KR20060104294A - Fan-motor apparatus - Google Patents

Abstract

The present invention discloses a fan motor structure for cooling cooling, and is connected to a fan motor housing so as to communicate with an air discharge port to guide air blown from a fan motor and an air discharge port mounted in a fan motor housing having an air discharge port in a predetermined direction. A fan motor structure including an installed air duct, wherein the connection portion between the fan motor housing and the air duct is characterized in that a damping means of porous foam material interposed to surround the edge of the air discharge port is provided. According to the fan motor structure having such a configuration, the damping means precisely seals the connection portion between the air outlet of the fan motor housing and the air duct, thereby effectively increasing the dustproofing and soundproofing effect.

Fan motor structure, noise, reduction, air duct, sealing, damper member

Description

Fan motor structure {Fan-motor apparatus}

1 is a perspective view schematically showing the main components of a conventional projection display device.

Figure 2 is an exploded perspective view schematically showing a fan motor structure according to a preferred embodiment of the present invention.

3 is a perspective view of the fan motor structure shown in FIG.

4 is a cross-sectional view taken along the line A-A shown in FIG. 3.

5 is a cross-sectional view taken along the line B-B shown in FIG. 3.

6A and 6B are a perspective view and a partially cut perspective view showing an extract of the damper member shown in FIG.

7 is a cross-sectional perspective view showing another embodiment of a damper member used in the fan motor structure of the present invention.

<Description of Symbols for Main Parts of Drawings>

60; fan motor structure 61; fan motor housing

61a; air intake 62; border

62a; air outlet 63; fan motor

64; fan 65; air duct

66; damping means 66a, 66b; inner / external bonding

67; Bracket 68; Damper member

The present invention relates to a fan motor structure for cooling the drive heat generating unit of the apparatus, and more particularly, to a fan motor structure with enhanced dust and soundproofing effect.

In general, the fan motor structure is a device for forcibly blowing contaminated air or heating air generated in the device out of the device, it is used in a variety of devices from large plant equipment to small household appliances.

In particular, a fan motor structure used in a device having a high density of internal components must satisfy the blowing performance required under conditions of high flow resistance, and a careful design considering the problem of the size of the whole device or vibration noise is required.

In general, centrifugal fans in which air flows in the radial direction of the fan are used in a device having a large flow resistance. In order to use an axial fan in which air flows in the axial direction of a fan in a device having a large internal flow resistance, it is necessary to use a larger size than a centrifugal fan or a faster rotation speed than a centrifugal fan to obtain the required blowing performance.

1 is a perspective view schematically showing a projection display system as an example of a device having a large flow resistance therein.

As shown in FIG. 1, the projection display system includes an optical system 10 for generating an image, a light source device 20 for irradiating light to the optical system 10, and a light source device 20. And a fan motor structure 30 for discharging the heated heat, and an air duct 40 connected to the fan motor structure 30.

When such a projection display system is operated, high heat is generated while the high heat lamp of the light source device 20 emits light, and at the same time, the fan motor structure 30 is operated to forcibly blow out the heat generated from the lamp to open the air duct 40. Through the system. At this time, the noise generated while the fan inside the fan motor structure 30 rotates is transmitted to the silencer 50 along the air duct 40 and attenuated.

Such a conventional fan motor structure 30 is installed directly in the housing of the system through a bracket without a damping device that damps the vibration generated when the fan rotates at high speed, or on a rubber plate provided separately in the housing of the system. It is usually installed.

However, since the bracket is made of galvanized steel or stainless steel, the vibration generated when the fan is rotated is transmitted to the system as it is. Therefore, the vibration generated in the fan motor structure 30 is another cause of the noise, and this vibration affects various internal components of the system, thereby deteriorating the reliability and durability of the system.

In addition, the conventional fan motor structure 30 is discharged to the outside at the connection between the fan motor structure 30 and the air duct 40 before the drive noise of the fan is transmitted to the muffler 50 to reduce the operating noise of the system. There is a problem to increase.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a fan motor structure having a high dustproof and soundproof effect against vibration and noise generated when the fan rotates.

The fan motor structure according to the present invention for achieving the above object is a fan motor housing having an air discharge port, a fan motor mounted to the fan motor housing to blow air to the air discharge port and the air blown from the air discharge port And an air duct connected to the fan motor housing so as to communicate with the air outlet so as to guide in a predetermined direction, and a damping means interposed between the fan motor housing and the air duct to surround the air outlet. It is characterized by being provided.

In the present invention having the configuration as described above, the inner and outer surfaces of the damping means are provided with an adhesive portion, respectively, by the bonding portion, the inner surface of the damping means and a portion of one side of the fan motor housing are bonded at the same time An outer surface of the damping means and a portion of the inner surface of the air duct may be joined.

