This application is a broadening reissue application of U.S. Pat. No. 9,822,801, issued on Nov. 21, 2017, which is a U.S. national stage application of PCT international application PCT/KR2014/011715 filed on Dec. 2, 2014 and claims the benefit of Japanese Patent Application Nos. JP2013-249308, filed on Dec. 2, 2013, and JP2014-157177, filed on Jul. 31, 2014, and Korean Patent Application No. 10-2014-0170184, filed on Dec. 2, 2014, in the Japan Patent Office and the Korean Intellectual Property Office, respectively, the content of each of the foregoing is incorporated herein by reference.
1. Technical Field
The present invention relates to an outdoor unit of an air conditioner and a blower used for the same.
2. Background Art
In a conventional blower, a diffuser part (a ventilation part) extends to a downstream from a cylindrical bell mouth part installed around a propeller fan, for example, as described in Japanese Unexamined Patent Application Publication No. 2013-119816.
However, an air current may not be uniformly introduced into inlet ports installed at an upstream side of the bell mouth part based on an apparatus in which the blower is installed, therefore a suction flow rate may be distributed according to region.
Because of this, blowing efficiency may not be improved more than a certain level, and there is also a problem in that when the number of revolutions of a propeller fan is increased for increasing the suction flow rate, power consumption is increased and noise is generated. Particularly, in a configuration of Patent document 1 in which a noise prevention blade (a stator blade) is installed in a diffuser part, noise generated in the noise prevention blade is also a problem.
Recently, high efficiency has been achieved by heat exchangers being installed in a plurality of parallel rows in an outdoor unit of an air conditioner, and accordingly a plurality of blowers are adjacently disposed to correspond to the heat exchangers. However, this arrangement has caused efficiency to deteriorate or noise to increase, such as air currents which flow from diffuser s collide with each other and interfere with each other.
The present invention is directed to providing a blower which significantly improves blowing efficiency and suppresses noise and an outdoor unit of an air conditioner using the same.
One aspect of the present disclosure provides a blower including a fan, a container-shaped molded object provided so that a bell mouth part provided to be spaced apart from an outer circumferential surface of the fan and a diffuser part provided to be extended from a downstream end of the bell mouth part are integrally molded, and a molded blade part including a plurality of noise prevention blades and provided at the diffuser part, wherein the diffuser part is provided to be inclined so that an area of a flow path increases toward a downstream end of the diffuser part, and an inclination angle of the diffuser part varies along a circumferential direction of the diffuser part with respect to a rotation shaft of the fan. Another aspect of the present disclosure provides an outdoor unit of an air conditioner including a heat exchanger, the outdoor unit includes a fan having an outer circumferential end coupled to a rotation shaft; a bell mouth part including a downstream end, the bell mouth disposed to be around the outer circumferential end of the fan and spaced apart from the outer circumferential end of the fan; and a diffuser part including: an opening having an inner circumferential surface, an upstream end disposed at the downstream end of the bell mouth part, and a downstream end at which the air is discharged to outside of the outdoor unit, the diffuser part disposed to be extended from the downstream end of the bell mouth part to provide an air flow path of the fan through the opening, from the upstream end of the diffuser part toward the downstream end of the diffuser part. The inner circumferential surface of the diffuser part is inclined at a diffuser angle (θ) with respect to an axis of a rotation of the rotation shaft so that a cross-sectional area of the air flow path increases toward the downstream end of the diffuser part, and the diffuser angle (θ) with respect to the axis of the rotation of the rotation shaft of the fan varies along a circumferential direction of the inner circumferential surface of the diffuser part
When an inclination angle between an inclination of the diffuser part and a rotation shaft of the fan is represented as a diffuser angle (θ), a diffuser angle positioned at a side at which an air flow rate is great may be provided to be greater than a diffuser angle positioned at a side in which an air flow rate is small.
The plurality of noise prevention blades may be disposed to be spaced apart from each other in a radial shape around the rotation shaft of the fan, and outer circumferential ends of the plurality of noise prevention blades may be supported by an inside of the diffuser part.
The plurality of noise prevention blades may be formed to have an arc-shaped surface and provided to have convex surfaces facing the fan.
The molded blade part may be provided so that a boundary surface of a lower end of the molded blade part is provided along the convex surfaces of the plurality of noise prevention blades.
