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AU2009237152B2 - Turbofan and air conditioner - Google Patents

Turbofan and air conditioner Download PDF

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Publication number
AU2009237152B2
AU2009237152B2 AU2009237152A AU2009237152A AU2009237152B2 AU 2009237152 B2 AU2009237152 B2 AU 2009237152B2 AU 2009237152 A AU2009237152 A AU 2009237152A AU 2009237152 A AU2009237152 A AU 2009237152A AU 2009237152 B2 AU2009237152 B2 AU 2009237152B2
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AU
Australia
Prior art keywords
blade
plate
side plate
edge
turbofan
Prior art date
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Active
Application number
AU2009237152A
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AU2009237152A1 (en
Inventor
Atsushi Edayoshi
Shingo Hamada
Takashi Ikeda
Kazuya Kubo
Kazutaka Suzuki
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Mitsubishi Electric Corp
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Mitsubishi Electric Corp
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Publication of AU2009237152A1 publication Critical patent/AU2009237152A1/en
Application granted granted Critical
Publication of AU2009237152B2 publication Critical patent/AU2009237152B2/en
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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04DNON-POSITIVE-DISPLACEMENT PUMPS
    • F04D29/00Details, component parts, or accessories
    • F04D29/26Rotors specially for elastic fluids
    • F04D29/28Rotors specially for elastic fluids for centrifugal or helico-centrifugal pumps for radial-flow or helico-centrifugal pumps
    • F04D29/281Rotors specially for elastic fluids for centrifugal or helico-centrifugal pumps for radial-flow or helico-centrifugal pumps for fans or blowers
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04DNON-POSITIVE-DISPLACEMENT PUMPS
    • F04D29/00Details, component parts, or accessories
    • F04D29/26Rotors specially for elastic fluids
    • F04D29/28Rotors specially for elastic fluids for centrifugal or helico-centrifugal pumps for radial-flow or helico-centrifugal pumps
    • F04D29/281Rotors specially for elastic fluids for centrifugal or helico-centrifugal pumps for radial-flow or helico-centrifugal pumps for fans or blowers
    • F04D29/282Rotors specially for elastic fluids for centrifugal or helico-centrifugal pumps for radial-flow or helico-centrifugal pumps for fans or blowers the leading edge of each vane being substantially parallel to the rotation axis
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04DNON-POSITIVE-DISPLACEMENT PUMPS
    • F04D29/00Details, component parts, or accessories
    • F04D29/26Rotors specially for elastic fluids
    • F04D29/28Rotors specially for elastic fluids for centrifugal or helico-centrifugal pumps for radial-flow or helico-centrifugal pumps
    • F04D29/30Vanes
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F1/00Room units for air-conditioning, e.g. separate or self-contained units or units receiving primary air from a central station
    • F24F1/0007Indoor units, e.g. fan coil units
    • F24F1/0018Indoor units, e.g. fan coil units characterised by fans
    • F24F1/0022Centrifugal or radial fans
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F1/00Room units for air-conditioning, e.g. separate or self-contained units or units receiving primary air from a central station
    • F24F1/0007Indoor units, e.g. fan coil units
    • F24F1/0035Indoor units, e.g. fan coil units characterised by introduction of outside air to the room
    • F24F1/0038Indoor units, e.g. fan coil units characterised by introduction of outside air to the room in combination with simultaneous exhaustion of inside air
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F1/00Room units for air-conditioning, e.g. separate or self-contained units or units receiving primary air from a central station
    • F24F1/0007Indoor units, e.g. fan coil units
    • F24F1/0043Indoor units, e.g. fan coil units characterised by mounting arrangements
    • F24F1/0047Indoor units, e.g. fan coil units characterised by mounting arrangements mounted in the ceiling or at the ceiling
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F13/00Details common to, or for air-conditioning, air-humidification, ventilation or use of air currents for screening
    • F24F13/02Ducting arrangements
    • F24F13/06Outlets for directing or distributing air into rooms or spaces, e.g. ceiling air diffuser
    • F24F2013/0616Outlets that have intake openings

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Structures Of Non-Positive Displacement Pumps (AREA)
  • Air-Conditioning Room Units, And Self-Contained Units In General (AREA)

Abstract

A turbofan (10) is equipped with a main plate (2) having a boss (2a) which is a fixation section at which the rotating shaft of a motor is fixed, blades (4), and a side plate (3) for forming an air sucking and leading wall. That portion of a rear edge (4e) of a blade (4) which is located on the main blade (2) side bends to form a projection facing the rotational direction of the blades (4), that portion of the rear edge (4e) which is located on the side plate (3) side bends to form a recess facing the direction opposite to the rotational direction, and thus the rear edge (4e) has at least the two bend points, or the projection and the recess. The section between the main plate side bend section and the side plate side bend section is formed such that that portion of the section which is on the main plate (2) side tilts in the rotational direction relative to that portion of the section which is on the side plate (3) side.

Description

DESCRIPTION TURBOFAN AND AIR CONDITIONING APPARATUS Technical Field [0001] The present invention relates to a turbofan and an air conditioning apparatus, and more particularly, to a turbofan for use in an air conditioning apparatus for air cleaning, humidifying, dehumidifying, cooling, or heating purposes and to an air conditioning apparatus provided with the same. Background Art [0002] (A) A turbofan having a fan blade formed in a three dimensional shape is widely used for a blower fan to be mounted on a conventional ceiling-embedded type air conditioning apparatus. For example, there is disclosed a turbofan having a blade inlet diameter gradually increasing toward a side plate side from a main plate side, having an inlet diameter at a blade side plate inside end being greater than an inlet diameter of a side plate and having a blade upper end slanted in a rotational direction of an impeller, and a turbofan in which an inclination angle between the impeller rotational axis and the blade upper end is set at a greater angle at a position closer to the impeller outer 1 circumference than to the impeller inner circumference, while the inclination angle is set at a smaller angle in the vicinity of the side plate, in a cross-sectional view as taken in the shape of a cylinder concentric with the impeller axis (see Patent Document 1, for example). [0003] The turbofan according to this arrangement prevents an air flow from a blade upper end from separating on a blade negative-pressure surface as well as prevents degradation in air blowing performance and an increase in noise level due to turbulent flow. [0004] (B) Also, as another conventional example, there is disclosed a turbofan in which the position of a side plate side jointed portion of a blade trailing edge is offset from a main plate side joined portion in an opposite impeller rotational direction by a predetermined distance, and at the same time the position of a side plate side jointed portion of a blade leading edge is offset from the main plate side joined portion in an impeller rotational direction by a predetermined distance (see Patent Document 2, for example). [0005] The turbofan according to this arrangement allows a blade pressure surface to be tilted toward the side plate side at the blade trailing edge, which causes a force 2 exerted by the pressure surface on the air to lean against the side plate, preventing air flow separation on the outlet side of the side plate. In addition, it elongates a blade chord length on the blade side plate side having a greater flow speed at the blade leading edge, which causes the air flow entering to the blade leading edge near the main plate to head on the side plate side and prevents separated flow from occurring on the side of the outlet of the blade side plate, thereby homogenizing wind speed distribution on the front face side of the heat exchanger disposed downstream of the impeller in the entire vertical region. [0006] (C) Furthermore, there are disclosed a turbofan having a joined end with the side plate shifted in the rotational direction in relation to a joined end with the main plate in a region from the leading edge to the trailing edge, and having the side plate end on the blade leading edge side slanted toward the rotational direction, a turbofan having the side plate end on the blade leading edge side slanted radially inward in the rotational direction with