Here, the adhesive part is preferably a double-sided tape, a bond may be used.

In addition, the damping means is preferably formed of a porous foam material, or molded of a synthetic resin such as polyurethane (polyurethane).

In addition, the damping means may be molded to have the same shape structure as the opening shape structure of the air discharge port.

In addition, the fan motor housing has a bracket coupled to support itself to be mounted to the housing of the system, it is preferable that a plurality of damper members are installed between the fan motor housing and the coupling portion of the bracket.

According to the present invention, since the damping means provided to surround the edge of the air outlet port tightly seals the connection portion between the fan motor housing and the air duct, the vibration and noise generated when the fan motor is driven, Sound insulation effect can be improved.

Hereinafter, a fan motor structure according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

2, a fan motor structure 60 according to a preferred embodiment of the present invention includes a fan motor housing 61 having an air discharge port 62a and a fan motor provided inside the fan motor housing 61. 63 and an air duct 65 connected to the fan motor housing 61 and damping means 66 interposed between the fan motor housing 61 and the air duct 65.

The fan motor housing 61 has an air intake port 61a formed in the center portion so that air is sucked in, and an air discharge port 62a through which air is discharged. The air discharge port 62a is formed inside the edge 62 protruding to one side of the fan motor housing 61 to allow air flow with the air inlet 61a. Outside the fan motor housing 61 is coupled to the bracket 67 for supporting the fan motor housing 61 to the system.

The fan motor 63 includes a centrifugal fan 64 that rotates at a high speed to forcibly blow air, and is installed inside the fan motor housing 61. When the fan 64 rotates at a high speed, air outside the fan motor housing 61 flows in the axial direction of the fan 64 through the air inlet 61a, and the air introduced into the fan motor housing 61 passes through the fan ( Flow in the radial direction of the 64 is discharged to the outside of the fan motor housing 61 through the air discharge port 62a.

The air duct 65 has a connector 65a which is connected to the air discharge port 62a of the fan motor housing 61 so that air flow is possible. The air duct 65 has one end with a connector 65a coupled to the housing 61 and the other end connected to the silencer 50 of the system (see FIG. 1).

The damping means 66 is provided to surround the edge 62 of the air discharge port 62a to tightly seal the connection between the fan motor housing 61 and the air duct 65. The damping means 66 has the same shape structure as that of the air discharge port 62 to tightly seal between the fan motor housing 61 and the air duct 65.

That is, as shown in FIG. 4, when the shape of the air discharge port 62 is square, the damping means 66 also has a square shape, and when the shape of the air discharge port is circular or other polygonal shapes other than square, It has a corresponding circular or polygonal shape.

The damping means 66 according to the present invention is made of porous foam or synthetic resin with good compressibility, and in particular, it is preferable that the damping means 66 is made of polyurethane having good rigidity, good thermal insulation, and excellent shock absorption. .

Each inner surface of the damping means 66 is provided with an inner adhesive portion 66a for joining the damping means 66 to the fan motor housing 61, and the damping means 66 on each outer surface of the damping means 66. To the air duct 65 is provided with an outer adhesive portion 66b. The inner and outer adhesive parts 66a and 66b may be formed by attaching a double-sided tape having both sides to the inner and outer surfaces of the damping means 66, and attaching an adhesive such as a bond to the damping means 66. It may also consist of applying to.

When the air duct 65 is coupled to the fan motor housing 61, the edge 62 of the air discharge port 62a and the damping means 66 surrounding the edge 62 are air ducts, as shown in FIG. 3. Fully inserted into 65.

At this time, as shown in Figure 4, the damping means 66 is tightly sealed each part of the upper, lower, left and right while the fan motor housing 61 and the air duct 65 is tightly sealed. At the same time, the upper, lower, left and right inner surfaces of the damping means 66 are bonded to the outer surface of the edge 62 by the inner adhesive portion 66a (see FIG. 2), and the upper, lower, left and right outer surfaces of the damping means 66 are attached to the outer adhesive portion ( 66b; see FIG. 2) to the inner surface of the air duct 65.

In this embodiment, the damping means 66 is shown and described as being located between the outer surface of the edge 62 of the air discharge port 62a and the inner surface of the air duct 65, but the present invention is not limited to such a configuration. . That is, when the air duct 65 is fitted into the air discharge port 62a of the fan motor housing 61 and coupled, the damping means 66 has an inner surface of the edge 62 of the air discharge port 62a and the air duct 65. May be interposed between the outer surfaces of the

FIG. 5 is a cross-sectional view taken along AA of FIG. 3, as shown in FIG. 5, between the fan motor housing 61 and the fan motor 63 and between the bracket 67 and the fan motor 63. The damper member 68 for damping the vibration of the fan motor 63 is provided. The damper member 68 attenuates the vibration generated when the fan motor 63 is driven to reduce noise generated by the vibration, and reduces the effect of the vibration on other internal parts of the system.