Another aspect of the present disclosure provides a blower including a fan, a diffuser part provided so that an area of a flow path is increased from a discharging surface through which the fan discharges air toward a downstream end, and a molded blade part including a hub provided in a cylindrical shape and having a hollow around a rotation shaft of the fan and a plurality of noise prevention blades provided to be extended from an outer circumferential surface of the hub toward an inclined surface of the diffuser part, wherein the plurality of noise prevention blades are disposed to be spaced apart from each other in a radial shape around the hub, and outer circumferential ends of the plurality of noise prevention blades are provided to be extended from the hub to the inclined surface of the diffuser part in an arc shape so that the outer circumferential ends of the plurality of noise prevention blades are supported by the inclined surface of the diffuser part.
An inclination angle of the diffuser part may vary along a circumferential direction of the diffuser part with respect to the rotation shaft of the fan, and a distance between an outer circumferential end of the hub and the inclined surface of the diffuser part may proportionally vary according to the varying inclination angle of the diffuser part.
That is, the blower according to an embodiment of the present disclosure is a blower provided with the bell mouth part disposed at the outside of a propeller fan in a diameter direction and having a lateral cross-section in a circular shape, and the diffuser part installed in series at a downstream end of the bell mouth part, an inclined surface facing the outside in the diameter direction as at least a part of the inner circumferential surface of the diffuser part faces a downstream side, and simultaneously an opening of a downstream end of the diffuser part has a shape different from the circular shape.
Accordingly, since a flow path enlargement rate of the diffuser part varies according to positions by, for instance, setting the flow path enlargement rate according to a flow rate of each position of non-uniform air current having a suction flow rate deviation (a distribution) due to the position, loss of the diffuser part is may be suppressed, and a pressure restoring effect may be maximized.
As a result, blowing efficiency may be significantly increased and blowing noise may be decreased due to a flow speed decreasing effect which is an evidence of the pressure restoring effect.
An opening of a downstream end of the diffuser part, which is easy to manufacture and practical may have an oval shape (a capsule shape) or polygonal shape of which corners are rounded.
When an angle formed by the inclined surface and a rotation shaft line of the fan is represented as a diffuser angle and the diffuser angle is provided to generally vary in a circumferential direction, turbulence generation due to drastic increasing an area of a flow path of the diffuser part is suppressed as much as possible, a pressure restoring effect may be obtained, and thus efficiency improvement and a noise decrease effect may more obviously be obtained.
As a specific aspect which suppresses the turbulence generation, when the diffuser angle is represented as θ, the diffuser angle may vary in the range of 3°≤θ≤35°.
To more obviously obtain the effect of the embodiment of the present disclosure, it is preferable that the diffuser angle of a portion at which an air flow rate which passes through the propeller fan is great be greater than that of a portion at which the air flow rate which passes through the propeller fan is small.
To obtain high efficiency and low noise while suppressing loss due to collision or interference of air currents discharged from the blowers at the blowers and other blowers disposed adjacent to the blowers, it is preferable that the diffuser angle θ of a portion adjacent to the other blowers be set in the range of 3°≤θ≤7° when the diffuser angle is represented as θ.
Meanwhile, when the bell mouth part is disposed to be spaced a predetermined distance from the outer circumferential end of the propeller fan, the diffuser part is installed at the downstream side of the bell mouth part, in which an area of a flow path is increased from an upstream side to a downstream side with an enlargement rate greater than an area enlargement rate of a flow path at the downstream end of the bell mouth part, and the stator part includes the plurality of noise prevention blades and disposed in the diffuser part, the diffuser part is formed at the downstream side of the bell mouth part, a tip clearance between the propeller fan and the bell mouth is kept to a necessary minimum, and the area enlargement rate of the flow path required for pressure restoring at the diffuser part may be obtained. Meanwhile, since the stator part is disposed in the diffuser part, the dynamic pressure of a vortex may be collected from the propeller fan compared with a conventional case. In addition, the blower according to an embodiment of the present disclosure may further improve blowing efficiency due to a synergistic effect.
In addition, since the diffuser part has an enlarged magnified flow path shape and the stator part is installed therein, the vortex may be introduced into the stator part from the propeller fan in a state in which an average speed of the vortex is sufficiently lowered, and thus a noise level generated from the noise prevention blades may be lowered.
