The present invention relates to a centrifugal blower provided with a scroll casing for automobile air-conditioning use.
A centrifugal blower used in an air-conditioning system for automobile use is, for example, disclosed in Japanese Unexamined Patent Publication No. 2004-360497.
Such a conventional centrifugal blower is provided with a multi-blade fan 16 having a large number of blades 2, a motor 34 to an output shaft 33 of which this multi-blade fan 16 is attached, and a casing 31 housing the multi-blade fan 16 inside it and having a scroll chamber 30 formed in a spiral shape at an outer circumferential side of the multi-blade fan. The scroll chamber 30 is formed in a spiral shape which starts from a nose portion 1a of the casing 31 and gradually expands in passage toward the air outlet. In general, the center of rotation O of the multi-blade fan forms the center point of the scroll chamber. When the nose portion 1a is an arc shape, strictly speaking, the position showing the center of curvature of the nose portion 1a is the spiral start part (starting point of spiral casing). The starting point of the circumferential direction angle φ with respect to the center O is the center of curvature of the nose portion 1a. The nose portion is not limited to an arc shape. Here, the explanation will be given deeming the nose portion end part as a spiral start part.
The casing 31 has an air inlet 13 at one surface of the multi-blade fan 16 in the axial direction. When the motor 34 rotates, the multi-blade fan 16 sucks in air from the air inlet 13 to the center part of the multi-blade fan 16. The air is sucked into the center part of the multi-blade fan, then is given kinetic energy (dynamic pressure) by this multi-blade fan, has part of the dynamic pressure converted to static pressure in the casing while passing through the scroll chamber 30, and is discharged from the air outlet.
In this prior art, it is possible to reduce noise accompanying the formation of backflow near the nose portion 16. That is, the starting point 21a of the step 21 matches the spiral start part (that is, the circumferential direction angle φ (see
The prior art aimed at reduction of the noise accompanying the formation of backflow, but provided a step for sharply expanding the shape of the bottom of the scroll chamber and sharply expanded the scroll chamber passage. For this reason, a sufficient noise reduction effect could not be obtained. The “backflow phenomenon” expresses the phenomenon where part of the flow in the case enters between the blades.
On the other hand, the prior art shown in Japanese Patent No. 3231679 prevents backflow occurring largely near the nose portion by a plate and thereby suppresses a drop in blower efficiency and suppresses the generation of noise due to this backflow.
The prior art shown in this Japanese Patent No. 3231679 provides a plate 3′ having a slanted part facing a main plate side 110 from a side plate side 109 of the multi-blade fan 16 in the axial direction of the air inlet 13 and has a maximum length part at the inside of the nose portion 1a. The distribution of peripheral speed in the direction of the electric motor shaft 33 at the outer circumference of the multi-blade fan 16 is not uniform (see Japanese Patent No. 3231679,
The plate 3′ at Japanese Patent No. 3231679, as shown in
This section provides a general summary of the disclosure, and is not a comprehensive disclosure of its full scope or all of its features.
The present invention was made in consideration of the above problem and provides a centrifugal blower provided with a scroll casing for automobile air-conditioning use which is effective for reducing the noise level.
To solve this problem, a centrifugal blower is provided with a multi-blade fan comprised of a large number of blades arranged in a circumferential direction at fixed intervals to form a fan wheel and of an air inlet provided upward in an axial direction of the fan wheel, the multi-blade fan having a fan outlet angle of the multi-blade fan in the range of an angle of 20° to 75° and having a fan wheel diameter in the range of 0.05 to 0.15D when an outside diameter of the multi-blade fan is D, and with a scroll chamber around the multi-blade fan surrounded by a spiral shaped casing which has an expansion angle of the spiral of an angular range of 2° to 6° from a spiral start part as the starting point, the spiral shaped scroll chamber having a chamber bottom part of the scroll chamber which gradually expands downward in the axial direction together with the expansion of the spiral and having a flow area which gradually increases toward an air outlet from the spiral start part, an initial slant angle θ0 downward in the axial direction at the spiral start part of the chamber bottom part being a range of angle of 5.2° to 27.5°.