a greater inclination angle (inlet angle a) on the center side than on the main and side plate sides or a smaller inclination angle at on the side plate side than on the main plate side, and a turbofan having the side plate end at the blade trailing edge slanted radially outward in the opposite rotational 3 direction with a greater inclination angle (outlet angle ) on the center side than on the main and side plate sides (see Patent Document 3, for example). [0007] The turbofans according to these arrangements cause the side plate side end of the blade leading edge having a particularly greater velocity component in the axial direction of inlet air to be slanted in the rotational direction so as to follow the air inlet direction, thereby securely preventing a separation forming readily in the opposite blade rotational direction and consequently providing improved performance and reduced noise levels. Also, a greater leading edge side inclination angle a at the center allows air to be very smoothly taken in from the inner circumferential side. Furthermore, if an inclination angle a on the side plate side is smaller than that on the main plate side, air can be smoothly taken in since the blade is shaped to follow the inlet angle. At the blade trailing edge, a greater inclination angle (outlet angle ) on the center side than on the main and side plate sides allows homogenization of air blown on the outer circumferential side. [0008] [Patent Document 1) Japanese Unexamined Patent Application Publication No. 10-30590 (page 4, Fig. 8) 4 [Patent Document 2] Japanese Patent No. 2701604 (page 4, Fig. 3) [Patent Document 3] Japanese Patent No. 3861008 (page 7, Fig. 4) Disclosure of Invention Problems to be solved by the Invention [0009] However, a turbofan and an air conditioning apparatus disclosed in Patent Documents 1 to 3 have the following problems. (A) A turbofan disclosed in Patent Document 1 has a difficulty in assembly. That is, at least in the case of a turbofan in which an impeller is integrally formed after molding a blade and a side plate separately and joining them into one unit by welding or fitting, if a blade upper end is slanted in the impeller rotational direction, such a slanted upper end causes a stress to be exerted on the main plate joined portion, so as to prevent a force from being properly applied to the side plate, because the side plate and the blade are joined by pressing the side plate on the blade in the direction of the rotational axis. [0010] (B) In a case of forming of a thermoplastic resin, there is a problem of an increase in weight due to increasing amount of materials and poor workability. That 5 is, forming of a thermoplastic resin may cause a surface sink, leading to poor workability. Since a thickness of a blade with poor workability is substantially equal along the impeller height direction from the main plate to the side plate, in a case of wing type blade in which the thickness of the blade gradually increases from the impeller inner circumference in a plan view perpendicular to the rotational axis and further decreases toward the impeller outer circumference, in the vicinity of the center of the blade having a larger thickness, for example, the thickness increases at the slanted blade upper edge in a side view resulting in increased amount of materials used, resultant increased weight, and occurrence of a surface sink. (C) In addition, an inclination angle at the blade upper edge is increased at lease toward the impeller outer circumference from the inner circumference so that the amount of inflow air at the blade side plate joined portion increases and as a result interferes with air flow from the blade impeller inner circumference of the blade, causing noise or vibration which degrades ambient surroundings (hereinafter called "degraded noise problem"). [0011] (D) In a turbofan disclosed in Patent Document 2, the side plate side joined portion of the blade trailing edge is offset by a predetermined amount in the opposite rotational 6 direction from the main plate side joined portion, which improves the homogenization of wind speed distribution on the front face side of the heat exchanger disposed downstream of the impeller, but causes air flow to concentrate on the side plate side at the blade trailing edge in the impeller outlet, leading to a degraded noise problem. (E) Offsetting the side plate side joined portion of the blade leading edge by a predetermined amount in the rotational direction from the main plate side joined portion prevents a separation around the side plate side joined portion, but a separation in a region from the intermediate portion of the blade leading edge to the blade side, plate side joined portion still remains unchanged, so that there is room for noise reduction. [0012] (F) Furthermore, the blade side plate side joined portion is slanted in the rational direction in relation to the main plate side joined portion, and the surface of the main plate and the blade pressure surface (surface of the opposite rotational direction) make a sharp angle of less than 90 degrees. This causes an inlet air flow from the leading edge to drift into the main plate side, leaving a separation region in the blade trailing edge at the side plate side. 7 (G) In addition, offsetting the blade side plate side joined portion on the sides of the leading and trailing edges in the reverse direction causes a region from the blade side plate side joined portion joined to the side plate to the main plate side joined portion to be slanted relative to the side plate, which leads to a difficulty in assembly, like a turbofan disclosed in Patent Document 1. [0013] (H) Meanwhile, in a turbofan disclosed in Patent Document 3, the side plate side joined portion is shifted over a portion from the blade leading edge to the trailing edge in the rotational direction in relation to the main plate side joined portion, and the side plate side end on the leading edge side is slanted in the rotational direction, which prevents separation of an inlet air flow at the side plate side end and the side plate side joined portion, but causes an inlet air flow from the leading edge to drift on the main plate side, leaving a separation region in the blade trailing edge on the side plate side. (I) In the case of a turbofan formed by at least molding a blade and a side plate separately and joining them by welding or engagement into one unit, since the entire blade is slanted in the rotational direction, the blade and the side plate are joined with pressing the blade in the direction of the rotational axis , which causes a stress to 8 be exerted on the main plate side joined portion and prevents a force from being properly applied to the blade on the side plate side, leading to a difficulty in assembly. [0014] It is desirable to solve or ameliorate the above described problems. It is desirable to provide a turbofan and an air conditioning apparatus provided with the same, which provides low-noise emission, ease to assemble, and good workability by suppressing a separation region at a blade leading edge, a side plate side end, and a trailing edge, while minimizing performance degradation even if air flow resistance is added. Alternatively, it is desirable to provide the public with a useful alternative to existing arrangements. [0014A] As used herein, except where the context requires otherwise the term "comprise" and variations of the term, such as "comprising", "comprises" and "comprised", are not intended to exclude other components, integers or steps. [0014B) Reference to any prior art in the specification is not, and should not be taken as, an acknowledgment or any form of suggestion that this prior art forms part of the common general knowledge in Australia or that this prior art could reasonably be expected to be ascertained, understood and 9 regarded as relevant by a person skilled in the art. Summary of the Invention [00151 In accordance with an aspect of the present invention, there is provided a turbofan comprising: a disc-shaped main plate having a boss that is a fixed portion to which a rotational shaft of a motor is secured; an annular side plate having a side plate opening formed at the center thereof and forming a wind guide wall together with the main plate; and a plurality of blades mounted across the main plate and the side plate; in a plan view seeing a face perpendicular to the rotational shaft from the side plate opening, each blade being positioned farther away from the rotational shaft, when coming from a blade leading edge to a blade trailing edge; with the blade leading edge, a front edge side side-plate edge and a front edge inner periphery side edge are continuously formed with a blade leading edge end being a bending point; an outer circumferential surface and an inner circumferential surface of the blade having a central region in the height direction substantially parallel to the rotational shaft at the blade leading edge, a region close to the main plate of the outer circumferential surface curves radially outward of the main plate as the region