JP2008057480A - Propeller fan with shroud - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To effectively prevent circulation of a leakage flow from a gap to the intake side of a blade outer peripheral end even if a gap between a shroud on an impeller side and a tubular part for forming a fan guide port on a partition board side, so as to improve air blowing performance and reduce noise caused by interference of the leakage flow with the blade. <P>SOLUTION: A propeller fan with shroud comprises: fan guide ports 11 disposed through the partition board 10; and an impeller having impeller blades which are integrated with shrouds 7 at their outer peripheries and are rotatably and loosely fit in the fan guide ports 11. The fan guide ports 11 are formed in a tubular part 10b extended from a partition face 10a of the partition board 10 to an air blow-off port direction. On the other hand, the shroud 7 is extended rearward with a state opposed along the fan guide ports 11 in the tubular part 10b, their air intake side front edge parts 7a are bent outward in a radial direction at front sides of the fan guide ports 11 so as to be disposed in parallel with partition faces 10a of the partition board 10, and their air blow-off side rear end parts 7c are smoothly enlarged outward in the radial direction. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a structure of a propeller fan having a shroud on the outer periphery of a blade of an impeller.

  In the case of a propeller fan, the outer periphery of the impeller blade is generally configured with a cylindrical mouth ring that is separate from the impeller blade and having an appropriate gap.

  In the case of such a propeller fan, not only the shape of the blade and the number of rotations but also the air blowing capacity is greatly influenced by the gap with the mouth ring. It is possible to reduce the intrusion of air from the blowing direction by reducing the gap, but if you do so, depending on the roundness of the impeller and mouth ring and variations in mounting accuracy, the outer periphery of the blade and the mouth ring Will come into contact and become a fatal defect as a device or device.

  Therefore, conventionally, the air blowing capacity is sacrificed, the gap size is increased, and the air gap is attached with a certain margin.

  Further, the fact that the gap between the outer periphery of the blade and the inner periphery of the mouth ring is not constant due to variations in roundness and mounting accuracy has also caused a reduction in blowing capacity.

  For this reason, in order to minimize the gap between the outer periphery of the impeller blade and the inner periphery of the mouth ring and eliminate the variation in size, a shroud is integrated into the outer periphery of the impeller, and its air blowing performance Several proposals have been proposed (see, for example, Patent Documents 1 to 4).

Japanese Utility Model Publication No. 63-10296 (the first page of the specification, FIGS. 1 to 3) JP-A-9-318100 (Specification, page 1-2, FIGS. 1 to 5) Japanese Patent No. 3092371 (Specifications, pages 1-7, FIGS. 1-7) Japanese Patent Laid-Open No. 2001-248590 (Specifications page 1-4, FIGS. 1 to 3)

(1) In the case of Patent Document 1 This invention relates to a fan having a fan having a plurality of blades and an annular fan guide (partition plate) provided on the outer leeward side of the rear end of the fan. An annular member (shroud) covering at least a part of the guide suction side is fixed to the outer peripheral portion of the rear end edge of the fan blade.

  However, in such a configuration, the inlet end of the annular member is close to the blade trailing edge in an oblique direction with respect to the partition plate, so that the clearance from the gap between the fan guide (partition plate) and the annular member (shroud) There is a problem that the leakage flow tends to flow to the suction side, and the leaked flow that interferes with the blade tip and the trailing edge of the blade tends to cause noise.

(2) In the case of Patent Document 2 In the outdoor unit of an air conditioner, the present invention provides an inward convex mouth ring (shroud) on the outer peripheral portion of the rear end edge side of a propeller fan that performs heat exchange with outside air, and the rear edge side This is characterized in that it corresponds to the fan guide (small mouse) on the partition plate (grill) side.

  Therefore, as in the case of the invention of (1), the leakage flow from between the mouth ring and the partition plate easily flows to the suction side, and the same leakage flow interferes with the blade tip and the blade trailing edge. Thus, there is a problem that noise is likely to occur.

(3) In the case of Patent Document 3 This invention forms a bell mouth having a semicircular cross section from the air suction side to the air blowing side of the partition plate side fan guide portion, The bell mouth is provided by providing a shroud comprising a suction side edge portion and a blow side edge portion having a surface, and fitting the rounded suction side edge portion of the shroud into the bell mouth having a semicircular cross section. An annular air circulation chamber is formed between the shroud and the shroud.