As shown in FIGS. 6A and 6B, the damper member 68 includes a base portion 68a and a base portion 68a coupled to the fan motor housing 61 (see FIG. 5) or the bracket 66 (see FIG. 5). It consists of a boss portion 68b protruding from the center of the. In the center of the base portion 68a and the boss portion 68b, a coupling hole 68c into which the coupling shaft 69 (see FIG. 5) of the fan motor 63 (see FIG. 5) is inserted is provided. The damper member 68 is preferably made of a rubber material having a large elastic force.

7 is a view showing another embodiment of the damper member. The damper member 68 'shown in FIG. 7 also includes a base portion 68a' and a boss portion 68b ', and the coupling portion 69 of the fan motor 63 (see FIG. 5) is attached to the boss portion 68b'. 5 is provided with a coupling hole 68c '.

Hereinafter, the operation of the fan motor structure 60 according to the present invention having the above configuration will be described with reference to FIGS. 2 and 3.

When the system is operated, the fan motor 63 of the fan motor driving body 60 is also operated. When the fan 64 of the fan motor 63 rotates at a high speed, the heat generated from the internal parts of the system is removed from the fan motor housing ( It is suctioned through the air intake port 61a of 61. Air sucked into the fan motor housing 61 is forcibly blown to the air duct 65 through the air discharge port 62a and discharged to the silencer 50 installed in the system along the air duct 65 (see FIG. 1). .

At this time, the vibration generated during the rotation of the fan 64 is a damper member for supporting the damping means 66 and the fan motor 63 interposed between the fan motor housing 61 and the air duct 65 from above / below ( 68; see FIG. 5).

In addition, the driving noise generated when the fan 64 is rotated is not easily released through the connection between the fan motor housing 61 and the air duct 65 and is provided in the system along the air duct 65 in the silencer 50. 1 is reduced in the silencer 50.

Therefore, the noise generated during operation of the system is reduced and the reliability and durability of the system are improved because the internal parts of the system are hardly affected by the vibration generated during the rotation of the fan 64.

According to the present invention described above, since the damping means interposed between the fan motor housing and the air duct tightly seals the gap between the fan motor housing and the air duct without any gap, driving noise generated when the fan is rotated is prevented. It is not easily discharged out of the housing or air duct, which reduces system noise.

In addition, according to the present invention, since the vibration generated while the fan rotates at a high speed is attenuated by the damping means interposed between the fan motor housing and the air duct and the damper member that supports the fan motor up and down. Noise generation can be suppressed and vibrations can be reduced on the internal components of the system. Thus, the reliability and durability of the system is improved.

As mentioned above, although this invention was demonstrated to the specific Example as an example, this invention is not limited to the structure and operation as it was drawn and described as such. That is, the present invention can be variously modified and changed within the spirit and scope of the claims described. Accordingly, all such suitable modifications and changes and equivalents should be considered to be within the scope of the present invention.

Claims (7)

A fan motor housing having an air discharge port, a fan motor mounted to the fan motor housing to blow air to the air discharge port, and the fan motor to communicate with the air discharge port to guide the air blown from the air discharge port in a predetermined direction; In the fan motor structure comprising an air duct connected to the housing, The fan motor structure and the connection portion between the air duct and the fan motor structure characterized in that the damping means is interposed to surround the edge of the air outlet. The method of claim 1, Bonding portions are provided on inner and outer surfaces of the damping means, respectively, and the inner side of the damping means and a portion of one side of the fan motor housing are joined to each other by the bonding portion, and at the same time the outer surface of the damping means and the air duct A fan motor structure, wherein a part of the inner surface is joined. The method of claim 2, The adhesive unit is a fan motor structure, characterized in that the double-sided tape is attached. The method according to claim 1 or 2, The damping means is a fan motor structure, characterized in that molded into a porous foam. The method according to claim 1 or 2, The damping means is a fan motor structure, characterized in that formed of polyurethane (polyurethane). The method according to claim 1 or 2, The damping means is a fan motor structure, characterized in that formed to have the same shape structure as the opening shape structure of the air discharge port. The method of claim 1, The fan motor housing has a bracket coupled to support itself so as to be mounted in a separate device, and the fan motor is installed so that a plurality of damper members are interposed between the fan motor housing and the coupling portion of the bracket. Structure.

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