In addition, since there is no need for the diffuser part to consider a tip clearance for the propeller fan unlike the bell mouth part, and the diffuser part is installed at a downstream of the bell mouth part and the stator part is disposed in the diffuser part, blowing efficiency may be further improved due to a synergistic effect with the diffuser part and the stator part. In addition, in the above-described structure, the diffuser part has an oval shape as seen from a shaft, a direction or length of span of at least a part of the noise prevention blades of the stator part may be different, a noise level which is increased by noise generated from the noise prevention blades reaching a peak point and overlapping each other may be prevented, and thus an overall noise level may be decreased.
Further specifically, it is preferable that the downstream end of the diffuser part be formed in an oval shape as seen from the shaft, the plurality of noise prevention blades be disposed in a radial shape from the center as seen from the shaft, and an outer circumferential end be in contact with an inner circumferential surface of the diffuser part. Accordingly, the diffuser part may have a suitable shape for restoring pressure, and a length or shape along a span direction of the noise prevention members constituting the stator part may not be the same, and thus a noise peak of a blade passing frequency (BPF) may be suppressed.
To obtain a specific shape for suppressing fluid separation due to a reverse pressure gradient at the diffuser part and easily obtaining a static pressure raising effect due to the diffuser part, it is preferable that a divergence angle α which is an angle formed by an upstream end of the diffuser part with respect to a virtual line extending from the downstream end of the diffuser part toward the shaft as seen from the longitudinal cross-section be in the range of 3°≤α≤35°, however, when there is the noise prevention blade, the divergence angle a may be set to in the range of 0°<α<18°. It may be more preferable that the divergence angle α be set to 9°. In addition, the diffuser angle θ may be an angle of any portion of the diffuser part, the divergence angle α may be an angle of the upstream end of the diffuser part, and θ and a may be the same.
To suppress a drastic change in a curvature at the inner circumferential surface of the diffuser part due to the divergence angles at a major axis and a minor axis of the diffuser part being greatly different, easily rectify a flow at the diffuser part, and improve a static pressure raising effect, it is preferable to be set such that 0.75<D/W<1 when a length of the major axis of an oval shape of the downstream end of the diffuser part seen from the shaft is represented as W, and a length of the minor axis is represented as D.
To uniformly collect a dynamic pressure of a vortex from the propeller fan, and improve blowing efficiency, it is preferable that the central point of a circular or polygonal shape of the downstream end of the diffuser part or an intersection point of the major axis and the minor axis of an oval shape be exist on a rotation shaft line of the propeller fan as seen from the shaft.
To decrease a weight applied to the noise prevention blade and decrease necessary strength so that a thickness of the noise prevention blade is maintained and material cost is decreased, it is preferable that the stator part include the hub in a substantially hollow cylindrical shape in which the inner circumferential end of the noise prevention blade is connected to the outer circumferential surface and the hub include a reinforcement rib structure in a radial shape.
For example, to prevent breaking a rotational balance of the propeller fan due to snow being accumulated on a central portion of the propeller fan in the bell mouth part and being in contact with the inner circumferential surface of the bell mouth part to be destroyed, it is preferable that a cover member which is installed to cover the downstream side of the hub and has a cone-shaped surface or dome-shaped curved surface be further provided. Accordingly, since the cover member has the curved surface, snow is not accumulated on the hub, and the noise prevention blades of the stator part may also be prevented from being damaged due to a weight of snow.
It is preferable that the cover member be installed to be detachable from the hub in an area where it hardly snows so that a manufacturing cost is decreased by omitting the cover member.
To mold the diffuser part having a lateral cross-section of the downstream side in an oval shape, dispose the stator part in the diffuser part, and efficiently mold an even complex shape for improving blowing efficiency using resin injection molding, it is preferable to provide a container-shaped molded object in which the bell mouth part and the diffuser part are integrally molded and a molded blade part in which at least the stator part are molded.
According to the outdoor unit of the air conditioner using the blower according to an embodiment of the present disclosure, blowing efficiency may be significantly improved and fluid noise may also be reduced to be suitable to heat exchangers installed in a plurality of parallel rows.
As described above, a blower according to an embodiment of the present disclosure can significantly improve blowing efficiency as well as reduce blowing noise.
One embodiment of the present disclosure will be described with reference to accompanying drawings.
A blower 7 according to the present embodiment is a type of axial fan used for an outdoor unit 600 (hereinafter, simply referred to as the outdoor unit 600) for an air conditioner.
As illustrated in
Hereinafter, the blower 7 will be specifically described.