  This is an inwardly convex shroud structure substantially the same as the invention of (2) above, in particular, by forming the mouth ring on the fan guide side into a semicircular shape, thereby forming a smoother circulation flow. However, there is a problem in that the leakage flow is unavoidably circulated to the suction side, and the interference with the blade outer peripheral edge and the trailing edge becomes remarkable due to the large flow velocity of the leakage flow.

(4) In the case of Patent Document 4 This invention realizes a so-called labyrinth seal structure between the shroud and the fan guide to suppress the leakage flow, but also the sneak around the suction side occurs, There is a problem of easily interfering with the edge and the rear edge.

  The present invention was made based on these circumstances, and even if the gap between the shroud and the partition plate forming the fan guide port is large, the leakage flow from the gap to the blade outer peripheral end intake side is circulated. An object of the present invention is to provide a propeller fan with a shroud that can be effectively prevented to improve the air blowing performance, and in which noise due to interference with the blades of the same leakage flow is effectively reduced.

  In order to achieve the above object, the present invention is configured with the following problem solving means.

(1) First Problem Solving Means The first problem solving means of the present invention is provided in the main casing 1a, the air inlet 4a provided at one end of the main casing 1a, and the other end of the main casing 1a. The air guide port 4b, the fan guide port 11 provided between the air inlet port 4a and the air outlet port 4b in the main body casing 1a through the partition plate 10, and the main body casing. Positioned between the heat exchanger 2 provided on the air inlet 4a side of the partition plate 10 in 1a, and between the heat exchanger 2 and the air outlet 4b in the main body casing 1a And a shroud-equipped propeller fan having blades 6, 6... With a shroud 7 integrated on the outer periphery thereof freely rotatably fitted in the fan guide port 11. 11 is formed in a cylindrical portion 10b extending in the direction of the air outlet 4b from the partition surface 10a of the partition plate 10, while the shroud 7 is along the fan guide port 11 in the cylindrical portion 10b. The air suction side front edge portion 7a extends rearward in a state of being opposed to each other, is bent radially outward on the front side of the fan guide port 11, and is arranged side by side on the partition surface 10a of the partition plate 10. The air outlet side rear edge portion 7c is characterized by being smoothly expanded radially outward.

  In the same configuration, the cylindrical portion 10b of the partition plate 10 forming the cylindrical fan guide port 11 is fitted to the outer periphery of the shroud 7, and along the fan guide port 11 in the cylindrical portion 10b. The gap between the shroud 7 and the shroud 7 extending rearward in a state of facing each other is a long distance having a predetermined length in the axial direction of the impeller.

Therefore, according to such a configuration, the flow resistance between the inner peripheral surface of the cylindrical portion 10b on the partition plate 10 side and the outer peripheral surface of the shroud 7 is increased, and the rear of the blade portions 6, 6. flow blown edge 6b, the outer peripheral end of 6b · · · is hardly sneak the front edge portion 7a side of the shroud 7, the leakage flow f ₃ is suppressed.

  Further, in the same configuration, the shroud 7 has an air suction side front edge portion 7 a bent radially outward on the front side of the fan guide port 11 and arranged in parallel on the flat plate surface 10 a of the partition plate 10. In addition, the air blowing side rear edge portion 7c is smoothly enlarged radially outward.

  Therefore, according to such a configuration, the shape of the rear edge portion 7c of the shroud 7 and the fan guide port 11 are formed in the medium airflow rate range where the fan flow is widened radially outward as the flow pattern and the fan efficiency is high. The shape of the rear edge portion 10c of the cylindrical portion 10b of the partition plate 10 that is formed becomes appropriate, effectively inducing a flow toward the outside (a smooth flow along the wall surface), and a fan guide port 11 Even if the clearance between the inner peripheral surface of the cylindrical portion 10b for forming 11 and the outer peripheral surface of the shroud 7 is a large clearance, the leakage flow can be effectively reduced.

  As a result, fan air volume and static pressure characteristics can be improved, specific noise level can be reduced, and fan efficiency can be improved.

