JP2010151399A - Fan device supporting structure for air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fan device supporting structure for an air conditioner reducing a whistling sound, suppressing the turbulence of an air current and reducing a pressure loss. <P>SOLUTION: The fan device 28 has a fan body 32 and a driving device 33 rotationally driving the fan body 32. An outer peripheral part of the fan body 32 is provided with an air blowoff port for blowing out air in a suction side space taken in from an air intake, into a discharge side space 30. The driving device 33 is mounted to a mounting plate 51. The mounting plate 51 is formed in triangular shape and supported to a base plate 31 through three posts 52. Each post 52 has a V-shaped cross section and is disposed around the fan body 32. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a support structure for a fan device provided in a fan chamber of an air conditioner.

  Conventionally, as shown in FIG. 9, the air conditioner 10 includes a return air fan chamber 11, an air supply fan chamber 12, an outside air chamber 13, and an air supply chamber 14. A return air inlet 16 for sucking the return air 46 is formed in the ceiling of the fan chamber 11 for return air. The partition wall 17 that partitions the return air fan chamber 11 and the outside air chamber 13 is formed with a discharge port 18 that discharges the return air 46 that has flowed into the fan chamber 11 from the return air port 16 into the outside air chamber 13. ing.

  The outside air chamber 13 and the air supply chamber 14 communicate with each other through an opening 19. The partition wall 20 that partitions the air supply chamber 14 and the air supply fan chamber 12 is formed with a suction port 21 that sucks the air in the air supply chamber 14 into the air supply fan chamber 12. An air supply port 22 is formed in the ceiling portion of the air supply fan chamber 12 to discharge the air sucked into the air supply fan chamber 12 from the air intake port 21 as the air supply 47.

  In the air conditioner 10, a ventilation path 23 is formed which communicates with the return air port 16 of the return air fan chamber 11 and the air supply port 22 of the air supply fan chamber 12. The return air port 16 and the air supply port 22 are each connected to an external air conditioning target system.

  A filter unit 24 including a pre-filter and a medium performance filter is provided in the outside air chamber 13. In the air supply chamber 14, a heat exchanger 25 including a cooling coil and a heating coil and a humidifier 26 are provided. The outside air chamber 13 and the air supply chamber 14 communicate with each other via a filter unit 24, a heat exchanger 25, and a humidifier 26.

Next, the configuration of the fan chamber 12 for supplying air will be described below.
As shown in FIGS. 10A and 11, the air supply fan chamber 12 has an indoor space that is surrounded by a wall surface 27 on all sides and has a rectangular cross section. In the air supply fan chamber 12, the base plate 31 that partitions the indoor space into the lower suction side space 29 and the upper discharge side space 30, and the air in the suction side space 29 are sucked and discharged to the discharge side space 30. A fan device 28 for supplying air is provided.

  The fan device 28 is installed in the discharge side space 30, and includes a fan main body 32 made up of a single suction centrifugal plug fan, and a drive device 33 made up of a motor that rotationally drives the fan main body 32. The fan main body 32 has a circular shape in plan view, has an air intake port 39 at a lower end portion, has an air outlet port 40 at an outer peripheral portion, and has a flow that communicates from the air intake port 39 to the air outlet port 40 inside. Has a road.

  The base plate 31 is swingably attached to a mounting base 38 installed in the fan chamber 12 via a plurality of buffer means 37. The base plate 31 is formed in a quadrangular shape in accordance with the cross-sectional shape of the fan chamber 12. The base plate 31 is formed with a communication port 41 communicating with the inside of the suction side space 29 and the air intake port 39 of the fan main body 32.

A seal member 43 that seals the gap between the base plate 31 and the wall surface 27 in the fan chamber 12 is attached to the outer peripheral edge of the base plate 31.
The driving device 33 is attached to a mounting plate 34, and the mounting plate 34 is supported on the base plate 31 via four support columns 35. The mounting plate 34 is rectangular (square) in plan view, and the length A of one side of the mounting plate 34 is substantially the same as the diameter B of the fan body 32.

  Each support 35 is located at the four corners of the mounting plate 34 and is arranged around the fan main body 32 every 90 °. The fan main body 32 and the support post 35 are provided between the mounting plate 34 and the base plate 31. In addition, the cross section of each support | pillar 35 is formed in circular shape.

  As shown in FIGS. 9 and 10B, the configuration of the return air fan chamber 11 is the same as that of the above-described supply air fan chamber 12 (see FIG. 10A). In the air fan chamber 11, a base plate 31 that divides the indoor space into a higher suction side space 29 and a lower discharge side space 30, and air in the suction side space 29 is sucked and returned to the discharge side space 30. A fan unit 45 is provided.