As illustrated in
The container-shaped molded object 73 has an edge having a rectangular (including a square) outline as seen from an axis of rotation C of the propeller fan 71, and simultaneously is an integrally molded object formed by forming a through hole along a direction of the axis of rotation C, and a bell mouth part 8 and a diffuser part 9 are formed on an inner circumferential surface of the through hole. In addition, here, the container-shaped molded object 73 is disposed at an upper portion in the casing 5.
The bell mouth part 8 includes a bell mouth duct 81 which is installed having a tiny gap at a further outer side than an outer circumferential end of the propeller fan 71 in an inner circumferential surface of the container-shaped molded object 73 and has a substantially circular container-like shape, and an opening (a bell mouth) 82, which is installed to be connected to an upstream side of the bell mouth duct 81, and has a horn shape.
The diffuser part 9 is formed at the inner circumferential surface which continues from or extends from a downstream end of the bell mouth part 8 toward a side in which a upstream is generated in the inner circumferential surface of the container-shaped molded object 73, and, here, is an inclined surface 91 which is inclined toward the outside in a direction of a diameter such that a front surface of the inner circumferential surface faces a downstream side thereof.
In addition, when an angle formed between the inclined surface 91 and the axis of rotation C is defined as a diffuser angle θ, as the diffuser angle θ is provided to be smoothly changed in a circumference direction, the downstream end opening 9a in the diffuser part 9 has a shape different from a substantially circular shape, for instance, an oval shape, so that a width of the downstream end opening 9a through which air flows from an outlet of the bell mouth duct 81 as seen from the axis of rotation C changes according to location.
Accordingly, the inclined surface 91 in which the width is minimized, that is, the diffuser angle θ is minimized, is the inclined surface 91 positioned on a minor axis C1 of the downstream end opening 9a having an oval shape as seen from the axis of rotation C. Here, the diffuser angle θ is set to 3°. In addition, a direction of the minor axis C1 matches along a shorter side at an outer edge outline of the container-shaped molded object 73 which has a rectangular shape, and simultaneously a plurality of (two) blowers 7 are installed along the minor axis C1 direction, in other words, longer side surfaces of the container-shaped molded objects 73 are adjacently disposed with each other.
Meanwhile, an inclined surface, in which the diffuser angle θ is maximized, is the inclined surface 91 positioned on a major axis C2 of the downstream end opening 9a as seen from the axis of rotation C. Here the diffuser angle θ is set to 35°.
In addition, an inner diameter value of a downstream end of the bell mouth duct 81 is defined as Db, a height value of the diffuser part 9 along the direction of the axis of rotation C is defined as L, an edge value of the container-shaped molded object (a width or a length as seen from the axis of rotation) is defined as S, and Db, L, and S are set to satisfy the following equation (1).
S/2=C(L×tan(θ)+Db/2) (1)
Here, C is a coefficient in the range of 1.03≤C≤1.5, and more preferably in the range of 1.06≤C≤1.12.
According to equation (1), the strength of the container-shaped molded object 73 is secured, an installation space may be maximally used, influence of an adjacent blower 7 is significantly reduced, noise due to maximizing a diameter of the propeller fan may be reduced, etc.
Meanwhile, as illustrated in
In addition, as illustrated in
0.6≤Dratio≤0.95 (2)
Hereinafter, an operation and an effect of the outdoor unit 600 configured as described above will be described.
As illustrated in
As described above, since a diffuser angle θ at the front and rear portions of the diffuser part 9 is set to as large a value as possible in the range in which a turbulent current does not occur (here, a maximum of 35°) even though an air flow rate increases in the front and rear portions of the diffuser part 9, a viscosity loss due to the turbulent current is suppressed and thus a pressure restoring effect at this portion may be maximized.
In addition, when the diffuser angles θ at the front and rear portions are the same while the air flow rate at both side portions of the diffuser part 9 is decreased, because the diffuser angle θ enlarges such that the air flow becomes unstable and a loss occurs.
In contrast, according to the present embodiment, since the diffuser angle θ at this portion is set to a small value (a minimum of 3°), the above-described unstable air flow may be suppressed and a pressure restoring effect due to the diffuser part 9 at this portion may also be maximized.
That is, in the diffuser part 9 according to the present embodiment, since a loss due to an unstable air current such as a dispersion of the suction flow rate is suppressed as much as possible, a pressure restoring effect is maximized, and a blowing efficiency may be dramatically increased.