(2) Second Problem Solving Means According to a second problem solving means of the present invention, in the configuration of the first problem solving means, the air blowing side rear edge portion 7c of the shroud 7 includes the blades 6 and 6 of the impeller. The rear edge portions 6b, 6b, ... are located near the outer periphery.

  When reducing the leakage flow in this way, if the rear edge portion 7c of the shroud 7 is located near the outer periphery of the rear edge portions 6b, 6b. The shape of the rear edge portion 7c of the shroud 7 and the cylindrical shape of the partition plate 10 forming the fan guide port 11 in a medium air volume range where the fan blowing flow as a pattern spreads outward in the radial direction and the fan efficiency is high. The shape of the rear edge portion 10c of the portion 10b becomes more appropriate, and the outward flow can be effectively induced (smooth flow along the wall surface).

(3) Third Problem Solving Means According to a third problem solving means of the present invention, in the configuration of the first or second problem solving means, the inner periphery of the cylindrical portion 10b forming the fan guide port 11 is provided. The clearance G between the surface and the outer peripheral surface of the shroud 7 is characterized in that G = (0.015−0.03) D ₂ when the outer diameter of the impeller is D ₂ .

According to the actual measurement result, the clearance G between the inner peripheral surface of the cylindrical portion 10b of the partition plate 10 and the outer peripheral surface of the shroud 7 is G = (when the outer diameter of the impeller is D _2. 0.015 to 0.03) D ₂ was the most effective in improving the blowing performance and reducing noise.

(4) Fourth Problem Solving Means According to a fourth problem solving means of the present invention, in the configuration of the first, second or third problem solving means, the cylindrical portion 10b forming the fan guide port 11 is provided. The rear edge portion 10c is located in the vicinity of the outer periphery of the rear edge portion 7c of the shroud 7 and is expanded outward in the radial direction.

  With such a configuration, it is possible to effectively realize the diffuser action in the impeller blowing region, and in particular, the outer periphery of the rear edges 6b, 6b. It becomes possible to recover the static pressure of the dynamic pressure in the air flow blown out from the end, and it is possible to further improve the blowing performance.

  As a result, according to the present invention, it is possible to reduce the noise level of the fan as much as possible while improving the blowing performance of the propeller fan.

(Best Embodiment 1)
First, FIG. 1 to FIG. 3 show the overall configuration of the outdoor unit for an air conditioner according to the first embodiment of the present invention, which is configured by adopting the propeller fan with shroud of the present invention as a blower fan, and the configuration of the main part. ing. Moreover, FIG. 8 has shown the noise reduction effect of the ventilation fan of the outdoor unit.

  First, as shown in FIGS. 1 and 2, for example, the outdoor unit 1 of the air conditioner according to the present embodiment includes a heat exchanger 2 and an inner central portion at a back side air inlet 4a portion of a box-shaped main body casing 1a. On the other hand, a propeller fan F is provided on the front side air outlet 4b of the main casing 1a. Then, when the propeller fan F rotates, the air sucked from the back side air intake port 4a and passed through the heat exchanger 2 becomes a swirling airflow swirling in the rotation direction of the propeller fan F, and has the blow grill. It blows out ahead of the outdoor unit 1 through the air blower outlet 4b.

The propeller fan F includes a cylindrical hub 5, a plurality of substantially fan-shaped blades 6, 6,..., Blades 6, 6. An impeller (outer diameter D ₂ ) composed of a cylindrical shroud 7 fixedly provided on the outer periphery of the main body casing, and a fan motor 9 that rotationally drives the impeller via a rotary drive shaft 8. A cylindrical fan guide port 11 (diameter D) formed in a tubular portion 10b in the front-rear direction of the partition plate 10 that partitions the air suction port 4a side ventilation passage 1a and the air outlet (air blowing grille) 4b side ventilation passage. ₁ ) The blades 6, 6... Including the shroud 7 of the impeller are supported in a freely loosely fitting manner while maintaining a predetermined gap (clearance dimension G).

