JP6492445B2 - Sirocco fan and pneumatic conveying device - Google Patents

Description

    The present invention relates to a sirocco fan and an air conveyance device.

    Conventionally, a sirocco fan (multi-blade fan) is known as a blower for blowing air. For example, the sirocco fan disclosed in Patent Document 1 is mounted on a humidity control apparatus.

    The humidity control apparatus includes two adsorption heat exchangers on which an adsorbent is supported, and is configured to dehumidify or humidify outdoor air and supply it to the room. Specifically, during operation of the humidity control apparatus, an air supply fan and an exhaust fan configured by a sirocco fan operate. When the air supply fan operates, outdoor air passes through the adsorption heat exchanger, and this air is dehumidified or humidified and supplied to the room. When the exhaust fan is activated, room air passes through the adsorption heat exchanger, and this air regenerates the moisture in the adsorption heat exchanger or imparts moisture to the adsorption heat exchanger and is discharged to the outside.

JP 2009-19864 A

    By the way, in a sirocco fan, a fan rotor is accommodated in the fan casing, and this fan rotor is rotationally driven by a motor. Here, in this type of sirocco fan, there is a fan in which suction ports are formed on both sides of the fan casing in the cylinder axis direction.

    In this sirocco fan, as a method of rectifying the air just before being sucked into the suction port, a convex bell mouth bulging outward in the axial direction is formed on both sides of the fan casing, and a suction port is formed inside the bell mouth A structure that can be considered. Thereby, the air on the outer peripheral side of the bell mouth is rectified so as to follow the inner wall of the bell mouth, and the fan performance can be improved.

    However, when convex bellmouths are formed on both sides of the fan casing as described above, the distance between the motor and the bellmouth adjacent to the motor is reduced. As a result, in the bell mouth close to the motor, the motor becomes an obstacle to the intake air, and the resistance of the intake air may increase. As a result, there is a problem that the fan efficiency is lowered due to the resistance of the intake air.

    This invention is made | formed in view of this point, The objective is to provide the sirocco fan which can obtain high fan efficiency.

    A first invention is directed to a sirocco fan, and includes a motor (82), a fan rotor (84) that is rotationally driven by the motor (82), and a substantially cylindrical main body that houses the fan rotor (84). A fan casing (85) having (90), the fan casing (85) being disposed on the opposite side to the motor (82) of both sides of the main body (90) in the cylinder axis direction, The first bell mouth (91) in which the suction port (91a) is formed and the motor (82) side of both sides of the main body (90) in the cylinder axis direction are arranged, and the second suction port (92a) And a second bell mouth (92) side surface (90b) of the main body portion (90). When the distance from the motor (82) to the motor (82) is L, the fan casing (85) is configured so that L / D ≦ 0.4. The first bell mouth (91) is configured to bulge outward in the axial direction from the side surface (90a) of the main body (90), and the second bell mouth (92) The fan casing (85) is configured to bulge outward in the axial direction from the side surface (90b) of the portion (90), and the fan casing (85) includes the side surface (90b) of the main body (90) in the second bell mouth (92) The bulging height H2 outward in the axial direction from the side is smaller than the bulging height H1 outward in the axial direction from the side surface (90a) of the main body (90) in the first bell mouth (91). It is comprised by this.

    In the first invention, bell mouths (91, 92) are respectively formed on both sides of the main body (90) of the fan casing (85) in the cylinder axis direction. The first bell mouth (91) on the opposite side of the motor (82) is formed with a first suction port (91a), and the second bell mouth (92) on the motor (82) side has a second suction port ( 92a) is formed. When the motor (82) drives the fan rotor (84), air is sucked from the suction ports (91a, 92a) and blown out in a predetermined direction.

    In the fan casing (85) of the present invention, the inner diameter of the second suction port (92a) is D, and the distance from the side surface (90b) on the second bell mouth (92) side of the main body (90) to the motor (82) If L is L, L / D ≦ 0.4. That is, the distance L from the motor (82) to the main body (90) is relatively small with respect to the inner diameter D of the second suction port (92a). Accordingly, the air sucked into the second suction port (92a) is subject to the interference of the motor (82), so that the resistance of the suction air is likely to increase.

