JP2011252652A - Ventilator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lightweight, safe, and compact ventilator with a small through-hole for efficiently dissipating heat generated from a motor.SOLUTION: The ventilator includes: a cylindrical frame 9 inside of which a fan 3 and a motor 4 are provided; and a flange 6 having an approximately square shape projecting in the radial direction on the circumference of a suction side opening of the frame 9. The motor 4 is provided with a cylindrical heat dissipation plate 12 as if to surround the outer periphery of a housing 4a of the motor 4 in the axial direction. The heat dissipation plate 12 is fixed to the frame 9 via a fixing leg 14 extending in the radial direction, which allows the heat dissipation plate to efficiently dissipate the heat generated from the motor 4 while surrounding the entire motor 4.

Description

  The present invention relates to a ventilating device that includes a motor and a fan and is attached to a wall surface that penetrates.

  Conventionally, the small ventilation apparatus attached to the through-hole provided by penetrating a wall was a thing as shown by patent document 1, for example.

  A conventional small ventilation device will be described with reference to FIG. In such a ventilator, the front panel 102 is detachably attached to the main body frame 101. The main body frame has a circular opening at a substantially central portion thereof. Further, a motor 104 is attached to the main body frame 101 via a motor frame 103. A fan 105 is attached to the rotating shaft of the motor 104. Such a ventilator is often operated continuously, and the motor 104 becomes hot due to its rotation. The heat generated at this time is transmitted to the motor frame 103 and the main body frame 101.

  On the other hand, as a heat dissipation structure of a motor used in such a ventilator, there is one as shown in Patent Document 2.

  Such a heat dissipation structure will be described with reference to FIG. In other words, flanges 112a and 113a are provided on the facing joint surfaces of the casings 112 and 113 of the motor 111 incorporating the stator 115 and the rotor 116, respectively. And the heat sink 114 is provided so that it may extend in the outer peripheral direction from these flanges 112a and 113a.

JP 2005-163598 A JP 2001-178067 A

  In recent small ventilators, from the viewpoint of safety, the motor portion is required to be sealed, and more efficient heat dissipation is required. And when the said heat radiating structure was applied to the small ventilator, the subject that a ventilation path became narrow or the through-hole of a big cross-sectional area was needed occurred.

  Further, in order to reduce the weight of the apparatus, the motor frame, the main body frame, and the like are manufactured using a resin, and from this point of view, it is required to lower the temperature of the motor mounting portion.

  Therefore, the present invention solves such a conventional problem, and an object of the present invention is to provide a lightweight and safe small ventilation device that efficiently dissipates heat generated by a motor.

In order to achieve this object, the ventilator of the present invention
A cylindrical frame in which a fan and a motor are provided;
The outer periphery of the opening on the suction side of the frame has a flange portion projecting in a substantially square shape in the radial direction,
The motor includes a cylindrical heat sink that covers the periphery of the motor housing in the axial direction,
The heat radiating plate is fixed to the frame via fixing legs extending radially in the radial direction, and the intended purpose is achieved by this configuration.

As described above, the ventilation device of the present invention includes a cylindrical frame in which a fan and a motor are provided,
The outer periphery of the opening on the suction side of the frame has a flange portion projecting in a substantially square shape in the radial direction,
The motor includes a cylindrical heat sink that covers the periphery of the motor housing in the axial direction,
Since the heat radiating plate is fixed to the frame via fixing legs extending radially in the radial direction, heat generated from the motor can be efficiently radiated while covering the entire motor. Therefore, downsizing of the ventilation device can be realized.

Sectional drawing which shows the attachment state of the ventilation apparatus of Embodiment 1 of this invention External perspective view of the ventilation device External perspective view showing a heat sink attached to the motor of the ventilation device Enlarged external perspective view of the motor part of the ventilation device External perspective view of the ventilator with a heat sink attached Rear view of the ventilator External perspective view showing the fixed leg portion of the motor of the ventilation device External perspective view of a conventional ventilator Diagram showing heat dissipation structure of conventional motor

  The ventilator according to claim 1 of the present invention has a cylindrical frame in which a fan and a motor are provided, and a flange portion projecting in a substantially rectangular shape radially on the outer periphery of the suction side opening of the frame, The motor includes a cylindrical heat radiating plate that covers the periphery of the motor housing in the axial direction, and the heat radiating plate is fixed to the frame via fixing legs that extend radially in the radial direction. The heat of the motor is dissipated from a cylindrical heat sink with a wide heat dissipation area, and the temperature of the fixed part can be lowered below the motor outer temperature without impairing the air volume and noise level. It is possible to prevent the motor from falling when it becomes unstable or abnormally generates heat.

  Further, the fixed legs are provided so as to extend radially from the heat sink almost uniformly and are fixed to the frame at the tips of the fixed legs, and the fixing portions of the fixed legs that extend radially are from the motor. Since the temperature rise value becomes small because the distance is long, the structure is configured to efficiently dissipate heat.

  Further, three fixing legs are provided, and the motor is screwed at substantially equal intervals and is stably fixed, so that it is possible to prevent abnormal noise due to vibrations and rattling of parts.