  In the case of the present embodiment, the shroud 7 has a predetermined shape radially outward on the front side of the partition surface (opening edge) 10a of the partition plate 10 so that the air suction side front edge portion 7a of the cylindrical main body portion 7b. A curved base portion (suction boundary portion) of the lower edge of the front edge portion 7b that rises in a width flange shape and is bent at a substantially right angle, for example, impeller blades 6, 6,. The cylindrical main body portion 7b is positioned at the outer peripheral end of the blades 6, 6... So that the chord width of the end portion is about ¼ to ¾ of the chord width. The flange-shaped front edge portion 7a is fixed to the surface, and the rear side of the flange-shaped front edge portion 7a is an opening on the air suction side of the tubular portion 10b in which the tubular fan guide port 11 of the partition plate 10 is formed. It is arranged so as to face the edge (the flat plate surface around the inlet of the fan guide port 11) with a predetermined gap. That.

  The blade chord positions (1/4 to 3/4) of the blades 6, 6... Where the front edge 7 a of the shroud 7 stands up in a flange shape are the outer peripheral ends of the blades 6, 6. This is the region where the air suction force is greatest on the front edge side to the rear edge side. Therefore, if there is a front edge portion 7a that is bent in a radial flange shape that performs the suction flow guide function of the shroud 7 in the same portion, an effective intake action is generated in the outer peripheral part of the impeller, and the blowing performance is as much as possible Will improve.

  As a result, interference with the outer peripheral ends of the blades 6, 6... And the rear edge portions 6b, 6b.

On the other hand, the standing width (overlapping width) in the radial direction of the flange-shaped front edge portion 7a of the shroud 7 that contacts the opening edge portion of the fan guide port 11 of the partition plate 10 with a predetermined gap is, for example, the blade it is preferred vehicles from 0.05 times the diameter D ₂ is the size of the order of 0.15 times.

  If this width is too large, the frictional sliding noise will increase, and if it is too small, the leakage flow will tend to wrap around to the front edge 7a side and the interference noise will increase.

Arrows f ₁ in FIG. 3 shows a flow of main suction air flow from the impeller front.

On the other hand, in the case of the present embodiment, the rear edge of the shroud 7 (rear end of the cylindrical main body 7b) 7c is the rear edge 6b, 6b,. The rear edge 7c is formed in a smooth rounded surface that gradually increases the opening diameter from the inside in the radial direction to the outside. Therefore, in the case of such a configuration, as shown in FIG. 3, with respect to the blowout flow f ₂ from the vicinity of the rear edge portions 6 b, 6 b... A suitable Coanda effect is produced, and the air that tries to go around from the vicinity of the outer peripheral edge of the rear edge 6b, 6b, ... of the blade 6, 6, ... to the front edge 7a side of the shroud 7 Is smoothly guided outward in the downstream direction by the rounded surface of the rear edge portion 7c, causing interference at the rear edge portions 6b, 6b. No longer.

  As a result, noise is effectively reduced.

  Moreover, in the case of the present embodiment, a cylindrical portion 10b that is long in the front-rear direction of the partition plate 10 forming the cylindrical fan guide port 11 is fitted on the outer periphery of the cylindrical main body portion 7b of the shroud 7. The gap between the cylindrical portion 10b of the partition plate 10 and the cylindrical main body portion 7b of the shroud 7 is a long distance having a predetermined length in the axial direction of the impeller. ing.

Accordingly, the flow resistance between the inner peripheral surface of the partition plate 10 side cylindrical portion 10b and the outer peripheral surface of the cylindrical main body portion 7b of the shroud 7 is increased, and the trailing edge portion of the blades 6, 6. The flow f ₂ blown to the outer peripheral end from 6b, 6b... Is more reliably prevented from flowing to the front edge portion 7a side of the shroud 7, and the leakage flow f ₃ is more effectively suppressed.

  Further, in the same configuration, the shroud 7 has an air suction side front edge portion 7 a bent radially outward on the front side of the fan guide port 11 and arranged in parallel on the flat plate surface 10 a of the partition plate 10. In addition, the air outlet side rear edge portion 7c is smoothly expanded radially outward.

  The air blowing side rear edge portion 7c of the shroud 7 is located in the vicinity of the outer periphery of the rear edge portions 6b, 6b.

  Therefore, according to such a configuration, the shape of the rear edge portion 7c of the shroud 7 and the fan guide port 11 are formed in the medium airflow rate range where the fan flow is widened radially outward as the flow pattern and the fan efficiency is high. The shape of the rear edge portion 10c of the cylindrical portion 10b of the partition plate 10 that is formed becomes appropriate, effectively inducing a flow toward the outside (a smooth flow along the wall surface), and a fan guide port 11 Even if the clearance between the inner peripheral surface of the cylindrical portion 10b for forming 11 and the outer peripheral surface of the shroud 7 is a large clearance, the leakage flow can be reduced more effectively.