approaches the main plate in the blade leading edge, and a region close to the side plate of the front edge side side-plate edge and the front edge inner periphery side edge of the blade curves radially outward of the side plate as the region approaches the side plate, thereby, the 10 curved region of the blade outer circumferential surface forms a substantial triangle shape with the blade leading edge end being an apex. (2) An air conditioning apparatus according to another aspect of the present invention includes the turbofan, and a ventilating pressure loss unit at least either at an inlet opening of the turbofan or at an air outlet opening thereof. Advantages [0016] (i) With this arrangement, a turbofan according to the present invention provides a homogeneous wind speed distribution at the fan outlet opening. As a result, if a heat exchanger is provided downstream of the turbofan, air vertically uniformly flows in at least in the vicinity of the fan outlet opening, thereby suppressing an air flow that flows on the surface without passing through the heat exchanger due to a wind speed difference as well as reducing a pressure loss, resulting in a reduction in operating noise level. (ii) Also, an air conditioning apparatus according to 10A the present invention suppresses air separation at a blade leading edge of the turbofan and provides low-noise operation, even if a ventilating pressure loss unit such as a filter is provided at a turbofan inlet opening. Brief Description of Drawings [0017] [Fig. 1] Fig. 1 is a longitudinal sectional view showing an air conditioning apparatus according to Embodiment 1 of the present invention. [Fig. 2] Fig. 2 is a perspective view showing a turbofan according to Embodiment 2 of the present invention. [Fig. 3] Fig. 3 is a plan view, partly in cross section, of a turbofan shown in Fig. 2, as viewed from a fan inlet opening side. [Fig. 4] Fig. 4 is a side view showing a section taken along the line X-X of Fig. 3. [Fig. 5] Fig. 5 is a side view showing a blade of a turbofan shown in Fig. 2. [Fig. 6] Fig. 6 is a sectional view showing a section taken along the line Ll-L1 of Fig. 5. [Fig. 7] Fig. 7 is a sectional view showing a section taken along the line L2-L2 of Fig. 5. [Fig. 81 Fig. 8 is a sectional view showing a section taken along the line L3-L3 of Fig. 5. [Fig. 9] Fig. 9 is a sectional view showing a section 11 taken along the line L4-L4 of Fig. 5. [Fig. 10] Fig. 10 is a plan view showing a section taken along the line L5-L5 of Fig. 5. [Fig. 11] Fig. 11 is a longitudinal sectional view showing a section taken along the line K1-K1 of Fig. 3. [Fig. 12] Fig. 12 is a longitudinal sectional view showing a section taken along the line K2-K2 of Fig. 3. [Fig. 13] Fig. 13 is a diagram showing relationship between a blade trailing edge inclination angle a and a noise level associated with the same air volume. [Fig. 14] Fig. 14 is a diagram showing relationship between a circumferential curvature angle y and a noise level associated with the same air volume. [Fig. 15] Fig. 15 is a diagram showing relationship between an outlet angular difference A02 and a noise level associated with the same air volume. [Fig. 16] Fig. 16 is a diagram showing relationship between a curvature angle 6 and a noise level associated with the same air volume. [Fig. 17] Fig. 17 is a diagram showing relationship between an inlet angular difference AP1 and a noise level associated with the same air volume. [Fig. 18] Fig. 18 is a perspective view showing a turbofan according to Embodiment 3 of the present invention. [Fig. 19] Fig. 19 is a longitudinal sectional view of a 12 blade of a turbofan shown in Fig. 18. Reference Numerals [0018] 1 turbofan (Embodiment 2) la fan inlet opening lb fan outlet opening 2 main plate 2a boss 2b blade opening section 3 side plate 4 blade 4a blade leading edge 4al blade leading edge side plate end 4a2 blade leading edge inner circumferential end 4a3 blade leading edge end 4acl intersection of blade leading edge 4e and horizontal camber line Cl 4ac2 intersection of blade leading edge 4e and horizontal camber line C21 4ac3 intersection of blade leading edge 4e and horizontal camber line C31 4ac4 intersection of blade leading edge 4e and horizontal camber line C4 4b blade outer circumferential surface 4bl side plate induction portion 13 4c blade inner circumferential surface 4d blade main plate end 4e blade trailing edge 4ecl intersection of blade trailing edge 4e and horizontal camber line Cl 4ec2 intersection of blade trailing edge 4e and horizontal camber line C2 4ec3 intersection of blade trailing edge 4e and horizontal camber line C3 4ec4 intersection of blade trailing edge 4e and horizontal camber line C4 4g blade side plate joined portion 4gl end in a rotational direction on at the blade outer circumferential surface of blade side plate joined portion 5 concave groove 5a concave groove bottom 10 air conditioning apparatus body (Embodiment 1) 10a body top plate 10b body side plate 10c body inlet opening 10d body outlet opening 11 decorative panel lla inlet grill llb panel outlet opening 12 filter 14 13 wind direction vane 14 bell mouth 15 fan motor 16 heat exchanger 17 room 30 turbofan (Embodiment 2) A rotational direction B curvature reference line Cl horizontal camber line C2 vertical camber line D chord El tangent to the horizontal camber line Cl at the intersection of the horizontal camber line Cl and the blade leading edge inner circumferential end 4a2 E2 tangent to the horizontal camber line Cl at the intersection of the horizontal camber line Cl and the blade trailing edge 4e Fl tangent to a circle passing through the intersection of the horizontal camber line Cl and the blade leading edge inner circumferential end 4a2 F2 tangent to a circle passing through the intersection of the horizontal camber line Cl and the blade trailing edge 4e G straight line connecting the main plate side joined point 4ecl and the side plate side joined point 4ec4 15 J inlet air flow T blade planar thickness t blade thickness 0 rotational axis Best Modes for Carrying Out the Invention [0019] [Embodiment 1: air conditioning apparatus] Fig. 1 is a longitudinal sectional view showing an air conditioning apparatus according to Embodiment 1 of the present invention. An air conditioning apparatus according to Embodiment 1 of the present invention is equipped with a turbofan according to Embodiment 2 to be described later, and is described below with reference to accompanying drawings. In Fig. 1, a ceiling-embedded type air conditioning apparatus body (hereinafter referred to as "air conditioning apparatus body") 10 is mounted on a ceiling 21 of a room 20 in such a manner that it is embedded in a rectangular-shaped hole formed in the ceiling 21. In other words, the air conditioning apparatus body is a box having an opening formed at the bottom thereof and having a top plate 10a and a side plate 10b opposed to the top plate 10a. The side plate 10b has a side plate opening (communicating with a body inlet opening 10c) formed at the center thereof and has a bottom edge substantially flush with the ceiling 21, so an 16 opening of the air conditioning apparatus body is also substantially flush with the ceiling 21. [0020] In addition, decorative panel 11 shaped substantially in a rectangle in a plan view is installed on the side plate 10b or the ceiling 20 while facing the room 20 so as to cover the lower end of the side plate 10b and the rectangular-shaped hole of the ceiling 21. The decorative panel 11 includes an inlet grill 1la, which is an inlet opening of air for the air conditioning apparatus body 10, provided at the center thereof, a filter 12 for removing dust from the air having passed through the inlet grill lla, a panel outlet opening llb formed along each side of the decorative panel 11. Each panel outlet opening lb is provided with a wind direction vane 13. [0021] Furthermore, inside the air conditioning apparatus body 10 a turbofan 1, a bell mouth 14 that forms an inlet air passage for the turbofan, a fan motor 15 for turning and driving the turbofan 1, and a heat exchanger 16 for performing heat exchange of room air drawn into the apparatus body (hereinafter referred to as "drawn air") are disposed respectively. The heat exchanger 16 is formed to have a substantial C-shaped form in the plan view , installed uprightly so as to surround the periphery of the 17 turbofan 1, and connected to an outdoor unit (not illustrated) through connecting piping. The air conditioning apparatus body 10 includes a body inlet opening 10c formed at the center thereof, and a body outlet opening 10d is formed around the body inlet opening 10c. The body inlet opening 10c communicates with the inlet grill lla of the facing panel 11, while the body outlet opening 10d communicates with the panel outlet opening llb of the decorative panel 11. [0022] In the air conditioning apparatus 10 according to this arrangement, when the turbofan 1 rotates, the air in the room 20 is drawn into the turbofan 1 after passing through the inlet grill 11a of the decorative panel 11, the filter 12 removing