    However, in the present invention, the bulging height H2 from the side surface (90b) of the main body portion (90) in the second bell mouth (92) to the axially outward direction is such that the main body portion in the first bell mouth (91) ( 90) is configured to be smaller than the bulging height H1 outward in the axial direction from the side surface (90a). Therefore, a sufficient distance between the second suction port (92a) and the motor (82) is secured, and the resistance of the suction air at the second suction port (92a) is reduced.

    The first bell mouth (91) bulges in the radial direction from the side surface (90a) of the main body (90). For this reason, the air on the outer periphery of the first suction port (91a) of the first bell mouth (91) is rectified when passing through the first suction port (91a).

    According to a second aspect, in the first aspect, the fan casing (85) is configured such that L / D = 0.4 and L / H2 ≧ 10.

    In the second invention, since the fan casing (85) satisfies the relationship of L / D = 0.4, the distance between the motor (82) and the main body (90) becomes excessively large or narrow. Can be avoided. Furthermore, in this invention, it can avoid that the distance between a motor (82) and a 2nd suction inlet (92a) becomes too narrow by setting it as L / H2> = 10, and a 2nd suction inlet ( It is possible to reduce the resistance of the air sucked into 92a).

A third invention includes a casing (20) and a sirocco fan (80), and inside the casing (20), a chamber (39, 40) in which the sirocco fan (80) is disposed, An air passage (36,38) communicating with the chamber (39,40) and flowing upstream of the chamber (39,40) is formed, and the sirocco fan (80) includes the motor (82) A fan rotor (84) that is rotationally driven by a motor (82); and a fan casing (85) having a substantially cylindrical main body (90) that houses the fan rotor (84). ) Is arranged on the opposite side of the motor (82) of both sides of the main body (90) in the cylinder axis direction, and a first bell mouth (91) in which a first suction port (91a) is formed; A second bell that is disposed on the motor (82) side of both sides of the main body (90) in the cylinder axis direction and has a second suction port (92a). The motor (82) from the side surface (90b) on the second bell mouth (92) side of the main body (90), wherein the inner diameter of the second suction port (92a) is D. When the distance up to L is L, the fan casing (85) is configured to satisfy L / D ≦ 0.4, and the first bell mouth (91) is formed on the side surface (90a of the main body (90). ) Swell outward in the axial direction, and the fan casing (85) swells outward in the axial direction from the side surface (90b) of the main body (90) of the second bell mouth (92). The protruding height H2 is configured to be smaller than the bulging height H1 extending axially outward from the side surface (90a) of the main body (90) in the first bell mouth (91). The first suction port (91a) of the mouse (91) faces the outflow end side of the air passage (36, 38) and extends from the air passage (36, 38). Air flowing out to the (39, 40) is drawn into the first inlet of the first bell mouth (91) (91a) and the second second suction port of the bell mouth (92) (92a), said second bell The mouse (92) is an air conveyance device configured to bulge outward from the side surface (90b) of the main body (90) in the axial direction .

In a fourth aspect based on the third aspect , the fan casing (85) is configured so that L / D = 0.4 and L / H2 ≧ 10. It is.

    According to the first and third inventions, even if the distance between the motor (82) and the main body (90) is relatively small, the gap between the motor (82) and the second suction port (92a) A sufficient distance can be secured, and the resistance of the suction air at the second suction port (92a) can be reduced, and consequently the fan efficiency can be improved. Moreover, the installation space of the sirocco fan can be reduced by relatively reducing the distance between the motor (82) and the main body (90).

    Further, according to the first and third inventions, since the first bell mouth (91) bulges outward in the axial direction, the intake air can be sufficiently rectified at the first suction port (91a). As a result, fan efficiency can be further improved.

According to the second and fourth inventions, by setting L / H2 ≧ 10, a sufficient distance between the motor (82) and the second suction port (92a) can be secured, and the second suction port (92a ) Can be reliably reduced. As a result, fan efficiency can be further improved.