  As a result, fan air volume and static pressure characteristics can be improved, specific noise level can be reduced, and fan efficiency can be improved.

In the above case, the length of the tubular portion 10b for forming the tubular fan guide port 11 of the partition plate 10 is the same as the rear edge portion 7c of the tubular portion main body 7b of the shroud 7, for example, as shown in FIG. Or a little longer than that is preferable. If the length of the cylindrical portion 10b is too short, and the rear edge portion 7c of the shroud 7 does not have the above-described radial outward surface, as shown in FIG. 4, for example, as shown in FIG. Callout flow f ₂ is separated inside the shroud trailing edge, easily enter the flow leaking from the external space of.

On the other hand, even if a rounded surface is formed on the rear edge 7c of the shroud 7, if the length of the rear edge 10c of the cylindrical portion 10b on the partition plate 10 side is too long as shown in FIG. will callouts flow f ₂ itself extends radially outward from the outer peripheral end is inhibited by the edge 10c after long, fan performance deteriorates. Further, the flow f ₂ on the outer peripheral end side of the impeller collides with the same long rear edge portion 10c to generate a reverse flow, and the leakage flow f ₃ is easily generated.

  Therefore, even if the length of the cylindrical portion 10b of the partition plate 10 is longer than the rear edge portion 7c of the shroud 7, it is, for example, slightly longer than that shown in FIG. It is possible to obtain the same effect as the above.

  As described above, according to the present embodiment, the gap between the inner peripheral surface of the cylindrical portion 10b for forming the fan guide port 11 of the partition plate 10 and the outer peripheral surface of the cylindrical main body portion 7b of the shroud 7 is Even with a large clearance, the leakage flow can be effectively reduced.

  As a result, the noise level of the fan can be reduced as much as possible while improving the blowing performance of the propeller fan. In addition, the fan can be easily assembled and the reliability can be improved (installation and icing).

In the above configuration, in this case, the clearance G between the inner peripheral surface of the cylindrical portion 10b of the partition plate 10 and the outer peripheral surface of the cylindrical main body portion 7b of the shroud 7 is the same as that of the impeller. the outside diameter when the D _2, is set to G = (0.015~0.03) D _2.

According to the actual measurement results, for example, as shown in the graph of FIG. 8, when the clearance G is G = (0.015−0.03) D ₂ , for example, the flow of air is outside as a flow pattern. It was found to be particularly effective in the medium air volume range where the fan efficiency is high and the fan efficiency is wide.

In contrast to the specific noise level in FIG. 8, as an example of the related art, as shown in FIG. 10, for example, the impeller portion of the propeller fan F is brought slightly forward from the partition surface 10a of the partition plate 10 as described above. At the same time, the front edge portion 7a of the shroud 7 is bent in a right angle direction so as to be parallel to the partition surface 10a of the partition plate 10, so that the front edge portion 7a is formed on the front side of the partition surface 10a of the partition plate 10 as a fan guide. The opening edge portion of the flat fan guide port 11 of the partition plate 10 is used to make contact with the opening edge portion of the mouth 11 and reduce the gap 11 between the partition plate 10 and the shroud 7 at the contact portion. What improves the sealing effect by providing the convex portion 10d on the front side (the inner peripheral surface of the opening of the partition plate 10 in which the fan guide port 11 is formed in a flat shape rather than a cylindrical shape) Outer diameter D ₂ of the impeller of a propeller fan F was measured by employing the case) of the D ₂ = 160 mm in the clearance G is G = 1.5 mm between the cylindrical portion 7b peripheral surface of the shroud 7.

  As a result, as is apparent from the data of FIG. 8, as shown in the configuration of FIG. 10, the convex portion 10 d is formed on the opening edge portion of the fan guide port 11 that simply opens planarly on the partition surface 10 a of the partition plate 10. If the gap between the fan guide port 11 and the shroud 7 is reduced, it is not effective in reducing the specific noise, and is effective only when configured as in the above-described embodiment of the present invention. I understand.