dust, the body inlet opening 10c, and the bell mouth 14. Then, the air blows off into the heat exchanger 16 where the air is subjected to heat exchanging including heating or cooling and dehumidifying, and is blown out from the panel outlet opening llb toward the room 20 through the body outlet opening 10d while subjected to wind direction control by the wind direction vane 13. Whereby, the air in the room 20 is air-conditioned (hereinafter referred to as "air conditioning"). [0023] [Embodiment 2: turbofan] 18 Figs. 2 through 17 are views showing a turbofan according to Embodiment 2 of the present invention. Fig. 2 is a perspective view. Fig. 3 is a plan view, partly in cross section, of a turbofan, as viewed from a fan inlet opening side. Fig. 4 a side view showing a section taken along the line X-X of Fig. 3. Fig. 5 is a partial side view. Figs. 6 through 9 are partial planar sectional views. Fig. 10 is a partial plan view. Figs. 11 and 12 are partial sectional views. Figs. 13 through 17 are diagrams showing the relationship between a noise level and an angle of each section. Fig. 2 corresponds to a perspective view of Fig. 1, as seen when looking up at the ceiling 21. Fig. 4 and Fig. 1 (Embodiment 1) are upside-down views, where air is drawn from the upper side in Fig. 4 and blown off toward the right and left directions in Fig. 4. A top to bottom direction in Fig. 4 is called "height direction", while a left to right direction and a face-to-back direction is called "horizontal direction" for convenience sake. In Fig. 1 and the other figures, the same reference numbers and symbols refer to the same components, and descriptions of the components are partially omitted. [0024] Fig. 13 is a diagram showing relationship between a blade trailing edge inclination angle a and a noise level 19 associated with the same air volume. Fig. 14 is a diagram showing relationship between a circumferential curvature angle y and a noise level associated with the same air volume. Fig. 15 is a diagram showing relationship between an outlet angular difference A32 and a noise level associated with the same air volume. Fig. 16 is a diagram showing relationship between a curvature angle s at a blade leading edge end 4a3 and a noise level associated with the same air volume in relation to the ratio of an air flow resistance without dust accumulation on a filter disposed at an inlet side to that with dust accumulation. Fig. 17 is a diagram showing relationship between an inlet angular difference AP1 and a noise level associated with the same air volume, the inlet angular difference being an angular difference between an inlet angle the blade leading edge end and an inlet angle at a blade leading edge inner circumferential side end at a height of a concave-shaped bottom where a vertical camber line C12 becomes most along the opposite rotational direction in a blade outer circumferential surface. [0025] In Figs. 2 through 5, the turbofan 1 is integrally formed of a main plate 2 of a body of revolution (disk) having a substantially angular-shaped section, a side plate 3 of a circular ring having a substantially circular arc 20 section disposed so as to be opposed to the periphery of the main plate 2, and a plurality of blades 4 disposed so as to extended from the main plate 2 to the side plate 3. The main plate 2 includes a boss 2a formed at the center (convex portion having a substantially angular shaped section) thereof, the boss 2a being a fixing part to which a rotational shaft 0 of the fan motor 15 is secured. Accordingly, a rotational axis is parallel to the height direction and perpendicular to the horizontal direction. [0026] In the side plate 3 in the form of a circular ring, a side plate opening formed at the center thereof forms a fun inlet opening la. The peripheral portion (skirt having a substantially angular shaped section) of the main plate 2 and the side plate 3 form wind guide walls, and a space defined by these components forms a fan outlet opening lb. In other words, in Fig. 1, since the section of the peripheral edge of the main plate 2 and the section of the side plate 3 are rising toward the outer circumference, air flow is formed which rises (indicated by a downward arrow since the upside is down in Figs. 2 through 12) and then horizontally moves toward the outer circumference. [0027] (Blade Layout) In a plan view of the blade 4, the blade 4 is located 21 farther away from the rotational axis 0 as it comes nearer to the blade trailing edge from the blade leading edge 4a. The blade is connected at its end edge of the blade 4 close to the side plate 3 to the side plate in a region (4ec4-4gl) close to the blade trailing edge 4e, and is located at the side plate opening away from the side plate 3 in a region (4gl-4a3) close to the blade leading edge 4a. The blade 4 has a hollow structure having a cavity therein and an opening formed outside of the impeller of the main plate 2 in such a manner that a wall thickness T (equal to the distance between the blade outer circumferential surface and the blade inner circumferential surface) in a horizontal section perpendicular to the rotational axis 0 of the blade 4 decreases from a position close to the main plate 2 toward a position close to the side plate 3. [0028] (Blade Trailing Edge) The blade trailing edge 4e of the blade 4 is located on a hypothetical cylinder defined by connecting the circumferential edges of the main plate 2 and the side plate 3, and has a wavy form having at least two inflection points on such a hypothetical cylinder. Namely, an intersection of a horizontal camber line Cl and the blade trailing edge 4e depicts, in relation to an intersection 4ecl as a main plate side joined point in the height direction, an intersection 22 4ec2 which is a main plate side inflection point having a curvature toward a rotational direction in a convex form at a predetermined position on the side of the main plate 2 closer to the center of the fan outlet opening lb, an intersection 4ec3 which is a side plate side inflection point having a curvature toward the reverse rotational direction in a concave form on the side of the side plate 3 closer to the center of the fan outlet opening lb, and an intersection 4ec4 which is a side plate side joined point of the side plate 3. In other words, a line G connecting between the main plate side joined portion 4ecl and the side plate side joined portion 4ec4 is upright in the vicinity of the main plate 2 and the side plate 3 so as to be parallel to the rotational axis 0, while the blade trailing edge on the side of the main plate 2 is inclined to the rotational direction A in relation to that on the side of the side plate 3 between the main plate side inflection point 4ec2 and the side plate side inflection point 4ec3 so that the blade trailing edge 4e has a substantial S shape. [0029] At this time, the blade trailing edge 4e is located on a hypothetical cylinder defined by connecting the outer circumferential edges of the main plate 2 and the side plate 3, and a line G connecting a main plate side jointed point 4ecl and a side plate side joined point 4ec4 is orthogonal 23 (orthogonal as a normal line) to the outer circumferential surface of the main plate 2 so as to be parallel to the rotational axis 0. Also, the blade trailing edge 4e is parallel to the normal line of the side plate 3 in the vicinity of the side plate 3. Furthermore, between main plate side curvature point 4ec2, which is a location in a main plate side curved portion most projected to the rotational direction A, and the side plate side curvature point 4ec3, which is a location in a side plate side curved portion most projected to the opposite direction of the rotational direction A, the blade trailing edge 4e projects more to the rotational direction A as it is closer to the main plate 2, so as to be inclined in a side view. As a result, the blade trailing edge 4e has a substantial S shape. [0030] Accordingly, on the blade outer circumferential surface 4b, drawn air is divided by the main plate side curvature point 4ec2 into the sides of the main plate 2 and the central part in the height direction of the outlet opening lb, thereby preventing air flow from concentrating on the side of the main plate 2. An inclined section 4e5 between the main plate side curvature point 4ec2 and the side plate side curvature point 4ec3 exerts a force in the direction of the side plate 3, guiding the air flow. In addition, a 24 portion between the side plate side curvature point 4ec3 and the side plate side joined point 4ec4 guides, on the blade inner circumferential surface 4c thereof, air flow coming from a portion around the side plate side joined portion 4g at the leading edge side plate side end 4al of the blade 4 to the side of the side plate 3 in the fan outlet opening lb. [0031] (Cross-sectional Shape of Blade) The horizontal cross-sectional shape of the blade 4 will be described. Figs. 6 through 10 are sectional views taken along the line L1-Ll, the line L2-L2, the line L3-L3, the line L4-L4, and the line L5-L5 of Fig. 4, respectively. The rotational direction is indicated by "Arrow A". In other words, Fig. 6 is a sectional-view taken along the line Ll-Ll at the main plate side end 4d joined to the main plate 2. Fig. 7 is a cross-sectional view taken along the line L2-L2 located on the side of the main plate 2 from the center of the fan outlet opening lb. Fig. 8 is a cross sectional view taken along the line L3-L3 located on the side of the side plate 3 from the center of the fan outlet opening lb. Fig. 9 is a cross-sectional view taken along the line L4-L4 going through the side plate 3 in the fan outlet opening lb. Fig. 10 is a cross-sectional view taken along the line L5-L5 when removing the side plate 3 corresponding to one blade 4. 