  The return air fan device 45 is supported on the lower side of the base plate 31 in an upside down posture with respect to the air supply fan device 28. The support structure of the return air fan unit 45 is the same as the support structure of the supply air fan unit 28.

  In the air conditioner 10 as described above, the return air 46 is supplied from the return air port 16 to the fan chamber for returning air by driving the drive devices 33 of the fan devices 28 and 48 to rotationally drive the fan main body 32. 11 is sucked into the suction side space 29 and is discharged from the suction side space 29 through the communication port 41 and the fan body 32 into the discharge side space 30, and from the discharge side space 30 into the adjacent outside air chamber 13. After the foreign matter such as dust is removed by the filter unit 24, it flows into the air supply chamber 14, is heated or cooled by the heat exchanger 25 and is humidified by the humidifier 26, and then the air supply chamber 14. The air is sucked into the suction side space 29 of the air supply fan chamber 12 through the suction port 21 from the inside, and is discharged from the suction side space 29 into the discharge side space 30 through the communication port 41 and the fan main body 32. , Air supply 4 As supplied from supply port 22 to the outside.

The air conditioner 10 as described above is described in Patent Document 1 below. Moreover, the structure which supports a fan apparatus using four support | pillars is described in the following patent document 2. FIG.
JP2007-271141A JP-A-6-281194

  In the above conventional type, when the fan main body 32 of the air supply fan device 28 is rotationally driven, the air in the suction side space 29 of the air supply fan chamber 12 passes through the communication port 41 and the fan main body. 32 flows into the inside through the air inlet 39 and blows out from the air outlet 40 to the outside in the radial direction of the fan main body 32, and then flows upward through the space 44 between the mounting plate 34 and the wall surface 27. It is supplied to the outside from the air port 22.

  At this time, since each of the four struts 35 is at the air blowing position of the fan main body 32, there is a problem that wind noise is generated from four locations, and noise during driving of the fan increases. Further, there is a problem that the air flow (airflow) from the air outlet 40 of the fan main body 32 toward the air supply port 22 is disturbed by each support 35. Further, since the occupation ratio of the area of the mounting plate 34 to the cross-sectional area of the fan chamber 12 for supplying air is large, the area of the space 44 is reduced, and the air blown from the air outlet 40 of the fan body 32 is supplied to the inlet port. There is a problem that the pressure loss when flowing toward 22 increases.

The above-described problem occurs not only when the fan unit 28 for supplying air but also when the fan main body 32 of the fan unit 45 for returning air is rotationally driven.
An object of the present invention is to provide a fan device support structure for an air conditioner that can reduce wind noise, can suppress airflow turbulence, and can reduce pressure loss. .

In order to achieve the above object, the first invention provides a fan for an air conditioner that is provided in a fan chamber having a suction port and a discharge port and the interior of which is partitioned into a suction side space and a discharge side space by a partition. A device support structure,
The fan device is installed in the discharge side space and has a fan main body and a driving device that rotationally drives the fan main body.
An air outlet is formed on the outer periphery of the fan body to blow out air in the suction side space taken from the air intake into the discharge side space.
The drive is attached to the mounting member;
The mounting member is supported by the partition via three support members,
Each support member is disposed around the fan body.

  According to this, when the fan main body is rotationally driven by the driving device, the air in the suction side space flows into the fan main body from the air intake port, and blows out from the air blowout port into the discharge side space. It passes through the wall and is discharged from the outlet of the fan chamber to the outside. At this time, each support member is in the air blowing position of the fan body, but since there are three support members, wind noise is generated in three locations, reducing wind noise compared to the conventional four locations. This can reduce noise when the fan is driven.

In the fan apparatus supporting structure for an air conditioner according to the second aspect of the present invention, the mounting member is formed in a triangular shape, and the air blown from the air outlet of the fan body flows in the middle of the flow path flowing to the outlet of the fan chamber. Placed in
Each support member is disposed at each corner of the mounting member.

  According to this, since the occupying ratio of the area of the mounting member to the cross-sectional area of the fan chamber can be reduced by forming the mounting member in a triangular shape, the area of the space between the mounting member and the wall surface in the fan chamber Spread. Thereby, the pressure loss when the air blown out from the air outlet of the fan body flows toward the outlet of the fan chamber is reduced.