(Best Mode 2)
Next, FIG. 6 shows the configuration of the fan portion of the outdoor unit for an air conditioner according to the second preferred embodiment of the present invention, which is configured by adopting the propeller fan with shroud of the present invention as a blower fan.

  In this embodiment, the diameter of the rear edge portion 10c of the tubular portion 10b for forming the fan guide port 11 of the partition plate 10 having the configuration of the best embodiment is set to be the same as that of the rear edge portion 7c of the shroud 7. It is characterized by a rounded surface that is smoothly expanded radially outward. The structure of the other parts is exactly the same as that of the above-described best embodiment 1, and performs the same function.

According to such a configuration, the above-mentioned Coanda effect on the blow-off flow f ₂ from the vicinity of the outer peripheral end of the rear edge portions 6b, 6b,... flow path resistance between the inner peripheral surface and a tubular body portion 7b outer peripheral surface of the shroud 7 of the cylindrical portion 10b of the fan guide opening 11 for the formation increases, the leakage flow f ₃ is suppressed.

  Then, in the medium air volume range where the fan flow is spread outward as the flow pattern and the fan efficiency is high, the shape of the rear edge portion 7c of the shroud 7 and the cylindrical portion for forming the fan guide port 11 of the partition plate 10 The shape of the rear edge portion 10c of 10b becomes more appropriate, effectively inducing the outward flow (to make a smooth flow along the wall surface), and the inside of the tubular portion 10b for forming the fan guide port 11 Even if the clearance between the peripheral surface and the outer peripheral surface of the cylindrical body portion 7b of the shroud 7 is a large clearance, the leakage flow can be reduced more effectively.

  As a result, the noise level of the fan can be reduced as much as possible while improving the blowing performance of the propeller fan.

(Best Mode 3)
Next, FIG. 7 shows a configuration of a fan portion of an outdoor unit for an air conditioner according to a third preferred embodiment of the present invention, which is configured by adopting the propeller fan with shroud of the present invention as a blower fan.

  In this embodiment, the length of the rear edge portion 10c of the tubular portion 10b for forming the fan guide port 11 of the partition plate 10 in the configuration of the best embodiment 2 is slightly increased in the rear, and then the above-described configuration. The second embodiment is characterized in that it is bent (inclined) so that its diameter is enlarged radially outward from the rear end position in substantially the same manner as in the second embodiment. It is. The structure of the other parts is exactly the same as that of the second embodiment, and performs the same function.

That is, even with such a configuration, as shown in FIG. 7, the above-mentioned Coanda effect on the blow-off flow f ₂ from the rear edges 6b, 6b,. Becomes more effective, and the flow resistance between the inner peripheral surface of the cylindrical portion 10b for forming the cylindrical fan guide port 11 and the outer peripheral surface of the cylindrical main body portion 7b of the shroud 7 increases, and the leakage flow f ₃ is suppressed.

  Then, in the medium air volume range where the fan flow is spread outward as the flow pattern and the fan efficiency is high, the shape of the rear edge portion 7c of the shroud 7 and the cylindrical portion for forming the fan guide port 11 of the partition plate 10 The shape of the rear edge portion 10c of 10b becomes appropriate, and the flow toward the outside is effectively induced (as a smooth flow along the wall surface), and the inner periphery of the cylindrical portion 10b for forming the fan guide port 11 Even if the clearance between the surface and the outer peripheral surface of the cylindrical body portion 7b of the shroud 7 is a large clearance, the leakage flow can be effectively reduced.

  As a result, the noise level of the fan can be reduced as much as possible while improving the blowing performance of the propeller fan.

(Fourth Embodiment)
Next, FIG. 9 shows the configuration of the fan portion of the outdoor unit for an air conditioner according to the fourth preferred embodiment of the present invention, which is constructed by adopting the propeller fan with shroud of the present invention as a blower fan.

  In this embodiment, as in the case of the configuration of the best embodiment 3, the length of the rear edge portion 10c of the cylindrical portion 10b for forming the fan guide port 11 of the partition plate 10 is increased rearward. The diameter is increased outward in the radial direction, but unlike the above-described third embodiment, the enlarged end portion is further extended to the rear by a predetermined length to obtain an equal diameter portion. It is formed in (cylindrical part).