25 [0032] In the Li-Li section (Fig. 6), a wall thickness center line (equal to the center between the blade inner and outer circumferential surfaces) in the section is indicated by "horizontal camber line Cl", and "the intersection of the horizontal camber line C1 and the blade leading edge 4a" and "the intersection of the horizontal camber line Ci and the blade trailing edge 4e" are indicated by "4acl" and "4ecl", respectively. Also, in the L2-L2 section (Fig. 7), a wall thickness center line in the section is indicated by "horizontal camber line C2", and "the intersection of the horizontal camber line C2 and the blade leading edge 4a" and "the intersection of the horizontal camber line C2 and the blade trailing edge 4e" are indicated by "4ac2" and "4ec2", respectively. Likewise, in the L3-L3 section (Fig. 8), "horizontal camber line C3" is indicated by "4ac3" and "4ec3". Also, in the L4-L4 section (Fig. 9), "horizontal camber line C3" is indicated by "4ac4" and "4ec4". Reference numerals "4acl" and "4ecl" are added to each figure to make clear a phase in the height direction. [0033] In Figs. 6 through 9, the blade 4 is an wing type blade which is gradually thickening toward the center of the blade 26 from the blade inner circumference side leading edge 4a2, and is gradually thinning toward the blade trailing edge 4e. In an Li-Li section shown in Fig. 6, the blade 4 is slanted backward against the rotational direction A and radially outwardly curved. In a section L2-L2 shown in Fig. 7, the side of the main plate 2 of the blade trailing edge 4e is curved in a warped backward shape in the rotational direction A. In addition, in an L3-L3 section shown in Fig. 8, the blade trailing edge 4e is curved in a warped shape in the direction opposite to the rotational direction A against the main plate side joined part 4ecl. [00341 IN the L4-L4 section shown in Fig. 9, the side plate side jointed point 4ec4 and the main plate side joined point 4ecl in the L1-L1 section shown in Fig. 6 have the same phase in a plan view as seen from the fan inlet opening la, and the leading edge inner circumference side end radially outwardly curves. In addition, in a plan view shown in Fig. 10, the main plate side curvature point 4ec2 and the side plate side curvature point 4ec3 are disposed so as to make a predetermined angle y across the main plate side joined point 4ecl and the side plate side joined point 4ec4. [0035] In Fig. 6 (L1-L1 section), the angle (acute angle) 27 between a tangent line El to the horizontal camber line Cl at the intersection 4ecl of the horizontal camber line Cl and the blade trailing edge 4e, and a tangent line Fl to a circle concentric with the rotational axis 0 and passing through the intersection 4ecl is referred to as "outlet angle 021". In Fig. 7 (L2-L21 section), the angle (acute angle) between a tangent line E2 to the horizontal camber line C2 at the intersection 4ec2 of the horizontal camber line C2 and the blade trailing edge 4e, and a tangent line F2 to a circle concentric with the rotational axis 0 and passing through the intersection 4ec2 is referred to as "outlet angle $22". Likewise, "outlet angle P23" and "outlet angle $24" are defined in Fig. 8 (L3-L3 section) and Fig. 9 (L4-L4 section), respectively. The blade 4 is formed such that these outlet angles have the relationship of "P23 < 121 = 024 < 22". [0036] (Blade Leading Edge) In Figs. 2 and 3, the blade leading edge 4a on the blade 4 at the air inlet side has a shape defined by the side plate side end 4al and the inner circumferential side end 4a2 continuously formed with the leading-edge end 4a3 as a bending point. The side plate side end 4al is tilted toward the fan inlet opening la as it approaches "side plate 28 joined portion 4g (see Fig. 4) where the blade 4 and the side plate 3 are joined" from the leading-edge end 4a3. In other words, the side plate side end 4al approaches the side plate 3 being inclined so as to approach the normal line of the side plate 4. [0037] In Fig. 3, the intersection of the horizontal camber line Cl and the blade leading edge inner circumferential side end 4a2 is called "intersection 4acl", the intersection of the horizontal camber line C1 and the blade trailing edge end 4e is called "intersection 4ecl", and a line connecting the intersection 4acl and the intersection 4ecl is called "chord line D". A longitudinal section perpendicular to the chord line D in the vicinity of the blade leading edge inner circumferential end 4a2 is called "K1-Kl section", and the blade 4 in the Kl-Kl section is shown in Fig. 11. A longitudinal section perpendicular to the chord line D at the end in a rotational direction 4gl of the side plate joined portion (equal to the boundary between a joined region and a region located at the side plate opening) is called "K2-K2 section", and the blade 4 in the K2-K2 section is shown in Fig. 12. In Figs. 11 and 12, vertical thickness center lines (equal to the center line between the blade inner 29 circumferential surface and the blade outer circumferential surface) in the Kl-K1 section and the K2-K2 section are called "vertical camber lines C12", while angles between the vertical camber line C12 and the rotational axis 0 at the blade leading edge end 4a3 (Kl-K1 section) and at the blade side plate joined portion 4gl (K2-K2 section) are called "curvature angle 61" and curvature angle c2", respectively. [0038] In Figs. 2, 11, and 12, a region apart from the side plate 3, in an end edge of the blade close to the side plate 3 (equal to the region located at the side plate opening), curves so as to be located more radially outward at a position closer to the blade leading edge 4a in a plan view, and expands so as to be farther away from the end edge at the curved region closer to the blade leading edge 4a in a side view. In other words, the blade leading edge side plate side end 4al and the leading edge inner circumferential side end 4a2 on the side of the side plate 3 curves radially outward so that the curvature angle 6 becomes larger at a position closer to the impeller inner circumference (equal to a position closer to the blade leading edge 4a) with the end in the rotational direction 4gl on the blade outer circumferential surface of the side plate joined portion 4g being as a supporting point and the blade leading edge end 30 4a3 being as a power point. [0039] Consequently, the curved region is formed to have a substantial triangle shape in a side view, causing an oblique "folding line B" to be created on the outer circumferential surface 4b of the blade 4 so as to extend toward the blade leading edge inner circumferential side end 4a2 of the blade leading edge from the end in the rotational direction 4gl to the main plate 2. In addition, as shown in Figs. 4 and 11, the blade thickness T is made gradually larger so that the blade outer circumferential surface 4b of the blade leading edge 4a on the side of the main plate 2 curves radially outward, and at the same time the vertical camber line C12 curves radially outward. [0040] In the K2-K2 section shown in Fig. 12, the blade outer circumferential surface 4b is substantially perpendicular to the outer circumferential surface of the main plate 2. Only the blade inner circumferential surface 4c on the side of the side plate 3 curves radially outward, and the blade 4 stands substantially upright with its thickness becoming smaller toward the side plate 3 from the main plate 2(with increasing height), as a whole . For inlet angles 011, P12, P13, and P14 shown in cross 31 sectional views of Figs. 6 through 10, an inlet angle 1 gradually becomes larger in a region from the blade leading edge end 4a3 to the side plate 3 to cause the inlet angle 114 at the blade leading edge end 4a3 to be the smallest, so that 14 is smaller than pll, and $12 and 113 of middle portions in the height direction are greater than at least 311 and P14, respectively (112>311, 113>114). As described above, in a side view as seen from the inner circumference, the blade leading edge 4a is at least so formed that the blade outer circumferential surface 4b on the sides of the blade side plate 4al and the main plate 2 is formed to have a convex shape in relation to the rotational direction A, while the blade inner circumferential surface 4c is formed so as to curve radially outward. (0041] (Effects and Advantages) As shown in Fig. 2, when being rotated by the