability of the rotor 123 is not impaired.

  For example, a structure is also conceivable in which an opening is provided in the heat radiating plate 115 and heat from the stator coil 107 and the stator core 105 is radiated by securing air permeability from the outside to the stator 108. However, in that case, there is a problem of dust and foreign matter entering the rotor 123. In pursuit of downsizing the axial blower 100 and reducing the size of the gap between the stator 108 and the rotor 123, it is not preferable that dust and foreign matter enter the rotor 123. In the case of the heat dissipation structure of the present embodiment, a structure is realized in which heat is released from the rotor 123 while suppressing the occurrence of this problem.

  Since the heat sink 115 is fitted into the shaft 113, heat conducted through the shaft 113 can be efficiently radiated from the heat sink 115. Further, by forming the boss 114 by resin injection molding using the shaft 113 and the heat sink 115 as an insert material, the shaft 113 can be accurately fixed to the rotation center of the heat sink 115. Since the integral structure of the shaft 113 and the heat sink 115 is secured by the boss portion 114, the balance of the rotor 123 can be easily secured with high accuracy. Further, since the heat radiating plate 115 is a member different from the rotor yoke 121, the heat radiating plate 115 does not need to be made of a magnetic material, and the heat radiating plate 115 can be made of a metal having good thermal conductivity and heat radiating characteristics. Can be a prioritized structure. For example, when a cup-shaped rotor yoke in which the heat sink 115 and the rotor yoke 121 are formed from a single member is employed, the portion corresponding to the heat sink 115 must also be made of a magnetic material. This makes it impossible to select materials that prioritize the heat dissipation function.

(Modification 1)
A structure in which the shaft 111 is fixed to the fitting hole 115a of the heat sink 115 by press fitting is preferable. According to this structure, since the contact between the shaft 111 and the heat radiating plate 115 becomes more reliable, heat conduction from the shaft 111 to the heat radiating plate 115 can be performed more reliably.

(Modification 2)
FIG. 4 shows an example in which the blade 117, the cylindrical portion 118, and the boss portion 114 are formed as an integrally molded product. In the structure shown in FIG. 4, the cylindrical portion 118 and the boss portion 114 are connected by three bridge portions 130 and have an integral structure. By having the bridge portion 130, it is possible to obtain a structure in which the blade 117, the cylindrical portion 118, and the boss portion 114 are integrally formed by an injection molding method using resin as a raw material. In the case of obtaining this structure, the structure shown in FIG. 4 is obtained by performing injection molding using resin as a raw material in a state where the heat radiation plate 115 (same as FIG. 1) is disposed as an insert material in the mold.

  Here, the bridge portion 130 may be provided only on one side of the heat sink 115 or may be provided on both sides. Further, the number of bridge portions 130 is not limited to three. In the structure shown in FIG. 4, since the heat radiating plate 115 is exposed at a portion where the bridge portion 130 is not provided, the same heat radiating effect as in the case of FIG. 1 can be obtained.

(Modification 3)
FIG. 5 shows a modification of the heat sink 115. The heat sink 115 shown in FIG. 5 has a cylindrical portion 115c extending in the axial direction at the fitting hole 115a. In this example, the shaft 113 and the heat radiating plate 115 are coupled by fitting (more preferably press-fitting) the shaft 113 into the cylindrical portion 115c. In this structure, since the inner peripheral surface of the cylindrical portion 115c is in contact with the outer peripheral surface of the shaft 113, a large contact area between the shaft 113 and the heat radiating plate 115 can be ensured, and heat conduction from the shaft 113 to the heat radiating plate 115 can be achieved. This is more effective than the structure shown in FIGS. 1 and 2.

(Modification 4)
The material of the heat sink 115 is preferably a material having higher thermal conductivity than the material of the rotor yoke 121. Examples of the material having high thermal conductivity include alloys mainly composed of copper and aluminum. For example, when a galvanized steel sheet is used for the rotor yoke 121, an alloy mainly composed of copper, aluminum or the like having a higher thermal conductivity than that of the galvanized steel sheet is used for the heat radiating plate 115, so that heat generated from the inside of the motor can be reduced. The effect of releasing to the outside is further increased. Since the heat radiating plate 115 does not need to be a magnetic material, a material giving priority to thermal conductivity can be selected.

  The aspect of the present invention is not limited to the individual embodiments described above, and includes various modifications that can be conceived by those skilled in the art, and the effects of the present invention are not limited to the contents described above. That is, various additions, modifications, and partial deletions can be made without departing from the concept and spirit of the present invention derived from the contents defined in the claims and equivalents thereof.

  The present invention can be used for a blower.

  DESCRIPTION OF SYMBOLS 100 ... Axial fan, 101 ... Casing, 102 ... Motor base support part, 103 ... Motor base, 104 ... Bearing housing, 105 ... Stator core, 106 ... Insulator, 107 ... Stator coil, 108 ... Stator, 109 ... Terminal pin, 110 ... Circuit board, 111 ... Bearing, 112 ... Bearing, 113 ... Shaft, 114 ... Boss part, 115 ... Heat sink, 115a ... Fitting hole, 115b ... Through hole, 115c ... Cylindrical part, 116 ... Spring, 117 ... Blade, 118 ... cylindrical part, 119 ... hub, 120 ... impeller, 121 ... rotor yoke, 122 ... rotor magnet, 123 ... rotor, 130 ... bridge part.

Claims (6)

A motor-integrated blower,
A rotatable shaft,
The shaft is fixed in the center, one surface is exposed to the drive coil side, and the other surface is exposed to the outside, and
A cylindrical portion fixed to the outer edge of the heat sink;
A blower comprising: a blade provided on an outer periphery of the cylindrical portion.   The blower according to claim 1, wherein the shaft and the heat radiating plate are coupled by a resin boss formed by an injection molding method using the shaft and the heat radiating plate as an insert material. The cylindrical portion is made of resin,
The cylindrical part and the boss part are connected via a connecting part,
The connecting portion is provided on a part of at least one of the one surface and the other surface of the heat sink,
In other portions where the connecting portion is not provided, the heat radiating plate is exposed, and an exposed surface on the side of the drive coil of the heat radiating plate and an exposed surface on the side opposite to the side of the drive coil are secured. The blower according to claim 2. A rotor yoke and a rotor magnet are disposed inside the cylindrical portion,
The blower according to any one of claims 1 to 3, wherein the heat radiating plate is a metal having a higher thermal conductivity than the rotor yoke.   The blower according to claim 4, wherein the heat radiating plate is made of an alloy mainly composed of copper or aluminum. The blower according to any one of claims 1 to 5, wherein the heat radiating plate includes a cylindrical portion that contacts an outer periphery of the shaft on an inner periphery.

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