In addition, since the maximizing of the pressure restoring effect denotes that a flow rate in the diffuser part 9 is decreased, a blowing noise reduction may also be obtained.
In addition, in the present embodiment, since the blowers 7 are installed in series and the diffuser angles θ at adjacent portions are set to be small values, an angle of an air current discharged therefrom becomes approximately vertical, Interference of the air currents exhausted from both of the blower 7 may be suppressed, and thus low noise blowing at high efficiency may be possible.
Because the above-described Dratio is set to 0.9 or less, a bending process of the top panel 51 is certainly possible at a position at which the outlet opening of the diffuser part 9 is closest to an edge of a top panel surface plate part 511, and thus the bent part 512 may be formed. Meanwhile, since Dratio is set to 0.6 or more, an equalization of a change ratio of the outlet opening of the diffuser part outlet (a change ratio of the diffuser angle θ along a circumferential direction) of the diffuser part defined by Dratio, an equalization of a flow change by reducing the change and improvement of noise performance may be obtained. In addition, a configuration related to this may also be applied to the top panel 51 having a rectangular shape as seen from the axis of rotation C.
Next, a modified example of the first embodiment will be described.
First, it is preferable that a diffuser angle be changed and an additional shape different from a circle be formed according to a shape of a downstream end opening of the diffuser part or, for example, a distribution of a suction flow rate. Since the distribution of the suction flow rate depends on at least an arrangement of internal apparatuses, it is preferable that, for example, a diffuser angle of the inclined surface positioned at a position at which the bell mouth parts are not vertically overlapped be set to be greater than the diffuser angle of the inclined surface positioned at a portion at which the internal apparatuses and the bell mouth part are vertically overlapped. Specifically, as illustrated in
In the embodiment, although the diffuser angle θ smoothly and continuously varies along the circumferential direction so as to suppress an occurrence of turbulence and the like as much as possible, the diffuser angle θ may also vary discontinuously. In this case, as illustrated in
Although, the diffuser angle θ is set to 35° as a maximum and 3° as a minimum in the embodiment, it is not limited thereto. For example, the maximum value may also be less than 35°, and the minimum value may also be more than 3°. Particularly, the diffuser angle θ of a side of an adjacent blower is preferably in the range of 3°≤θ≤7°.
The diffuser angle θ may be formed to be smoothly changed step-by-step or continuously toward a downstream side as seen from a cross-section parallel to an axis of rotation. In this case, an enlargement rate of the flow path of the diffuser part increases toward the downstream side.
In the embodiment, although a height of the downstream end of the propeller fan 71 and a height of an upstream end of the diffuser part 9 are matched when seen from a direction perpendicular to the axis of rotation C as illustrated in
A shape of the bell mouth duct is not limited to a cylindrical shape, and when the outer circumferential end of the propeller fan does not have a vertical shape, for example, the shape may be a partial cone shape corresponding thereto, or a noise prevention blade may be installed at the diffuser part. Such an example will be described in detail in a second embodiment.
The blower may not be limited to the outdoor unit, and may be used for various uses. For example, the blower may also be used for a blower having a ventilation fan or a blower connected to a duct for ventilation.
In addition, the blower is not limited to air and may obtain the same effect by being applied to a gas.
Next, a second embodiment of the present disclosure will be described. A blower 100 according to the present embodiment is formed by a resin injection mold, as illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
In addition, an intersection point of the major and minor axes of the diffuser part 12 and center of the stator part 2F is disposed on an axis of rotation of the propeller fan FN.
In addition, as illustrated in
As illustrated in
Here, in the bell mouth part 11 and the diffuser part 12, when a radius increase rate at a position from the upstream side to the downstream side along the shaft direction (a major axis radius and a minor axis radius) is compared, the radial increase rate of the diffuser part 12 is set to be bigger. That is, when seen in a longitudinal cross-section in
In addition, from the viewpoint of functions of the bell mouth part 11 and the diffuser part 12, the bell mouth part 11 is for improving a fluid pressure near the propeller fan FN, and the diffuser part 12 is for increasing a pressure of a vortex from the propeller fan FN.
As illustrated in an outer peripheral surface of the container-shaped molded object 1 in
Next, the molded blade part 2 will be described.