FIG. 1 is a plan view showing a schematic configuration of a humidity control apparatus according to a reference embodiment. FIG. 2 is a view (right view) taken along the arrow II in FIG. 1 showing the internal structure of the humidity control apparatus according to the reference embodiment. FIG. 3 is a view (left view) taken along the line III in FIG. 1 showing the internal structure of the humidity control apparatus according to the reference embodiment. FIG. 4A is a schematic piping system diagram of the refrigerant circuit and shows the first operation. FIG. 4B is a schematic piping system diagram of the refrigerant circuit, and shows the second operation. FIG. 5 is a perspective view of a sirocco fan according to a reference embodiment. FIG. 6 is a top view of the sirocco fan according to the reference embodiment. 7 is a cross-sectional view of the sirocco fan according to the reference embodiment, taken along the line VII-VII in FIG. FIG. 8 is a graph showing the relationship between L / D and efficiency α of the sirocco fan according to the comparative example. Figure 9 is a top view of a sirocco fan according to the embodiment form state. Figure 10 is a graph showing the relationship between the sirocco fan L / H2 and efficiency α according to an exemplary shape state.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

A reference embodiment as a premise of the present invention will be described. The sirocco fan (80) (multi-blade fan) according to the reference form is applied to the humidity control apparatus (10).

    The humidity control apparatus (10) is configured to switch between a dehumidifying operation and a humidifying operation. The humidity controller (10) includes a casing (20), a refrigerant circuit (50), and two fans (60, 70).

<casing>
As shown in FIGS. 1 to 3, the casing (20) is formed in a rectangular parallelepiped box shape having a low vertical height. The casing (20) has a front panel (21), a rear panel (22), a first side panel (23), a second side panel (24), a bottom plate (25), and a top plate (26). .

    The first side panel (23) is formed on the right side (right side in FIG. 1) of the casing (20), and the second side panel (24) is formed on the left side (left side in FIG. 1) of the casing (20). . The first side panel (23) has an outside air inlet (31) formed in the upper middle portion and an exhaust port (32) formed in the upper rear portion. The second side panel (24) has an inside air inlet (33) formed in the lower middle part and an air inlet (34) formed in the lower rear part. An outdoor air duct (31a) communicating with the outside is connected to the outside air inlet (31), and an exhaust duct (32a) communicating with the outside is connected to the exhaust port (32). An indoor air duct (33a) communicating with the room is connected to the room air inlet (33), and an air supply duct (34a) communicating to the room is connected to the air supply port (34).

    An outside air passage (35) and an exhaust passage (36) are formed along the first side panel (23) near the front surface inside the casing (20). The outside air passage (35) is formed above the air supply passage (38) and communicates with the outside air suction port (31). An inside air passage (37) and an air supply passage (38) are formed along the second side panel (24) near the front surface inside the casing (20). The inside air passage (37) is formed below the air supply passage (38), and communicates with the inside air suction port (33).

    A first heat exchanger chamber (41) and a second heat exchanger chamber (42) are formed in a central portion near the front surface inside the casing (20). Each of the heat exchanger chambers (41, 42) faces four dampers (45). The first heat exchanger chamber (41) is intermittently connected to the outside air passage (35), the exhaust passage (36), the inside air passage (37), and the air supply passage (38) via each damper (45). The second heat exchanger chamber (42) is intermittently connected to the outside air passage (35), the exhaust passage (36), the inside air passage (37), and the air supply passage (38) via each damper (45).

    An exhaust chamber (39) is formed along the first side panel (23) and an air supply chamber (40) is formed along the second side panel (24) on the rear side inside the casing (20). The The exhaust chamber (39) communicates with the exhaust passage (36) and the exhaust port (32), and the air supply chamber (40) communicates with the air supply passage (38) and the air supply port (34).

<Refrigerant circuit>
As shown in FIG. 4, the humidity control apparatus (10) includes a refrigerant circuit (50) filled with a refrigerant. In the refrigerant circuit (50), a refrigerant is circulated to perform a vapor compression refrigeration cycle. A compressor (51), a first adsorption heat exchanger (52), an expansion valve (53), a second adsorption heat exchanger (54), and a four-way switching valve (55) are connected to the refrigerant circuit (50). The

    As shown in FIG. 1, the compressor (51) is disposed on the right side of the air supply chamber (40). Each adsorption heat exchanger (52, 54) carries an adsorbent (sorbent) that adsorbs or desorbs moisture on the surface of a fin-and-tube heat exchanger. The first adsorption heat exchanger (52) is disposed in the first heat exchanger chamber (41), and the second adsorption heat exchanger (54) is disposed in the second heat exchanger chamber (42).