  Further, at least one of the fixed legs has a structure in which two portions parallel to the rotation axis of the motor are provided and bent into a U shape, and the temperature of the frame fixing portion is more than the motor outer temperature. Can be lowered.

  Further, the heat radiating plate is formed by providing a motor insertion hole in the center of one metal plate and bending the material around the insertion hole to form a heat radiating fin. Can be obtained.

  In addition, since a part of the radiating fin is bent radially outward to provide a ground terminal fixing part, it is not necessary to provide a ground terminal connecting part on the outer surface of the motor, so that standardization of parts can be achieved.

  Further, the heat radiating plate is obtained by processing one metal plate into a cap shape by deep drawing, and the heat radiating plate also serves as a motor cover, thereby reducing the number of parts. Since the area of the heat dissipation part increases, the heat dissipation effect is enhanced.

  Further, a motor cover is provided so as to cover the motor together with the heat radiating plate, and the fixing leg is provided so as to protrude from the motor cover and is fixed from the outside of the motor cover, and is exposed to the outer shell. By radiating heat from the screw head, the heat dissipation effect is enhanced.

  In addition, an auxiliary heat sink can be added along the frame from the end of the fixed leg, and even when the motor is changed to a motor with a large temperature rise value, the temperature of the frame fixing portion can be reduced simply by adding the auxiliary heat sink It is possible to ensure the reliability of fixing the motor.

  The said heat sink is comprised with the aluminum raw material, the inner peripheral side and the said motor shell are made to contact, and can improve the heat dissipation effect more.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
As shown in FIG. 1, a ventilation device 50 according to the present embodiment covers a wind tunnel pipe 2 that penetrates a wall portion 1, a cylindrical portion 5 in which a fan 3 and a motor 4 are provided, and a fan 3. And a louver 51 provided at the top. Usually, such a ventilator 50 is installed such that a louver 51 is provided on the indoor side and indoor air is discharged to the outside.

  Furthermore, as shown in FIG. 1, the wind tunnel pipe 2 is provided in the wall part 1 so that the room and the outdoor may communicate. The wind tunnel pipe 2 is fitted with a cylindrical portion 5 in which a fan 3 and a motor 4 are provided. A flange portion 6 is formed on the outer periphery of the tubular portion 5 on the louver 51 side so as to project in a substantially rectangular shape in a direction perpendicular to the rotation axis of the fan 3. A rising portion 7 is formed on the back side of the peripheral portion of the flange portion 6. The flange portion 6 and the rising portion 7 constitute a frame 9 that houses the electrical box 8. A motor cover 11 is fitted to the motor case 10 provided in the cylindrical portion 5 after the motor 4 is fitted. The motor 4 has a stator and a rotor housed inside a housing 4a. A cylindrical heat radiating plate 12 is provided on the outer periphery of the housing 4a.

  The heat sink 12 will be described in detail with reference to FIGS. In FIG. 2, the motor cover 11 will be described in a removed state. The housing 4 a of the motor 4 is fitted in a motor case 10 provided on the frame 9. And the cylindrical heat sink 12 is provided so that the circumference | surroundings of the rotating shaft direction of this housing 4a may be contact | connected. The heat radiating plate 12 is fixed to the frame 9 by fixing legs 14 provided radially in a direction perpendicular to the rotation axis.

  As shown in more detail in FIG. 3, the heat radiating plate 12 has a triangular claw-like and heat radiating fin 13a, a connecting portion 13b in which the radiating fins 13a are connected in an annular shape, and a connecting portion 13b. It is comprised from the fixed leg 14 extended radially. In this example, the fixed leg 14 extends in the direction orthogonal to the rotation axis as it is from the end portion of the connecting portion 13b (fixed leg 14a), and after standing up in parallel with the rotation axis from the end portion of the connecting portion 13b, the diameter is increased. L-shaped one (fixed leg 14b) extending in the direction, rising from the end of the connecting portion 13b once in parallel with the rotation axis, then extending in the radial direction and further extending in parallel with the rotation axis to form a U-shape (Fixed leg 14c), a total of three. The three fixed legs 14 are provided radially evenly.

  Moreover, the ground terminal fixing | fixed part 15 is also provided so that it may extend toward a radial direction from the edge part of the connection part 13b. And as shown in FIG. 4, the ground wire 15a is connected.

  The heat radiating plate 12 is formed by providing a radial cut or a star-shaped cut centering on the rotation axis on a single metal plate, and cutting the cut into a cylindrical shape.