fan motor 15 in the rotational direction A, the turbofan 1 having the above structure substantially radially blows out the room air (drawn air), which has been drawn through the fan inlet opening la and passed through the blade 4, through the fan outlet opening lb, providing the following effects and advantages. [0042] 32 (i) A homogeneous wind speed distribution is provided at the fan outlet opening lb. As a result, if the heat exchanger 16 is provided downstream of the turbofan 1, the air flows uniformly into the heat exchanger, at least in the vicinity of the fan outlet opening lb, thereby suppressing a secondary air flow that flows on the surface without passing through the heat exchanger 16 due to a wind speed difference as well as reducing a pressure loss, resulting in a reduction in operating noise level (see Fig. 1). Also, the blade trailing edge 4e stands upright in the vicinity of the main plate 2 and the side plate 3, which allows a force parallel to the rotational axis 0 to be precisely applied at the time of welding work during assembly, as compared with conventional turbofans where the trailing edge 4e is inclined in relation to the main plate 2 and the side plate 3, thereby preventing defective welding caused by the back clearance of the blade 4. [0043] (ii) "Trailing edge inclination angle a2" or an inclination angle between an inclined section 4e5, which is located between the main plate side curvature point 4ec2 and the side plate side curvature point 4ec3, and a line G parallel to the rotational axis 0 is set at 10 to 30 degrees. This prevents a flow from concentrating on the blade outer circumferential surface 4b on the side of the side plate 3 33 in the fan outlet opening lb. Also, this prevents a flow coming from the leading edge side plate side end 4al from concentrating on the blade inner circumferential surface 4c on the side of the side plate 3, thereby reducing a noise level as shown in the relationship between the trailing edge inclination angle a and the noise level associated with the same wind volume (see Fig. 13). [0044) (iii) In Fig. 10, a circumferential curvature angle y between a line connecting the impeller rotational axis with the main plate side curvature point 4ec2 and a line connecting the rotational axis with the side plate side curvature point 4ec3 is set at 5 to 15 degrees. When the heat exchanger 16 is disposed downstream of the fan outlet opening lb, this arrangement allows the air flow to be dispersed even at the time when the blade trailing edge 4e becomes close to the heat exchanger 16 due to running turbofan 1 and an air flow resistance increases locally. Like the effects of the trailing edge inclination angle a, this arrangement also prevents a flow from concentrating on the side of the side plate 3 of the blade outer circumferential surface 4b in the fan outlet opening lb, as well as prevents a flow coming from the leading edge side plate side 4al from concentrating on the side of the side plate 3 of the blade inner circumferential surface 4c, 34 thereby reducing a noise level as shown in the relationship between the circumferential curvature angle y and the noise level associated with the same wind volume (see Fig. 14). [0045] (iv) In each cross sectional view of the blade in a plane perpendicular to the rotational axis, "angular difference Ap2" that is a difference between the outlet angle P22 at the main plate side curvature point 4ec2 and the outlet angle p23 at the side plate side curvature point 4ec3 is set at 20 to 35 degrees. Accordingly, in the air conditioning apparatus 10, the blade trailing edge is formed to have a substantial S shape with concave and convex curvature, so that even if a distance between the heat exchanger 16 (ventilating pressure-loss body having a substantial C shape in a plan view) disposed on the fan outlet side and the fan outlet opening lb changes in the circumferential direction, the blade trailing edge 4e regulates an air flow due to the substantial S-shape. Consequently, the present invention provides a small change in wind speed distribution, thereby reducing a noise level, unlike conventional apparatuses in which an air flow concentrates on the fan outlet opening lb on the side of the main plate 2, in a region where the fan 1 is close to the heat exchanger 16, which causes a greater separation on the side of the side plate 3 and a significant increase in noise 35 level (see Fig. 15 showing the relationship between an outlet angular difference AP2 and a noise level associated with the same air volume). [0046] (v) On the blade leading edge 4a, drawn air is smoothly introduced without hitting the outer circumferential surface 4b and producing a turbulent flow at the blade leading edge inner circumferential side end 4a2 on the side of the side plate 2 and at the side plate side induction portion 4bl (leading edge side plate side end 4al curves radially outward) on the blade outer circumferential surface 4b, since, in a side view as seen from the center (rotational axis 0), the outer circumferential surface 4b on the side of the side plate 3 and the main plate 2 curves to have a concave shape in relation to the rotational direction A. This arrangement increases a blowing air volume at the same fan rotating speed, leading to a lower fan rotating speed than that for attaining the blowing air volume required for heat exchange of the air conditioning apparatus 10, which results in reduced operating noise levels as well as reduced motor power consumption due to performing a rotational drive of the fan with a reduced driving torque. [0047] (vi) The blade outer circumferential surface 4b of the blade leading edge 4a on the side of the main plate 2 is 36 formed to curve radially outward, which allows an air flow passing through the surface of the main plate 2 from the boss 2a to be directed toward the center of the blade height, preventing the air flow from concentrating on the side of the main plate 2, together with an air flow from the blade leading edge inner circumferential side end 4a2. Also, the air flow can be smoothly introduced to the blade outer circumferential surface 4b without hitting the blade 4, thereby preventing turbulence. Consequently, a homogeneous blown off wind speed distribution as well as reduced noise levels can be achieved by preventing a separation on the side plate side and a concentration on the main plate side, while conventional apparatuses suffer from the concentration of wind speed distribution on the main plate side in the fan outlet opening. [0048] (vii) The blade inner circumferential surface 4c of the blade leading edge 4a on the side of the side plate 3 is formed to be slanted radially outward and curved, which allows drawn air on the inner circumferential surface 4c to smoothly flow along the slanted, curved surface toward the blade trailing edge 4e. This prevents the air flow separation occurring near the side plate 3 that is encountered in conventional turbofans, thereby reducing 37 noise levels. [0049] (viii) With the end in the rotational direction 4gl on the blade circumferential surface 4b at the side plate joined portion 4g being as a supporting point and the blade leading edge end 4a3 being as a power point, the "curvature angle s(equal to an angle between the vertical camber line C12 and the a line parallel to the rotational axis 0) becomes larger toward the inner circumference side of the impeller in a longitudinal cross section perpendicular to the chord D in a horizontal section at the blade main plate side end 4d. In other words, the leading edge side plate side end 4al and the leading edge inner circumferential side end 4a2 on the side of the side plate 3 curves radially outward toward the rotational direction surface 4b of the blade 4 (toward the blade leading edge inner circumferential side end 4a2 from the inner circumferential side end 4gl of the side plate joined portion) so as to create a folding line B (oblique line, see Fig. 2) going toward the main plate 2 side. This arrangement reduces the difference between an inflow at the blade leading edge inner circumferential side end 4a2 on the side of the side plate 3 and an inflow at the leading edge side plate side end 4al, as compared with a conventional curvature with starting point on the horizontal 38 line perpendicular to the rotational axis 0. [0050] (ix) The leading edge inner circumferential side end 4a2, and the leading edge side plate side end 4al are connectively formed into a substantially triangle shape with the leading edge end 4a3 as an apex, which homogenizes a vertical vortex occurring at the blade leading edge inner circumferential side end 4a2 and the leading edge side plate side end 4al around the blade leading edge end 4a3, causing to be stabilized by an air flow to be guided onto the blade inner circumferential surface 4c. Accordingly, even if the filter 12 (ventilating, pressure loss body disposed on the side of the fan inlet opening la) has dust built up thereon and air flow resistance is increased, air flow separation can hardly occurs, thereby suppressing noise levels deterioration