In the air conditioner fan device support structure according to the third aspect of the present invention, each support member and the fan body are provided between the mounting member and the partition,
The diameter of the inscribed circle of the mounting member is set shorter than the diameter of the fan body.

  According to this, the air blown out from the air outlet of the fan body flows toward the outlet of the fan chamber without being obstructed by the mounting member. As a result, the airflow of the fan becomes easier to flow through the center of the fan chamber, and the resistance of the airflow at the discharge port of the fan chamber is reduced and the pressure loss is reduced. In addition, by attaching the drive device to the mounting member toward the discharge port side of the fan chamber, the drive device receives a larger amount of the air blown from the air outlet of the fan body, so the cooling effect of the drive device is improved. To do.

In the air conditioner fan device support structure according to the fourth aspect of the present invention, the support member has two side surfaces forming a V shape, and a tip portion where these both side surfaces intersect,
The tip of the support member faces the air outlet of the fan body.

  According to this, the air blown out from the air outlet to the outside of the fan body in the radial direction first hits the tip of the support member, and then flows while being guided along the side from the tip. It is suppressed. Thereby, the wind noise of a support member is further reduced.

  As described above, according to the present invention, the noise during driving of the fan is reduced, the turbulence of the airflow is suppressed, and the pressure loss when the air blown out from the air outlet of the fan body flows toward the outlet of the fan chamber is reduced. be able to.

Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. In addition, about the same member as the conventional thing mentioned above, the same code | symbol is attached | subjected and detailed description is abbreviate | omitted.
As shown in FIGS. 1 to 4, the air supply port 22 of the air supply fan chamber 12 is an example of a discharge port, and the base plate 31 in the air supply fan chamber 12 defines the indoor space of the suction port 21. It is an example of a partition that partitions into a lower suction side space 29 and an upper discharge side space 30 with an air supply port 22.

  The drive device 33 of the air supply fan device 28 is attached to an attachment plate 51 (an example of an attachment member), and the attachment plate 51 is supported by the base plate 31 via three support columns 52 (an example of a support member). . The mounting plate 51 is formed in an equilateral triangle shape in a plan view, and the air blown from the air outlet 40 of the fan body 32 flows in the middle of the flow path (that is, the fan body 32). And between the upper and lower air supply ports 22).

  Each support column 52 and the fan body 32 are provided between the base plate 31 and the mounting plate 51, and each support column 52 is disposed around the fan body 32 every 120 °. The upper end of each column 52 is connected to each corner of the mounting plate 51, and the lower end is connected to the base plate 31. The distance D from the outer peripheral end of the fan main body 32 to the support column 52 in the radial direction of the fan main body 32 is kept at a predetermined value.

  As shown in FIG. 5, the support column 52 is a member having a V-shaped cross section having two V-shaped side surfaces 52 a and a front end portion 52 b where both side surfaces 52 a intersect. The front end portion 52 b of each support column 52 faces the air outlet 40 of the fan main body 32 and is directed to the rotation axis 53 of the fan main body 32. In addition, each buffer means 37 is disposed in the vicinity immediately below each column 52.

  As shown in FIG. 1, the return air fan device 45 in the return air fan chamber 11 is supported on the lower side of the base plate 31 in a vertically inverted posture with respect to the air supply fan device 28. ing. The support structure of the return air fan device 45 is the same as the support structure of the air supply fan device 28.

Hereinafter, the operation of the above configuration will be described.
As shown in FIG. 1, when the fan main body 32 is rotationally driven by the driving device 33 of each of the air supply and return fan devices 28 and 45, the return air 46 is returned from the return air port 16. The air is sucked into the suction side space 29 of the fan chamber 11, passes through the outside air chamber 13, the air supply chamber 14, and the air supply fan chamber 12, and is supplied as air supply 47 from the air supply port 22 to the outside of the air conditioner 10. Supplied.

  At this time, as shown in FIGS. 2 to 4, in the air supply fan chamber 12, the air in the suction side space 29 flows into the interior from the air intake 39 of the fan main body 32 through the communication port 41. After blowing out from the air outlet 40 to the outside in the radial direction of the fan main body 32, the air flows upward through the space 54 between the mounting plate 51 and the wall surface 27, and is supplied from the air supply port 22 to the outside.

  At this time, each strut 52 is located at the air blowing position of the fan main body 32. However, since the number of the struts 52 is three, the wind noise is generated in three places, and the wind noise is compared with the conventional four places. It can be reduced, and the noise when driving the fan is reduced.