    The four-way switching valve (55) has a first port communicating with the discharge side of the compressor (51) and a second port communicating with the suction side of the compressor (51). The four-way switching valve (55) has a third port communicating with the gas side end of the first adsorption heat exchanger (52) and a fourth port communicating with the gas side end of the second adsorption heat exchanger (54). And have. The four-way selector valve (55) has a first state (FIG. 4A) in which the first port and the third port communicate with each other and the second port and the fourth port communicate with each other, and the first port and the fourth port communicate with each other. The communication is switched to the second state (FIG. 4B) in which the second port and the third port communicate.

<Structure of sirocco fans>
The exhaust fan (60) and the air supply fan (70) are each composed of a sirocco fan (80) having the same configuration. As shown in FIG. 1, the exhaust fan (60) is disposed in the exhaust chamber (39), and the air supply fan (70) is disposed in the air supply chamber (40). The air outlet (61) of the exhaust fan (60) is connected to the exhaust port (32), and the air outlet (71) of the air supply fan (70) is connected to the air supply port (34).

    The detailed configuration of the sirocco fan (80) will be described with reference to FIGS.

    The sirocco fan (80) has a motor support (81), a motor (82), a shaft (83), a fan rotor (84), and a fan casing (85).

    The motor support (81) is installed on the bottom plate (25) of the humidity control device (10). The motor support base (81) includes a pair of vertically long plate-like support plates (81a), a base plate (81b) extending over each lower end of the pair of support plates (81a), and a pair of support plates (81a). And an intermediate plate (81c) interposed in a vertical posture. The upper ends of the pair of support plates (81a) are formed in a tapered shape whose width becomes narrower upward.

    The motor (82) is supported between the upper ends of the pair of support plates (81a). The motor (82) is disposed to face the rear panel (22) of the humidity control device (10) (see FIG. 1).

    One end of the shaft (83) is connected to the axial center of the motor (82). The other end of the shaft (83) is connected to the axial center of the fan rotor (84).

    The fan rotor (84) constitutes an impeller whose outer shape is formed in a substantially cylindrical shape. On the outer peripheral side of the fan rotor (84), a plurality of blades (84a) are arranged in the circumferential direction at substantially equal intervals.

The fan casing (85) constitutes a casing that houses a part of the shaft (83) and the fan rotor (84). This reference embodiment of the fan casing (85), the resin of the casing part (86), and a metallic closing member (87).

    The case part (86) is formed in a hollow shape with the motor (82) side opened. The case portion (86) includes a substantially cylindrical housing portion (86a) in which the fan rotor (84) is housed, and a rectangular air outlet (61, 71) communicating with the inside of the housing portion (86a). Have.

    The blocking member (87) covers the entire area of the open part on the motor (82) side of the case part (86). The closing member (87) includes a substantially rectangular closing support plate (88) extending from the upper end of the case portion (86) to the bottom plate (25) of the humidity control device (10), and the closing support plate (88). And a suction plate (89) disposed at the top. The suction plate (89) is fixed to the closing support plate (88) via screws (fastening members) so as to overlap the surface of the closing support plate (88). An opening is formed in a portion of the closing support plate (88) corresponding to the suction plate (89), and the suction plate (89) covers this opening.

In this preferred embodiment, the upper portion of the housing portion of the case portion (86) (86a) and the closure support plate (88) constitutes a substantially cylindrical body portion (90). That is, the main body (90) is disposed adjacent to the motor (82) so as to be coaxial with the motor (82), and accommodates the entire fan rotor (84).

    Bell mouths (91, 92) are respectively formed on both sides of the main body (90) in the cylinder axis direction. Among these bell mouths (91, 92), the bell mouse on the opposite side of the motor (82) constitutes the first bell mouth (91), and the bell mouse on the motor (82) side constitutes the second bell mouth (92). It is composed.