As illustrated in
As illustrated in
As illustrated in
As described above, since a length in a span direction or a shape of the noise prevention blade 22 is repeatedly changed every quarter when the noise prevention blades 22 are seen in turn from the circumferential direction in the stator part 2F, noise may be prevented from being generated in the noise prevention blade 22 with the same specific frequency. That is, by alternating frequencies having the highest peak in the noise prevention blades 22, a Blade Passage Frequency (BPF) noise level may be decreased. More specifically, as illustrated in a graph in
In addition, as illustrated in
As illustrated in an enlarged perspective view of
As illustrated in
Next, division lines L between the container-shaped molded object 1 and the molded blade part 2 of the blower 100 provided as described above will be described.
As illustrated with bold lines in
As described above, since the blower 100 according to the present embodiment has a complex structure in which the diffuser part 12 is formed at the downstream side of the bell mouth part 11 and the stator part 2F in which the shape of the noise prevention blade 22 is formed at an inner surface of the bell mouth part 11 is disposed in the diffuser part, a restoring pressure of fluid increases compared to a conventional technology, and thus the blowing efficiency may be significantly improved.
In addition, because the diffuser part 12 is installed at the downstream side of the bell mouth part 11, the downstream end of the diffuser part 12 is formed in the oval shape, and the noise prevention blade 22 is installed in the radial shape therein, first, speed of fluid which flows from the downstream end of the diffuser part 12 is decreased, and thus an entire noise level may be decreased. In addition, because lengths along the span direction or the shapes of the noise prevention blades are not the same and have a tiny difference between them and the vortex coming out from the propeller fan FN and the interference state of the noise prevention blade 22 are different from each other, noise intensively generated at a specific frequency may also be prevented. From that, blowing performance may be significantly improved and a noise level may also be decreased.
In addition, since the container-shaped molded object 1 is divided by the division line L, and the blower 100 includes the molded blade part 2, the noise prevention blades 22 of the diffuser part 12 and the stator part 2F are formed separately. Accordingly, the diffuser part 12 which has the complex shape for improving the blowing efficiency described above, has an enlarged flow path varying from the circular shape to the oval shape and a form in which the noise prevention blade 22 of the stator part 2F is formed up to the outer circumferential end 2E, and thus priority is given to such a complex structure while preventing manufacturability from being decreased.
More specifically, for example, when the outer circumferential end 2E of the noise prevention blade 22 is integrally injection-molded with the other members, only the outer circumferential end 2E is perpendicularly molded with respect to the shaft to be easily separated from the mold, and thus priority has been given to the manufacturability while blowing efficiency is sacrificed. In contrast to the above description, in the present embodiment, since each element is divided by the division line L, consideration of mold separation in the conventional technology may not be needed, and blowing efficiency may be improved by installing the convex surface 2C and the pressure surface 2P formed to be inclined toward the outer circumferential end 2E. In addition, since as illustrated in a top view illustrating the blower 100 in
As described above, because molding property of the noise prevention blade 22 for the container-shaped molded object 1 is not needed, the shape of the bell mouth part 11 which expands from the substantially circular shape to the oval shape may also be molded by a simple mold. In addition, since a direction of the vertical rib 15 may be arranged by a half surface, the container-shaped molded object 1 may be molded by a mold divided into two along a radius direction, and thus manufacturability may be improved.
In addition, since the bell mouth part 11 and the diffuser part 12 are not separately formed, but are integrally formed as the container-shaped molded object 1, the blower 100 includes only two elements of the container-shaped molded object 1 and the molded blade part 2, and thus blowing efficiency is improved as well as the number of elements may also be decreased.
In addition, the other embodiments will be described.
As illustrated in
In the above-described embodiment, although the stator part 2F is formed by installing the noise prevention blade 22 into the diffuser part 12 in a radial shape, for instance, the plurality of noise prevention blades 22 having a shape expanding straight along a long or minor axis may be installed. Such a structure may improve blowing efficiency and also suppress a noise from being intensively increased at a specific frequency by varying lengths of the noise prevention blades 22. Although the downstream end of the diffuser part 12 has an oval shape, for instance, the downstream end may have a polygonal shape close to a circle or oval. In this case, it is preferable that a central point of the downstream end of the diffuser part 12 be disposed on the rotation shaft line of the propeller fan FN.
Various modifications or embodiments except for the above-described embodiments may be combined without departing from the purposes of the present.