  Also, as shown in FIG. 5, the air blown out from the air outlet 40 to the outside in the radial direction of the fan main body 32 first hits the front end portion 52b of the support column 52, and then from the front end portion 52b along the side surface 52a. Since it flows smoothly while being guided, the turbulence of the airflow is suppressed. Thereby, the wind noise of the support | pillar 52 is further reduced.

  In addition, as shown in FIG. 2, by forming the mounting plate 51 in a triangular shape, the occupation ratio of the area of the mounting plate 51 with respect to the cross-sectional area of the fan chamber 12 can be reduced. spread. Thereby, the pressure loss when the air blown out from the air outlet 40 of the fan main body 32 flows toward the air supply port 22 is reduced.

  FIG. 6 shows a comparison of the areas of the conventional rectangular mounting plate 34 and the triangular mounting plate 51 in the present embodiment, and FIG. 6 (a) is a conventional one. 6 (b) is the present embodiment. Here, as an example, as shown in FIG. 6A, the length L of one side of the fan chamber 12 is 0.9 m, and the length A of one side A of the conventional square mounting plate 34 is 0.5 m. The diameter B of the fan main body 32 is 0.5 m, and the distance D from the outer peripheral end of the fan main body 32 to the support column 35 is about 0.01 m.

According to this, the cross-sectional area S of the fan chamber 12 is an area S1 of 0.81 m ^2, and the mounting plate 34 becomes 0.25 m ^2. Thereby, the occupation ratio S1 / S of the area S1 of the mounting plate 34 with respect to the transverse area S of the fan chamber 12 is 0.25 m ² /0.81 m ² = 0.31. Further, the entire circumferential length L1 (running length) of the mounting plate 34 is 2 m.

Further, as shown in FIG. 6B, in the present embodiment, in order to keep the distance D from the outer peripheral end of the fan main body 32 to the support column 52 at about 0.01 m as in FIG. 6A, The length C of one side of the equilateral triangular mounting plate 51 is 0.62 m. In this case, the area S2 of the mounting plate 51 is 0.17 m ² , and the occupation ratio S2 / S of the area S2 of the mounting plate 51 with respect to the cross-sectional area S of the fan chamber 12 is 0.17 m ² /0.81 m ² = 0. 21. Further, the entire circumferential length L2 (running side length) of the mounting plate 51 is 1.86 m.

  As described above, the occupation ratio S2 / S of the mounting plate 51 of the present embodiment shown in FIG. 6B is smaller than the occupation ratio S1 / S of the conventional mounting plate 34 shown in FIG. 6A. Therefore, the area of the space 54 is expanded, and the pressure loss at the mounting plate 51 is reduced. Further, the pressure loss at the mounting plate 51 is also reduced by shortening the entire circumferential length L2 of the mounting plate 51 of the present embodiment compared to the entire circumferential length L1 of the conventional mounting plate 34.

  6B, the diameter F of the inscribed circle E (see the phantom line) of the mounting plate 51 is set to be shorter than the diameter B of the fan main body 32. Therefore, the air blown out from the air outlet 40 of the fan main body 32 is more likely to flow through the center of the fan chamber 12 without being obstructed by the mounting plate 51. Thereby, the resistance of the airflow at the air supply port 22 of the fan chamber 12 is reduced, and the pressure loss is reduced. Further, since the drive device 33 is attached to the attachment plate 51 toward the air supply port 22 side, the drive device 33 receives a larger amount of air blown from the air outlet 40 of the fan main body 32. Thereby, the cooling effect of the drive apparatus 33 (motor etc.) improves.

  The above-described effect is not only the support structure of the air supply fan device 28 in the air supply fan chamber 12 but also the support of the return air fan device 45 in the return air fan chamber 11. The structure is also obtained. Moreover, each numerical value shown in the said FIG. 6 is an example, and is not limited to these numerical values.

  In the first embodiment, as shown in FIG. 2, the mounting plate 51 is formed in a regular triangle shape and the tip corners of the mounting plate 51 are formed flat, but the second embodiment As shown to Fig.7 (a), you may leave each front-end | tip corner | angular part of the attachment plate 51 sharply.

  Moreover, in 3rd Embodiment, as shown in FIG.7 (b), the attachment board 51 has the disk-shaped bracket 56 in each front-end | tip corner | angular part. The upper end of each column 52 is connected to each bracket 56 of the mounting plate 51.

  Further, in the fourth embodiment, as shown in FIG. 7C, notches 57 are formed on each side of the mounting plate 51. According to this, the area of the mounting plate 51 can be further reduced.