    The first bell mouth (91) is formed integrally with the resin case (86). The first bell mouth (91) bulges outward in the axial direction from the first side surface (90a) of the main body (90) opposite to the motor (82) (see FIGS. 6 and 7). Yes. A first suction port (91a) is formed inside the first bell mouth (91). The inner peripheral edge of the first suction port (91a) is configured in a substantially trumpet shape that increases the inner diameter as it goes outward in the axial direction. As shown in FIG. 1, the first bell mouth (91) (first suction port (91a)) of the exhaust fan (60) faces the exhaust passage (36), and the first bell of the air supply fan (70). The mouse (91) (first suction port (91a)) faces the air supply passage (38).

    The second bell mouth (92) is formed at the center of the suction plate (89). The second bell mouth (92) is configured to be substantially flush with the second side surface (90b) on the motor (82) side of the main body (90). That is, the second bell mouth (92) does not bulge outward in the axial direction from the main body (90), and is configured to be flat.

    In the second bell mouth (92), the second suction port (92a) is formed inside by drawing the sheet metal. The inner peripheral edge of the second suction port (92a) is configured in a substantially trumpet shape that increases the inner diameter as it goes outward in the axial direction.

<Dimensions of sirocco fan>
The dimensional relationships of the sirocco fan (80) according to this reference embodiment will be described with reference to FIG. In the fan casing (85), the first bell mouth (91) bulges outward in the axial direction from the first side surface (90a) of the main body (90). That is, the bulging height H1 of the first bell mouth (91) is a predetermined length greater than 0,
On the other hand, in the fan casing (85), the second bell mouth (92) does not bulge outward from the second side surface (90b) of the main body (90) in the axial direction. That is, the bulging height H2 of the second bell mouth (92) can be substantially zero.

    In the sirocco fan (80), the distance from the side surface on the fan casing (85) side to the second side surface (90b) of the motor (82) is L, and the second suction port (92a) of the second bell mouth (92) When the inner diameter (strictly speaking, the maximum inner diameter shown in FIGS. 5 and 7) is D, L / D ≦ 0.4. That is, in the sirocco fan (80), the distance L between the motor (82) and the main body (90) is relatively narrow with respect to the inner diameter D of the second suction port (92a). The distance L is 54 mm, for example, and the inner diameter D is 175 mm, for example. That is, L / D is about 0.3.

-Driving action-
Next, the operation of the humidity control apparatus (10) will be described with reference to FIGS. During operation of the humidity control apparatus (10), the refrigeration cycle is performed in the refrigerant circuit (50), and at the same time, the air supply fan (70) and the exhaust fan (60) are activated.

[Dehumidifying operation]
In the dehumidifying operation of the humidity control apparatus (10), the first operation and the second operation are repeated. In the first operation, a refrigeration cycle is performed in which the first adsorption heat exchanger (52) serves as a radiator (condenser) and the second adsorption heat exchanger (54) serves as an evaporator. In the second operation, a refrigeration cycle is performed in which the second adsorption heat exchanger (54) serves as a radiator (condenser) and the first adsorption heat exchanger (52) serves as an evaporator.

    In the first operation, the open / close state of the damper (45) is switched so that the outdoor air (OA) passes through the outdoor air passage (35), the second heat exchanger chamber (42), and the air supply passage (38) in this order. As a result, the outdoor air (OA) is dehumidified by the second adsorption heat exchanger (54), and is supplied via the air supply passage (38), the air supply chamber (40), and the air supply port (34). SA) is supplied indoors. In the first operation, the open / close state of the damper (45) is switched so that the room air (RA) passes through the inside air passage (37), the first heat exchanger chamber (41), and the exhaust passage (36) in this order. . Thereby, the indoor air (RA) is used for regeneration of the adsorbent of the first adsorption heat exchanger (52), and the outdoor air is exhausted through the exhaust passage (36), the exhaust chamber (39), and the exhaust port (32). It is discharged outside as air (EA).