  According to such a configuration, in addition to the Coanda effect similar to that of the third embodiment, a diffuser effect can be obtained, and the static pressure in the air flow blown from the impeller can be reduced. Pressure recovery can be performed efficiently.

  Therefore, the air blowing performance is further improved.

It is a front view which shows the structure of the outdoor unit for air conditioners which concerns on best Embodiment 1 of this invention comprised using the propeller fan with a shroud of this invention. It is a longitudinal cross-sectional view which shows the structure of the outdoor unit. It is sectional drawing which shows the structure of the propeller fan part with a shroud of the outdoor unit. It is sectional drawing which shows the effect | action of the modification structural example 1 (comparative 1) of the cylindrical part for fan guide opening formation of the same propeller fan with a shroud, and a shroud rear edge part. It is sectional drawing which shows the effect | action of the modification structural example 2 (comparison 2) of the cylindrical part for fan guide port formation of the same propeller fan with a shroud, and a shroud trailing edge part. It is sectional drawing which shows the structure of the propeller fan part with a shroud of the outdoor unit for air conditioners which concerns on the best Embodiment 2 which employ | adopted and comprised the propeller fan with a shroud of this invention. It is sectional drawing which shows the structure of the propeller fan part with a shroud of the outdoor unit for air conditioners which concerns on the best Embodiment 3 of this invention comprised using the propeller fan with a shroud of this invention. It is a figure (graph) which shows the noise reduction effect of the same propeller fan with a shroud. It is sectional drawing which shows the structure of the propeller fan part with a shroud of the outdoor unit for air conditioners based on the best Embodiment 4 comprised using the propeller fan with a shroud of this invention. It is sectional drawing which shows the structure of the conventional propeller fan with a shroud contrasted with the noise reduction effect of the propeller fan with a shroud of the said best embodiment 1 of this invention.

Explanation of symbols

  1 is an outdoor unit, 1a is a main body casing, 2 is a heat exchanger, 5 is a hub, 6 is a blade, 7 is a shroud, 7a is a front edge, 7b is a cylindrical main body, 7c is a rear edge, and 9 is A fan motor, 10 is a partition plate, 10a is a partition surface (opening edge portion), 10b is a cylindrical portion, 10c is a rear edge portion, and 11 is a fan guide port.

Claims (4)

  A main casing (1a), an air inlet (4a) provided at one end of the main casing (1a), an air outlet (4b) provided at the other end of the main casing (1a), and the main body A fan guide port (11) provided between the air inlet port (4a) and the air outlet port (4b) in the casing (1a) and provided via a partition plate (10); and the main body casing. A heat exchanger (2) provided closer to the air inlet (4a) than the partition plate (10) in (1a), and the heat exchanger (2 in the main casing (1a)). ) And the air outlet (4b), and the blades (6), (6)... Integrated with the shroud (7) on the outer periphery can be rotated into the fan guide port (11). Propeller fan with shroud comprising a loosely fitted impeller The fan guide port (11) is formed in a cylindrical portion (10b) extending in the direction of the air outlet (4b) from the partition surface (10a) of the partition plate (10). The shroud (7) extends rearward while facing the fan guide port (11) in the cylindrical portion (10b), and its air suction side front edge (7a) is the fan guide port (11). Is bent radially outward on the front side of the partition plate 10 and arranged side by side on the partition surface (10a) of the partition plate (10), and the air blowing side rear edge (7c) smoothly expands radially outward. Propeller fan with shroud, characterized by   The rear edge (7c) of the air blowing side of the shroud (7) is located near the outer periphery of the rear edges (6b), (6b)... Of the impeller blades (6), (6). The propeller fan with a shroud according to claim 1. The clearance G between the outer circumferential surface of the inner circumferential surface and the shroud of the tubular portion forming the fan guide opening (11) (10b) (7 ) , the outer diameter of the impeller when the D _2, G = (0.015 to 0.03) shroud with a propeller fan according to claim 1 or 2, characterized in that a D _2.   The rear edge (10c) of the cylindrical portion (10b) forming the fan guide port (11) is located near the outer periphery of the rear edge (7c) of the shroud (7) and expands radially outward. The propeller fan with a shroud according to claim 1, wherein the propeller fan has a shroud.

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