  The operation of the ventilator 50 will be described. When the ventilator 50 is operated, the fan 4 is rotated by driving the motor 4, and the indoor air is discharged through the wind tunnel pipe 2. When the motor 4 continues to operate, the motor 4 generates heat and the temperature of the housing 4a rises. This heat is released to the outside by the heat radiating plate 12, transmitted to the air passing through the wind tunnel pipe 2, and released to the outside. In addition, since the motor cover 11 covers the periphery of the heat dissipation fins 13 a of the heat dissipation plate 12, the heat is released to the outside through the motor cover 11. Since the fixed leg 14 is connected to the heat radiating plate 12, heat is transmitted to the fixed leg 14 and is also radiated from the fixed leg 14. Here, the fixed leg 14b and the fixed leg 14c are configured to have a distance from the screw fixing portion by providing a portion substantially parallel to the rotation axis after once protruding from the end of the connecting portion 13b in the outer peripheral direction. Yes. With such a configuration, the fixed screw 14b and the fixed screw 14c of the fixed leg 14c are sufficiently cooled at the tip screwing portions. That is, the temperature rise is small in the fixed legs 14b and 14c, the resin frame 9, and the joint portion, and the deformation of the frame 9 in the joint portion is less likely to occur. Furthermore, since the fixed leg 14c is formed in a U shape so that a portion substantially parallel to the rotating shaft is folded back and the portion parallel to the rotating shaft is lengthened, the heat radiation effect is further increased.

  Thus, the small ventilation apparatus 50 is realizable by using the heat sink 12 with a large heat dissipation effect.

  Further, since the motor 4 is stably fixed by screwing with the three fixing legs 14 provided at substantially equal intervals, it is possible to prevent the generation of abnormal noise due to vibration or the like and rattling of parts.

  Moreover, the cylindrical heat sink 12 can be made by efficiently using one metal plate.

  As shown in FIG. 5, as a heat dissipation structure, the heat dissipation plate 12 may be formed into a bowl shape by deep drawing a single metal plate. According to such a configuration, the motor 4 is hermetically sealed to improve safety, the area of the heat radiating portion is increased, and the heat radiating effect is improved. Furthermore, in this case, as shown in FIG. 6, the fixing leg 14 protrudes to the outside of the heat radiating plate 12 and is fixed with screws 16. According to such a configuration, the heat generated from the motor 4 is radiated from the screw 16 exposed through the fixed leg 14, so that the heat radiation effect can be further enhanced.

  Further, FIG. 7 shows that the auxiliary heat sink 17 made of metal is provided on the frame 9 so as to be connected to the end of the fixed leg 14. According to this configuration, the temperature of the fixing portion of the frame 9 can be reduced only by adding the auxiliary heat radiating plate 17, and the reliability of fixing the motor 4 can be ensured.

  Moreover, the heat radiating plate 12 can enhance the heat radiating effect by using aluminum having high thermal conductivity.

  A ventilator according to the present invention has a cylindrical frame in which a fan and a motor are provided, and a flange portion projecting in a substantially rectangular shape in the radial direction on the outer periphery of the suction side opening of the frame. The housing is provided with a cylindrical heat radiating plate that covers the periphery of the housing in the axial direction, and this heat radiating plate is fixed to the frame via fixed legs extending radially in the radial direction. Without deteriorating the value, the temperature of the fixing portion can be lowered below the motor outer temperature, and the motor can be prevented from becoming unstable due to thermal deformation of the frame, or the motor can be prevented from dropping when the motor abnormally generates heat. Such a ventilator can be used for a quiet and small blower.

DESCRIPTION OF SYMBOLS 1 Wall part 2 Wind tunnel pipe 3 Fan 4 Motor 5 Cylindrical part 6 Flange part 7 Standing part 8 Electrical box 9 Frame 10 Motor case 11 Motor cover 12 Radiation plate 13a Radiation fin 13b Connection part 14 Fixed leg 15 Grounding terminal fixing | fixed part 15a Ground Wire 16 Screw 17 Auxiliary heat sink 50 Ventilator 51 Louver

Claims (10)

A cylindrical frame in which a fan and a motor are provided;
The outer periphery of the opening on the suction side of the frame has a flange portion projecting in a substantially square shape in the radial direction,
The motor includes a cylindrical heat sink that covers the periphery of the motor housing in the axial direction,
The heat radiating plate is a ventilator fixed to the frame via fixed legs extending radially in the radial direction. The fixed legs are provided so as to extend almost uniformly radially from the heat sink,
The ventilation device according to claim 1, wherein the ventilation device is fixed to a frame at a distal end of the fixed leg. The ventilation device according to claim 2, wherein three fixed legs are provided. The ventilation apparatus according to claim 2 or 3, wherein at least one of the fixed legs has a structure in which two portions parallel to the rotation axis of the motor are provided and bent into a U shape. The heat dissipation plate is provided with a motor insertion hole in the center of one metal plate,
The ventilator according to any one of claims 1 to 4, wherein a heat dissipating fin is formed by bending a material around the insertion hole. The ventilator according to any one of claims 1 to 5, wherein a ground terminal fixing portion is provided by bending a part of the radiating fin radially outward. The ventilator according to any one of claims 1 to 4, wherein the heat radiating plate is obtained by processing a single metal plate into a cap shape by deep drawing. A motor cover is provided to cover the motor together with the heat sink,
The ventilation device according to any one of claims 1 to 7, wherein the fixed leg is provided so as to protrude from the motor cover and is fixed from the outside of the motor cover. The ventilator according to any one of claims 1 to 8, wherein an auxiliary heat sink can be added along the frame from an end of the fixed leg. The ventilator according to any one of claims 1 to 9, wherein the heat radiating plate is made of an aluminum material, and an inner peripheral side is in contact with the motor outer shell.

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