    In the second operation, the open / close state of the damper (45) is switched so that the outdoor air (OA) passes through the outdoor air passage (35), the first heat exchanger chamber (41), and the air supply passage (38) in this order. As a result, the outdoor air (OA) is dehumidified by the first adsorption heat exchanger (52), and is supplied via the air supply passage (38), the air supply chamber (40), and the air supply port (34). SA) is supplied indoors. In the second operation, the open / close state of the damper (45) is switched so that the room air (RA) passes through the inside air passage (37), the second heat exchanger chamber (42), and the exhaust passage (36) in this order. . Thereby, the indoor air (RA) is used for regeneration of the adsorbent of the second adsorption heat exchanger (54), and the outdoor air is exhausted through the exhaust passage (36), the exhaust chamber (39), and the exhaust port (32). It is discharged outside as air (EA).

[Humidification operation]
In the humidifying operation of the humidity control apparatus (10), the first operation and the second operation are repeated.

    In the first operation, the open / close state of the damper (45) is switched so that the outdoor air (OA) passes through the outdoor air passage (35), the first heat exchanger chamber (41), and the air supply passage (38) in this order. As a result, the outdoor air (OA) is humidified by the first adsorption heat exchanger (52) and supplied through the air supply passage (38), the air supply chamber (40), and the air supply port (34) ( SA) is supplied indoors. In the first operation, the open / close state of the damper (45) is switched so that the room air (RA) passes through the inside air passage (37), the second heat exchanger chamber (42), and the exhaust passage (36) in this order. . As a result, the indoor air (RA) imparts moisture to the adsorbent of the second adsorption heat exchanger (54), and passes through the exhaust passage (36), the exhaust chamber (39), and the exhaust port (32). It is discharged outside as air (EA).

    In the second operation, the open / close state of the damper (45) is switched so that the outdoor air (OA) passes through the outdoor air passage (35), the second heat exchanger chamber (42), and the air supply passage (38) in this order. As a result, the outdoor air (OA) is humidified by the second adsorption heat exchanger (54) and supplied through the air supply passage (38), the air supply chamber (40), and the air supply port (34). SA) is supplied indoors. In the second operation, the open / close state of the damper (45) is switched so that the room air (RA) passes through the inside air passage (37), the first heat exchanger chamber (41), and the exhaust passage (36) in this order. . As a result, the indoor air (RA) gives moisture to the adsorbent of the first adsorption heat exchanger (52), and the outdoor air passes through the exhaust passage (36), the exhaust chamber (39), and the exhaust port (32). It is discharged outside as air (EA).

<Functional effects of sirocco fan>
In the above-described dehumidifying operation and humidifying operation, the air supply fan (70) and the exhaust fan (60) operate. In these sirocco fans (80), the motor (82) rotationally drives the fan rotor (84), whereby air is sucked from the first suction port (91a) and the second suction port (92a), respectively. The sucked air changes its direction in the circumferential direction (tangential direction) of the fan rotor (84), and is blown out from each outlet (61, 71).

Here, in the sirocco fan (80) of this reference form, in order to reduce the installation space, the motor (82) and the main body (90) of the fan casing (85) with respect to the inner diameter D of the second suction port (92a) ) Is relatively small. Specifically, the fan casing (85) is configured to satisfy L / D ≦ 0.4. However, as L / D is reduced as described above, there arises a problem that the efficiency of the fan decreases. This point will be described with reference to FIG.

    FIG. 8 is a graph for verifying how much the efficiency of the fan decreases when L / D is changed in the sirocco fan of the comparative example. Here, the efficiency α on the vertical axis is obtained by η2 / η1. η1 is the efficiency (maximum efficiency) of the fan when they are separated as much as possible so that the motor does not interfere with the intake air of the second intake port. On the other hand, η2 is the efficiency of the fan measured by changing L / D. That is, the lower the efficiency α, the lower the actual fan efficiency η2 with respect to the maximum fan efficiency η1.

    Note that the sirocco fan of the comparative example has a pair of convex bell mouths that bulge outwardly in the axial direction at the same bulging height from the side surfaces on both sides of the main body of the fan casing.