Due to this, it is possible to change the shape of the chamber bottom part so as to improve the flow between blades and eddy formation and guide backflow well to the chamber bottom part so as to prevent the entry of an air flow between blades causing noise. Further, backflow is prevented and the formation of an eddy at the chamber bottom part is reduced, so the effect is obtained of reduction of the noise level and improvement of the fan efficiency.
The chamber bottom part is comprised of a slanted cross-sectional shape changing part as a boundary and a sharply slanted chamber bottom part from the spiral start part to the slanted cross-sectional shape changing part and a gently slanted chamber bottom part from the slanted cross-sectional shape changing part to the air outlet, the slanted cross-sectional shape changing part having an angle formed, with respect to an axis of the fan wheel, from the spiral start part to the circumferential direction of a range of angle of 30 to 60° and being positioned downward in the axial direction from the position of the chamber bottom part at the spiral start part within a range of 0.2 to 0.5H with respect to the fan wheel total height H of the multi-blade fan. Due to this, effects similar to the aspect of the invention according to claim 1 are obtained.
The sharply slanted chamber bottom part is comprised of a plurality of straight cross-sectional shapes. Due to this, it is possible to make the change in flow at the slanted cross-sectional shape changing part smoother.
The sharply slanted chamber bottom part is comprised of a curved cross-sectional shape. Due to this, it is possible to make the change in flow at the slanted cross-sectional shape changing part smoother.
A width W1 of a top surface of the scroll chamber is smaller than a width W2 of the chamber bottom part at any angle formed from the spiral start part to the circumferential direction with respect to an axis of the fan wheel from the spiral start part to the air outlet. Due to this, the flow toward the bottom becomes stronger, the flow toward the top becomes weaker, and the backflow no longer flows between the blades. For this reason, impact with the intake air flow is eliminated, so the noise level also becomes lower.
A centrifugal blower is provided with a multi-blade fan comprised of a large number of blades arranged in a circumferential direction at fixed intervals to form a fan wheel and an air inlet provided upward in an axial direction of the fan wheel, the multi-blade fan having a fan outlet angle of the multi-blade fan in the range of an angle of 20° to 75° and having a fan wheel diameter in the range of 0.05 to 0.15D when an outside diameter of the multi-blade fan is D, and with a scroll chamber surrounded, around the multi-blade fan, by a spiral shaped casing which has an expansion angle of the spiral of an angular range of 2° to 6° from a spiral start part as a start point, the spiral shaped scroll chamber having a chamber bottom part of the scroll chamber which gradually expands downward in the axial direction together with the expansion of the spiral and having a flow area which gradually increases toward the air outlet from the spiral start part, a backflow prevention rib being arranged at the scroll chamber at a top end of the fan outlet and with an angle formed from the spiral start part to the circumferential direction centered at the axis of the fan wheel of near 0° to 45° in range, a maximum width of the backflow prevention rib being made 0.1 to 0.3h1 in range with respect to a fan outlet length h1 measured from the top end of the fan outlet downward in the axial direction, the backflow prevention rib being provided separated by a predetermined distance from the fan outlet.
The backflow prevention rib 3 is set at the outlet side, so it is possible to prevent in advance any flow entering between the blades and thereby reduce the noise and increase the fan efficiency.
The angle formed by the maximum width of the backflow prevention rib with respect to the circumferential direction is a range of angle of 5° to 25°. Due to this, it is possible to suppress the backflow which often occurs in a range of an angle φ of 5° to 25°. This is much more effective for reduction of the noise level and increasing the efficiency of the fan.
At any angle of the angle formed by the circumferential direction, a width W1 of a case top surface of the scroll chamber is smaller than a width W2 of a case bottom surface of the chamber bottom part. Due to this, even when backflow easily occurs due to the width W1 of the case top surface, it is possible to prevent disturbance in the flow.