to be low. [0051] (x) Fig. 16 is a diagram showing the relationship between a curvature angle s and "noise level in relation to air flow resistance ratio" associated with the same air volume. Namely, it shows "noise level in relation to air flow resistance ratio" that is the ratio of a value for the filter having no dust buildup to that for the filter having a dust buildup. As shown in Fig. 16, if 61 falls within a range between 25 and 45 degrees, a low-noise turbofan and a 39 low-noise air conditioning apparatus which hardly suffers from air flow separation regardless of a change in air flow resistance at the fan inlet opening la can be obtained. [0052] (xi) In addition, as shown in Fig. 12, the blade 4 has its thickness T decreasing toward the side plate 3 in the height direction of the fan from the main plate 2 and has a hollow structure having an opening 2b on the outside of the impeller of the main plate 2, which contributes to a reduction in weight. This arrangement reduces starting torque exerted on the boss 2a at a start of a fan motor as well as suppresses distortion, leading to an improvement in durability of the turbofan 1. [0053] (xii) Furthermore, in the blade 4, the longitudinal cross section Kl-Kl shown in Fig. 6 (longitudinal cross section containing the end in the rotational direction 4gl in the side plate joined portion of the blade 4 perpendicular to the chord D in a horizontal cross section at the blade main plate side end 4d) and a predetermined region toward the downstream blade trailing edge 4e are formed so as to substantially stand upright in parallel to the rotational axis 0 in relation to the main plate 2. Consequently, when the main plate 2 is pressed against the blade 4 in parallel to the rotational axis 0 in order to 40 weld the blade 4 and the side plate 2 into one body, "stress concentration at the blade main plate side end 4d" to be encountered by a conventional blade being slanted relative to the main plate 2 can be mitigated, thereby preventing the buckling of the blade 4 so as to lead to the facilitation of assembly as well as improved reliability. [0054] (xiii) As to an inlet angle 13 in each cross-sectional view of the blade 4 taken along a plane perpendicular to the rotational axis 0, the inlet angle P14 at the blade leading edge end 4a3 is the smallest in the leading edge 4a. In addition, the inlet angle 11 at a portion close to the center in the impeller height direction in the blade leading edge inner circumferential end 4a2, is formed radially inward so as to be greater than the inlet angle 011 on the main plate side and the inlet angle 114 at the blade leading end, that is, it has a relationship of 11 > 111 > 114. In addition, the inlet angle 11 is designed to gradually become larger toward the side plate joined portion 4g from the blade leading edge end 4a3 in the blade side plate side end 4al, thereby reducing "an incident angle 6" which is the angular difference between "inlet flow J" and the inlet angle 1 on a horizontal section perpendicular to the rotational axis 0 at the blade leading edge inner circumferential side end 4a2, as well as allowing drawn air 41 to be smoothly drawn in with less separation, which leads to a reduction in noise levels. [0055] (xiv) From the blade leading edge end 4a3 to the side plate joined portion 4g in the blade leading edge side plate side end 4al, the drawn air is radially introduced with a slope toward the fan inlet opening la, and further radially introduced by gradually increasing the inlet angle P, so as to mitigate the separation on the side of the side plate 3 as well as to homogenize the wind speed distribution in the fan outlet opening lb. [0056] (xv) An angular difference between the inlet angle 314 (see Figs. 8 and 11) at the blade leading edge end 4a3 and the inlet angle 112 at the leading edge inner circumferential side end 4a2 (see Figs. 7 and 11) at a height position on a concave-shaped bottom in which the vertical camber line C12 is most directed in the opposite rotational direction on the blade outer circumferential surface 4b is set as "angular difference A$1". With this arrangement, as shown in Fig. 17, although excessively greater angular difference A01 causes a separation on the blade inner circumferential surface 4c on the side of the main plate 2 as well as increased noise levels, the angular difference Apl of 10 to 20 degrees 42 causes a reduction in noise levels. [0057) (xvi) Incidentally, a blade trailing edge 4e formed into a curved shape as substantial S shape and a blade leading edge 4a formed to curve radially outward provide noise reduction effects individually, as compared with the conventional blade. In addition, the combination of these shapes allows the drawn air to be smoothly drawn in along the entire blade leading edge 4a, causing a rectified air flow to be drawn in toward the blade trailing edge 4e. This facilitates the flow of the drawn air along the substantial S shaped surface of the blade with less turbulence, further homogenizing the wind speed distribution and reducing noise levels by synergistic effect. [0058] As described above, a turbofan according to the present invention is a low-noise, reliable, and durable turbofan. An air conditioning apparatus provided with such a turbofan ensures a comfortable usage environment free from harsh noise as well as a trouble free use for a long time. Thus, a low-cost, high-quality air conditioning apparatus can be provided. [0059] [Embodiment 3: turbofan] 43 Figs. 18 and 19 show a turbofan according to Embodiment 3 of the present invention. Fig. 18 is a perspective view, while Fig. 19 is a partial cross-sectional view (to be precise, a longitudinal sectional view of the blade 4 in a plane perpendicular to the chord D at the blade main plate side end 4b). The same symbols and reference numerals in Figs. 18 and 19 as those in Embodiment 2 (Figs. 2 through 12) refer to the same components, and repeated descriptions of the same components are partially omitted. (0060] In Fig. 18, a leading edge side plate side end 4al which is an edge of the blade 4 close to the side plate 3 curved so as to be placed more radially outward as it becomes closer to the leading edge inner circumferential side end 4a2 in a plan view, in a region away from the side plate 3 (equal to a region located at the side plate opening), and the curved region expands so as to become away from that end as it becomes closer to the leading edge inner circumferential side end 4a2 in a side view. In other words, the turbofan 30 has a folding line B heading gradually in the direction of the main plate 2, which is formed in the radially outward curving leading edge side plate side end 4al of the blade 4 and in the blade outer circumferential surface 4b at the leading edge inner circumferential side end 4a2 on the side of the side plate 3 44 so as to be directed toward the leading edge inner circumferential side end 4a2 of the blade 4 from the end in the rotational direction 4gl in the blade outer circumferential surface 4b at the side plate joined portion 4g. In addition, a rectangular-shaped concave groove 5 is formed in the blade inner circumferential surface 4c in the curved region so as to be substantially perpendicular to the folding line B and obliquely outwardly extend to the side of the main plate 2 from the side of the side plate 3 in relation to the rotational axis 0. In Fig. 19, the concave groove 5 becomes shallower as it is closer to the leading edge side plate side end 4al. In other words, the blade 4 is formed of a component constituting the blade outer circumferential surface and a component constituting the blade inner circumferential surface, and has a dual structure having a hollow formed therein. These two components are joined together at the leading edge side plate side end 4al, and the distance between them becomes larger at a position further away from the leading edge side plate side end 4al. The groove bottom 5a of the concave groove 5 is formed with the component constituting the blade outer circumferential surface, so the depth of the concave groove 5 corresponds to the distance between the inner 45 circumferential surface of the component constituting the blade outer circumferential surface and the inner circumferential surface of the component constituting the blade inner circumferential surface. [0061] When driven by a fan motor in the rotational direction A, the turbofan 30 having the above structure draws air through the fan inlet opening la and substantially radially blows out the drawn air in the rotational direction through the fan outlet opening lb, after passing through the blade 4. When air is drawn into the blade 4, the air smoothly flows on and along the blade outer circumferential surface 4c to the blade trailing edge without any turbulence, since the leading edge side plate side end 4al curves in the radially outward direction. Also, the concave groove 5 extends obliquely so as to expand toward the side of the main plate 2 from the side of the side plate 3 in relation to the rotational axis 0, thereby allowing the groove bottom 5a to rectify the air flow and suppress the turbulence, leading to further reduction in noise levels. [0062] The groove bottom 5a of the concave groove 5 is formed to extend along the blade outer circumferential surface 4b, so as to make the thickness of the blade 4 smaller. In the case of a turbofan formed of a thermoplastic resin, this 46 arrangement prevents a surface sink due to smaller wall thickness even at a curved portion which tends to have a larger wall thickness, resulting in improved reliability in forming. In particular, the turbofan 30, if installed on an air conditioning apparatus 10 (see Fig. 1) having a ventilating pressure loss body such as a filter disposed at the fan inlet opening la thereof, prevents an air flow separation and maintains low noise levels even if dust gradually accumulates on the filter and results in increased air flow resistance. Industrial Applicability [0063] A turbofan according to the present invention can be widely used for household use and industrial use due to its low-noise and high manufacturing reliability. In addition, such a turbofan can be widely used in home-use and industrial air conditioning apparatuses. 47