    As shown in FIG. 8, in the sirocco fan of the comparative example, it can be seen that when the L / D is 0.4 or less, the efficiency α is rapidly reduced. That is, in the sirocco fan of the comparative example, when the motor and the main body are brought close to each other in order to reduce the installation space, the motor interferes with the second suction port, and the resistance of the air sucked into the second suction port increases. Resulting in. As a result, there arises a problem that the efficiency α shown on the vertical axis is lowered.

Therefore, in this reference embodiment, the second bell mouth (92) is formed in a flat shape without bulging outward in the axial direction. As a result, as shown in FIG. 7, a sufficient distance between the motor (82) and the second suction port (92a) can be secured, thereby preventing the motor (82) from interfering with the second suction port (92a). it can. As a result, the resistance of the suction air at the second suction port (92a) can be reduced, and the motor efficiency can be improved.

Further, in this preferred embodiment, the motor (82) is not adjacent, the air passage (supply passage (38) or an exhaust passage (36)) of the first bell mouth (91) facing outward in the axial direction It is bulging. For this reason, in the first bell mouth (91), ambient air can be sucked in while rectifying, and the efficiency of the motor can be further improved.

-Effect of reference form-
According to this preferred embodiment, the motor (82) and even the distance is relatively narrow state of the main body portion (90) of the fan casing (85), a motor (82) and the second suction port (92a) A sufficient distance can be secured between them, and the resistance of the suction air at the second suction port (92a) can be reduced, and consequently the fan efficiency can be improved. Moreover, the installation space of the sirocco fan (80) can be reduced by relatively reducing the distance between the motor (82) and the main body (90) of the fan casing (85).

    In addition, when the distance between the motor (82) and the second suction port (92a) can be sufficiently secured under the condition where L / D is 0.4 or less, the second suction port (92a ) Can be increased in flow rate or flow velocity of the air sucked into. As a result, the fan performance of the sirocco fan (80) can be improved.

    Further, since the first bell mouth (91) bulges outward in the axial direction, the intake air can be sufficiently rectified at the first suction port (91a). As a result, fan efficiency can be further improved.

Moreover, in this reference form, since it is not necessary to bulge the 2nd bellmouth (92) to axial direction outward, the 2nd bellmouth (92) can be easily shape | molded by drawing-processing a sheet metal.

<Embodiment >
Exemplary type status in the configuration of the Reference Embodiment with the sirocco fan (80) are different. As shown in FIG. 9, the sirocco fan (80) of the embodiment, unlike the reference embodiment, bulges to the second bell mouth (92) protruding also axially outwardly. The bulging height H2 of the second bell mouth (92) is smaller than the bulging height H1 of the first bell mouth (91).

Further, embodiments of the fan casing (85) is configured such that the L / D = 0.4. Thereby, while the installation space of the sirocco fan (80) becomes comparatively small, the distance between the motor (82) and the second suction port (92a) is not excessively narrowed. Furthermore, the fan casing (85) of the embodiment is configured to satisfy L / H2 ≧ 10. This point will be described with reference to FIG.

    FIG. 10 is a graph showing the relationship between the efficiency α described above and the horizontal axis L / H2. As can be seen from this graph, when L / H2 is less than 10, the efficiency α is significantly reduced. This is because the bulging height H2 of the second bell mouth (92) is relatively large with respect to the distance L between the motor (82) and the main body (90), and the motor (82) is second. It is because it becomes easy to interfere with a suction inlet (92a). On the other hand, when L / H2 is 10 or more, the efficiency α reaches almost the maximum value (α = 1.0). This is because the motor (82) is less likely to interfere with the second suction port (92a) due to the bulge height H2 being reduced, and the resistance of the suction air is reduced.

As described above, in the embodiment , by satisfying the relational expression of H2 <H1, L / D = 0.4 and L / H2 ≧ 10, the resistance of the intake air at the second suction port (92a) can be reduced, In addition, a sufficient rectifying effect in the first bell mouth (91) can be obtained.

    Also, under such conditions, if a sufficient distance between the motor (82) and the second suction port (92a) can be secured, the flow rate or flow rate of air sucked into the second suction port (92a) can be reduced. Can be increased. As a result, the fan performance of the sirocco fan (80) can be improved.