  In the first embodiment, as shown in FIG. 2, the space 54 includes a first space 54 a having a triangular shape in plan view formed between the first side 60 a of the mounting plate 51 and the wall surface 27. The second space 54b having a triangular shape in plan view formed between the second side 60b and the wall surface 27 and the third rectangular shape in plan view formed between the third side 60c and the wall surface 27. Space 54c. In this case, the area of the first space 54a and the area of the second space 54b are the same, but the area of the first space 54a or the second space 54b is different from the area of the third space 54c. Yes.

  On the other hand, in the fifth embodiment, as shown in FIG. 8, the mounting plate 51 is rotated around the rotation axis 53 of the fan main body 32 to install the first space 54 a. The area of the second space 54b and the area of the third space 54c may be substantially the same.

  According to this, since the air blown out from the air outlet 40 of the fan main body 32 to the discharge side space 30 flows almost evenly through the spaces 54a, 54b, 54c toward the air supply port 22, the pressure loss is further reduced.

  In the above embodiments, the mounting plate 51 is formed in a regular triangle shape, but may be formed in a triangle shape other than a regular triangle. In addition, as shown in the said FIG. 2, a triangle shape includes the shape which each tip corner | angular part of the mounting plate 51 was formed flat, and each shape shown to the said FIG. 7 (a)-FIG.7 (c). .

In each of the above embodiments, the fan chambers 11 and 12 have a square cross-sectional shape, but a square other than the square (for example, a rectangle) may be used.
In each of the above embodiments, as shown in FIGS. 3 and 4, the buffer means 37 that absorbs vibrations of the fan devices 28 and 45 is attached to the base plate 31, but is buffered to the column 52 that supports the mounting plate 51. It is good also as a structure to which the means 37 was attached.

It is a perspective view of the air conditioner provided with the fan chamber in the 1st Embodiment of this invention. It is a top view which shows the support structure of the fan apparatus in an air supply fan chamber. FIG. 3 is an XX arrow view in FIG. 2. It is a YY arrow line view in FIG. It is an enlarged plan view of the fan main body and the support of the fan device. It is a top view which shows an example of the magnitude | size of the attachment plate of the support structure of a fan apparatus, (a) is a conventional thing, (b) shows the thing of this Embodiment. It is a top view of the mounting plate of the support structure of a fan apparatus, (a) shows 2nd Embodiment, (b) shows 3rd Embodiment, (c) shows 4th Embodiment. It is a top view which shows the support structure of the fan apparatus in the fan room for air supply in the 5th Embodiment of this invention. It is a longitudinal cross-sectional view of the air conditioner provided with the conventional fan chamber. It is a side view which shows the support structure of the fan apparatus in a fan chamber, (a) shows the fan apparatus for air supply, (b) shows the fan apparatus for return air. It is XX arrow line view in Fig.10 (a).

Explanation of symbols

10 Air Conditioner 12 Fan Chamber 21 Suction Port 22 Air Supply Port (Discharge Port)
28 Fan device 29 Suction side space 30 Discharge side space 31 Base plate (partition body)
32 Fan body 33 Drive device 39 Air inlet 40 Air outlet 51 Mounting plate (mounting member)
52 Prop (support member)
52a Column side surface 52b Column tip B Fan body diameter E Inscribed circle F of mounting plate Diameter of inscribed circle

Claims (4)

A fan device support structure of an air conditioner provided in a fan chamber having a suction port and a discharge port and partitioned into a suction side space and a discharge side space by a partition,
The fan device is installed in the discharge side space and has a fan main body and a driving device that rotationally drives the fan main body.
An air outlet is formed on the outer periphery of the fan body to blow out air in the suction side space taken from the air intake into the discharge side space.
The drive is attached to the mounting member;
The mounting member is supported by the partition via three support members,
Each support member is arrange | positioned around the fan main body, The fan apparatus support structure of the air conditioner characterized by the above-mentioned. The mounting member is formed in a triangular shape, and is arranged in the middle of the flow path in which the air blown from the air outlet of the fan body flows to the outlet of the fan chamber,
2. The fan unit support structure for an air conditioner according to claim 1, wherein each support member is disposed at each corner of the mounting member. Each support member and the fan body are provided between the mounting member and the partition,
3. The fan device support structure for an air conditioner according to claim 2, wherein the diameter of the inscribed circle of the mounting member is set shorter than the diameter of the fan body. The support member has two side surfaces forming a V shape and a tip portion where these both side surfaces intersect,
The fan device support structure for an air conditioner according to any one of claims 1 to 3, wherein a tip end portion of the support member faces an air outlet of the fan body.

Images