Claims (14)

1. A turbofan comprising: a disc-shaped main plate having a boss that is a fixed portion to which a rotational shaft of a motor is secured; an annular side plate having a side plate opening formed at the center thereof and forming a wind guide wall together with the main plate; and a plurality of blades mounted across the main plate and the side plate; in a plan view seeing a face perpendicular to the rotational shaft from the side plate opening, each blade being positioned farther away from the rotational shaft, when coming from a blade leading edge to a blade trailing edge; with the blade leading edge, a front edge side side-plate edge and a front edge inner periphery side edge are continuously formed with a blade leading edge end being a bending point; an outer circumferential surface and an inner circumferential surface of the blade having a central region in the height direction substantially parallel to the rotational shaft at the blade leading edge, a region close to the main plate of the outer circumferential surface curves radially outward of the main plate as the region approaches the main plate in the blade leading edge, and a region close to the side plate of the front edge side side-plate edge and the front edge inner periphery side edge of 48 the blade curves radially outward of the side plate as the region approaches the side plate, thereby, the curved region of the blade outer circumferential surface forms a substantial triangle shape with the blade leading edge end being an apex.
2. The turbofan of claim 1, wherein, an end edge close to the side plate of the blade is connected to the side plate in a region close to the blade trailing edge, and the blade trailing edge of the blade has a wavy form having at least two inflection points located on a virtual cylinder connecting the outer circumferential edge of the main plate and the outer circumferential edge of the side plate and has a main plate side curved portion projecting to a rotational direction in a region closer to the main plate and a side plate side curved portion projecting in an opposite direction to the rotational direction in a region closer to the side plate.
3. The turbofan of claim 1, wherein, in a region located at the side plate opening, an end edge of the blade close to the side plate curves so as to be located more radially outward as the end edge comes closer to the blade leading edge in the plan view, and its curved region of the blade expands so as to go away from the end edge as the curved region comes closer to the blade leading edge in a side view in parallel to the rotational shaft. 49
4. he turbofan of any one of claims 1 to 3, wherein a line connecting a portion where the blade trailing edge is joined to the main plate and a portion where the blade trailing edge is joined to the side plate is parallel to the rotational shaft.
5. The turbofan of any one of claims 1 to 4, wherein the blade has a taper-shaped, in which the distance between the blade outer circumferential surface and the blade inner circumferential surface gradually becomes smaller toward the side plate from the main plate, and a hollow structure having a hollow formed therein.
6. The turbofan of any one of claims 1 to 5, wherein a center line between the blade outer circumferential surface and the blade inner circumferential surface is parallel to the rotational shaft in part of a region where the blade is joined to the side plate.
7. The turbofan of claim 2 or 4, wherein, in the side view of a tip of the blade trailing edge, an inclined line connecting a maximum projection in the rotational direction in the main plate side curved portion and a maximum projection in the opposite direction to the rotational direction in the side-plate side curved portion is inclined with an inclination angle between 10 to 30 degrees to a vertical line connecting a connecting portion with the main plate and a connecting portion with the side 50 plate.
8. The turbofan of claim 2 or 4, wherein, a circumferential curvature angle, which is an angle in the plan view, defined by a line connecting a center of the rotational shaft and an intersection of a horizontal camber line showing a center between the blade outer circumferential surface and the blade inner circumferential surface and an outer circumferential edge of the main plate in the plan view of the connecting portion with the main plate, and a line connecting the center of the rotational shaft and the intersection of the horizontal camber line showing the center between the blade outer circumferential surface and the blade inner circumferential surface and an outer circumferential edge of the side plate in the plan view of the connecting portion with the side plate is 5 to 15 degrees.
9. The turbofan of claim 2 or 4, wherein an angular difference between in the plan view of the main plate side curved portion, a main plate side outlet angle defined by a tangent to a horizontal camber line showing a center between the blade outer circumferential surface and the blade inner circumferential surface at a tip of the blade trailing edge and a tangent to a circle passing through the tip of the blade trailing edge having its center at the center of the rotational shaft at the tip of the blade trailing edge, and in the plan view of the side-plate side curved portion, a 51 side-plate side outlet angle defined by a tangent to a horizontal camber line showing a center between the blade outer circumferential surface and the blade inner circumferential surface at the tip of the blade trailing edge and a tangent to the circle passing through the tip of the blade trailing edge having its center at the center of the rotational shaft at the tip of the blade trailing edge, is 20 to 35 degrees.
10. The turbofan of claim 3, wherein, in the side view, a curvature angle which is an angle formed between a vertical camber line showing the center between the blade outer circumferential surface and the blade inner circumferential surface and the axial direction of the rotational shaft is between 25 to 45 degrees.
11. The turbofan of any one of claims 1 to 10, wherein, at a tip of the blade leading edge in the plan view, a blade side-plate side inlet angle that is an inlet angle at a position closer to the side plate, a blade middle inlet angle that is an inlet angle in the middle of the side plate and the main plate in a height direction, and a blade main plate side inlet angle that is an inlet angle at a position closer to the main plate have a relationship of "the blade middle inlet angle > the blade main plate side inlet angle > the blade side plate side inlet angle". 52
12. The turbofan of claim 11, wherein at a tip of the blade leading edge in the plan view, an angular difference between a blade middle inner circumferential inlet angle that is an inlet angle at an inner circumferential side in the middle of the side plate and the main plate in a height direction and a blade side-plate side inlet angle that is an inlet angle at an end closer to the side plate is between 10 to 20 degrees.
13. The turbofan of claim 3, wherein a concave groove is formed on the blade inner circumferential surface in the curved region of the blade at an end close to the side plate, a folding line is formed at a boundary of the curved region and the blade inner circumferential surface except the curved region, the concave groove is substantially perpendicular to the folding line, and the concave groove has a rectangular section and is gradually shallowing toward the end close to the side plate
14. An air conditioning apparatus, comprising the turbofan of any one of claims 1 to 13, and a ventilating pressure loss unit at least either at an air inlet opening of the turbofan or at an air outlet opening thereof. 53
AU2009237152A 2008-04-18 2009-03-04 Turbofan and air conditioner Active AU2009237152B2 (en)

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