<< Other Embodiments >>
In the embodiment described above, the sirocco fan (80) according to the present invention is employed for both the air supply fan (70) and the exhaust fan (60), but may be employed for only one of them.

    In this embodiment, the sirocco fan (80) is mounted on the humidity control device (10). However, the sirocco fan (80) is installed in other devices (devices for conveying air) such as a ventilation device, an air conditioner, and an air purifier. The sirocco fan (80) according to the invention may be mounted.

    As described above, the present invention is useful for a sirocco fan and an air conveyance device.

60 Exhaust fan (sirocco fan)
70 Air supply fan (sirocco fan)
80 Sirocco fans
82 Motor
84 Fan rotor
85 Fan casing
90 Main unit
90a 1st side
90b 2nd side
91 1st Bellmouth
91a 1st inlet
92 2nd Bell Mouse
92a 2nd inlet

Claims (4)

A sirocco fan
A motor (82),
A fan rotor (84) driven to rotate by the motor (82);
A fan casing (85) having a substantially cylindrical main body (90) for accommodating the fan rotor (84),
The fan casing (85)
A first bell mouth (91) disposed on the opposite side of the motor (82) of both sides of the main body (90) in the cylinder axis direction and having a first suction port (91a);
A second bell mouth (92) that is disposed on the motor (82) side of both sides of the main body (90) in the cylindrical axis direction and has a second suction port (92a);
When the inner diameter of the second suction port (92a) is D, and the distance from the side surface (90b) on the second bell mouth (92) side of the main body (90) to the motor (82) is L,
The fan casing (85) is configured to satisfy L / D ≦ 0.4,
The first bell mouth (91) is configured to bulge outward in the axial direction from the side surface (90a) of the main body (90),
The second bell mouth (92) is configured to bulge outward in the axial direction from the side surface (90b) of the main body (90),
The fan casing (85) has a height H2 bulging outward from the side surface (90b) of the main body (90) in the second bell mouth (92) in the first bell mouth (91). A sirocco fan, characterized in that the sirocco fan is configured to be smaller than a bulging height H1 outward from the side surface (90a) of the main body (90). In claim 1,
The sirocco fan, wherein the fan casing (85) is configured such that L / D = 0.4 and L / H2 ≧ 10. A casing (20);
With sirocco fan (80),
Inside the casing (20) is a chamber (39, 40) in which the sirocco fan (80) is disposed, and communicates with the chamber (39, 40) and air upstream of the chamber (39, 40). Air passage (36,38) through which
The sirocco fan (80)
A motor (82),
A fan rotor (84) driven to rotate by the motor (82);
A fan casing (85) having a substantially cylindrical main body (90) for accommodating the fan rotor (84),
The fan casing (85)
A first bell mouth (91) disposed on the opposite side of the motor (82) of both sides of the main body (90) in the cylinder axis direction and having a first suction port (91a);
A second bell mouth (92) that is disposed on the motor (82) side of both sides of the main body (90) in the cylindrical axis direction and has a second suction port (92a);
When the inner diameter of the second suction port (92a) is D, and the distance from the side surface (90b) on the second bell mouth (92) side of the main body (90) to the motor (82) is L,
The fan casing (85) is configured to satisfy L / D ≦ 0.4,
The first bell mouth (91) is configured to bulge outward in the axial direction from the side surface (90a) of the main body (90),
The fan casing (85) has a height H2 bulging outward from the side surface (90b) of the main body (90) in the second bell mouth (92) in the first bell mouth (91). It is configured to be smaller than the bulging height H1 from the side surface (90a) of the main body (90) outward in the axial direction,
The first suction port (91a) of the first bell mouth (91) faces the outflow end side of the air passage (36, 38),
The air that flows out from the air passage (36, 38) into the chamber (39, 40) is the first suction port (91a) of the first bell mouth (91) and the second suction port of the second bell mouth (92). sucked in (92a),
The second bell mouth (92) is configured to bulge outward from the side surface (90b) of the main body (90) in the axial direction . In claim 3 ,
The fan casing (85) is configured so that L / D = 0.4 and L / H2 ≧ 10.

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