A centrifugal blower is provided with a multi-blade fan comprised of a large number of blades arranged in a circumferential direction at fixed intervals to form a fan wheel and an air inlet provided upward in an axial direction of the fan wheel, the multi-blade fan having a fan outlet angle of the multi-blade fan in the range of an angle of 20° to 75° and having a fan wheel diameter in the range of 0.05 to 0.15D when an outside diameter of the multi-blade fan is D, and with a scroll chamber surrounded, around the multi-blade fan, by a spiral shaped casing which has an expansion angle of the spiral of an angular range of 2° to 6° from a spiral start part as a start point, the spiral shaped scroll chamber having a chamber bottom part of the scroll chamber which gradually expands downward in the axial direction together with the expansion of the spiral and having a flow area which gradually increases toward the air outlet from the spiral start part, a backflow prevention rib being arranged at the scroll chamber at a top end of the fan outlet in a range from 45° (−45°) to one side of the circumferential direction to 45° (+45°) to the other side of the circumferential direction from the spiral start part as the starting point (0°) centered about the axis of the fan wheel, a maximum width of the backflow prevention rib being made 0.1 to 0.3h1 in range with respect to a fan outlet length h1 measured from the top end of the fan outlet downward in the axial direction, the backflow prevention rib being provided separated by a predetermined distance from the fan outlet.
Due to this, it is possible to prevent the air flow discharged from the multi-blade fan in the scroll chamber from striking the wall surfaces of the casing, striking the top of the fan wheel in the axial direction, or entering between the blades and possible to remarkably improve the noise level and the fan efficiency in the entire region of the range of use of the blower.
For the scroll chamber, a distance L1 between the fan outlet tip and the inner wall surface of the casing at the chamber bottom part of the spiral start part is 0.14D to 0.25D when the outside diameter of the multi-blade fan is D.
The backflow prevention rib has a trapezoid shape having the maximum width as its height, a bottom base of the trapezoid shape is formed at a top end of the fan outlet in a range from 45° (−45°) to one side of the circumferential direction to 45° (+45°) to the other side of the circumferential direction from the spiral start part as the starting point (0°) centered about the axis of the fan wheel, and two end points of the top base of the trapezoid shape are respectively provided in a range of 25° (−25°) to 5° (−5° to one side of the circumferential direction and in a range of 5° (+5°) to 25° (+25°) to the other side of the circumferential direction from the spiral start part as the starting point (0°) centered about the axis of the fan wheel. Due to the large backflow in these ranges, a remarkable noise reduction effect is obtained.
Two multi-blade fans are joined at an opposite side from the air inlet.
Two multi-blade fans are joined at an opposite side from the air inlet.
Note that the above reference notations are examples showing the correspondence with specific embodiments explained later.
Further areas of applicability will become apparent from the description provided herein. The description and specific examples in this summary are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.
Corresponding reference numerals indicate corresponding parts throughout the several views of the drawings.
Example embodiments will now be described more fully with reference to the accompanying drawings.
Below, referring to the drawings, embodiments of the present invention will be explained. In the embodiments, parts of the same constitutions are assigned the same notations and explanations are omitted. Parts of the same constitution with respect to the prior art as well are also assigned the same notations and explanations are omitted.
The centrifugal blower is provided with a multi-blade fan 16 which has a large number of blades 2, a motor 34 to which this multi-blade fan 16 is attached, and a casing 31 which houses the multi-blade fan 16 inside of the casing 31 and which has a scroll chamber 30 formed in a spiral shape at an outer circumference side of the multi-blade fan. The multi-blade fan referred to here is also called a “sirocco fan”. The casing 31 having the scroll chamber 30 is called a “scroll casing”.
The casing 31 has an air inlet 13 at the surface of one side of the multi-blade fan 16 in the axial direction. If the motor 34 turns, the multi-blade fan 16 sucks in air from the air inlet 13 to the center part of the multi-blade fan 16. At the centrifugal blower, air is sucked into the center part of the multi-blade fan, then is given kinetic energy (dynamic pressure) by this multi-blade fan, has part of the dynamic pressure converted to static pressure in the casing while passing through the scroll chamber 30, and is discharged from the air outlet 20.
In a centrifugal blower in an embodiment of the present invention, the shape of the spiral forming the scroll casing has a spiral expansion angle of a range of angle of 2° to 6° from the spiral start part 1a as the starting point. The “expansion angle of the spiral” is explained as a logarithmic spiral function etc. (for example, see Japanese Unexamined Patent Publication No. 2004-270577, paragraph 0033, Japanese Unexamined Patent Publication No. 2003-193998, paragraph 0045, which corresponds to paragraph [0067] of US 2003/0012649 A1 etc.)