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WO2015/084030 | 6/11/2015 | WO | A |
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Chinese Office Action dated Jan. 3, 2020 in Chinese Patent Application No. 201810161062.9. |
Korean Office Action dated Feb. 28, 2020 in Korean Patent Application No. 10-2017-0062405. |
Indian Office Action dated Oct. 5, 2020 in Indian Patent Application No. 201818029076. |
European Office Action dated Jan. 12, 2021 from European Application No. 14868679.3, 9 pages. |
Japanese Office Action dated Jan. 18, 2022 from Japanese Application No. 2014-157177. |
Japanese Office Action dated Feb. 6, 2022 from Japanese Application No. 2014-049672. |
European Office Action dated Nov. 2, 2021 from European Application No. 17204460.4. |
Korean Notice of Allowance dated Jul. 28, 2021 from Korean Application No. 10-2021-0001774. |
International Search Report dated Feb. 26, 2015 from International Application No. PCT/KR2014/011715. |
Australian Office Action dated Oct. 25, 2017 from Australian Application No. 2014357992. |
Brazilian Office Action dated May 19, 2021 from Brazilian Application No. BR112016012519-3. |
Chinese Office Action dated Dec. 31, 2019 from Chinese Application No. 201780074746.5. |
Korean Notice of Allowance dated Apr. 29, 2018 from Korean Application No. 10-2017-0053670. |
Korean Notice of Allowance dated Dec. 30, 2020 from Korean Application No. 10-2017-0062405. |
Korean Notice of Allowance dated Jul. 28, 2021 from Korean Application No. 10-2017-0001748. |
Korean Notice dated Sep. 29, 2021 from Korean Application No. 10-2017-0001765. |
Korean Office Action dated Mar. 16, 2021 from Korean Application No. 10-2021-0001748. |
Korean Office Action dated Mar. 16, 2021 from Korean Application No. 10-2021-0001765. |
Korean Office Action dated Mar. 16, 2021 from Korean Application No. 10-2021-00017774. |
European Office Action dated May 4, 2022 from European Application No. 14868679.3. |
Chinese Office Action dated Jun. 1, 2022 from Chinese Application No. 201780074746.5. |
Chinese Office Action dated Dec. 13, 2021 from Chinese Application No. 201480074746.5. |
Brazilian Office Action dated Oct. 13, 2022 in Brazilian Patent Application No. BR122018012928-0 (3 pages: 6 pages English translation). |
European Office Action dated Dec. 20, 2022 in European Patent Application No. 14 868 679.3 (7 pages). |
Office Action dated Apr. 20, 2023 in European Patent Application No. 14 868 679.3 (5 pages). |
European Office Action dated May 12, 2023 in European Patent Application No. 17 204 460.4. |
Notice of Allowance dated Jan. 20, 2023 in Chinese Patent Application No. 201480074746.5 ( 4 pages; 3 pages English translation). |
Office Action dated Feb. 13, 2023 in Korean Patent Application No. 10-2021-0145364 ( 3 pages; 3 pages English translation). |
Korean Office Action dated Jun. 2, 2016 in corresponding Korean Patent Application No. 10-2014-0170184. |
U.S. Office Action dated Sep. 13, 2016 in corresponding U.S. Appl. No. 15/172,027. |
Korean Office Action dated Oct. 27, 2016 in corresponding Korean Patent Application No. 10-2014-0170184. |
Notice of Allowance dated Feb. 24, 2017 in corresponding Korean Patent Application No. 10-2014-0170184. |
Advisory Action dated May 4, 2017 in related U.S. Appl. No. 15/172,027. |
U.S. Office Action dated Feb. 16, 2017, in corresponding U.S. Appl. No. 15/172,027. |
U.S. Appl. No. 15/172,027, filed Jun. 2, 2016, Masaru Nakagawa, Samsung Electronics Co., Ltd. |
U.S. Office Action dated Jun. 23, 2017, in related U.S. Appl. No. 15/172,027. |
Extended European Search Report dated Jun. 23, 2017 in related European Patent Application No. 14868679.3. |
Russian Office Action and Search Report dated Jul. 19, 2017 in related Russian Patent Application No. 2016121624. |
Korean Office Action dated Jul. 2, 2017 in corresponding Korean Patent Application No. 10-2014-0170184. |
Number | Date | Country | |
---|---|---|---|
Parent | 15101387 | Dec 2014 | US |
Child | 16184166 | US |