A large number of blades 2 are arranged in the circumferential direction at fixed intervals to form a fan wheel. An air inlet 13 is provided upward in the axial direction of the fan wheel. The “fan wheel” indicates, among the parts of the multi-blade fan 16, the part comprised of the large number of blades 2 arranged in the circumferential direction at fixed intervals in parallel in a cylindrical shape. The “axis of the fan wheel” indicates the center of rotation O of the multi-blade fan 16 (also called “axis of rotation O”). The electric motor 34 is a drive means for driving rotation of the multi-blade fan 16. This electric motor 34 is fixed in the casing 31, housing the multi-blade fan 16. In
The casing 31 is formed in a substantially spiral shape so that a center axis O of the multi-blade fan 16 is positioned at the center axis L of the scroll chamber. At one end side of the casing 31 in the axial direction of the axis of rotation O (opposite side of the motor 34, here, referred to as “upward”), the air inlet 13 is formed for introduction of air. At the external edge of this air inlet 13, a bell mouth is provided for guiding the intake air smoothly to the multi-blade fan 16.
Up until now, it has been known that the cause of noise in a centrifugal blower was the interference at the scroll casing between the backflow air and intake air flow occurring near the spiral start part. In the present invention, the inventors researched in detail the backflow between blades and took note of the fact that the source of noise accompanying backflow is mainly the flow between blades.
In the case of
Further, it was learned that the casing shape, in particular the shape of the chamber bottom part of the scroll chamber 30, can be further changed from the previous prior art to improve the flow between the blades. Below, the chamber bottom part of the scroll chamber 30 formed in a spiral shape at the outer circumferential side of the multi-blade fan will be explained with reference to
In an embodiment of the present invention, the chamber bottom parts 14 and 11 are comprised of a slanted cross-sectional shape changing part 2a as a boundary and a sharply slanted chamber bottom part 14 from the spiral start part 1a to the slanted cross-sectional shape changing part 2a and a gently slanted chamber bottom part 11 from the slanted cross-sectional shape changing part 2a to the air outlet 20.
Further, the initial slant angle θ0 in the spiral start part 1a of the chamber bottom parts 14 and 11 (if expressed as one way, at the inside of the scroll chamber 30, the angle formed by the vertical plane with respect to the axis of rotation O at the inside cylindrical wall surface 40 near the chamber bottom part 14 when projecting and developing the chamber bottom part, see θ0 of
In an embodiment of the present invention, when the circumferential direction angle of the “slanted cross-sectional shape changing part 2a” from the spiral start part 1a is φ (measured about axis of rotation O), the circumferential direction angle φ of “the slanted cross-sectional shape changing part 2a” may be made a range of angle of 30° to 60 from the spiral start part 1a to the circumferential direction and “the slanted cross-sectional shape changing part 2a” may be made a position of a range (H2) within 0.2 to 0.5H with respect to the fan wheel total height H of the multi-blade fan downward in the axial direction from the position at the chamber bottom part of the spiral start part 1a.
The framework by which the generation of noise is suppressed in the above embodiment will be explained next.
In this example of an embodiment of the present invention, the slanted cross-sectional shape changing part 2a has a φ of 45°. The embodiment of
The air flow discharged from the multi-blade fan 16 strikes the nose portion and is rapidly changed in direction of flow, but due to the effect of the sharply slanted chamber bottom part 14, the flow is guided to the bottom direction whereby entry between the blades, the cause of noise, is prevented. As a result of research by the inventors, it has been learned that if quantitatively measuring the flow between blades, the effect of backflow is felt and noise is generated between blades in a specific range (0 to 45°). It is learned that in the flow inside the casing, the peripheral speed component accompanying rotation of the multi-blade fan is the largest. To prevent backflow between the blades, the cause of noise, due to this peripheral speed component, it was confirmed by experiments that a position of the slanted cross-sectional shape changing part 2a of 30° to 60° in range gives a particularly large effect. If φ=0 to 30°, a change ends up occurring in the sharp flow to the chamber bottom part, so the performance is no good. Further, if φ=60° or more, it is not possible to guide the backflow well to the case bottom and no effect arises.
The modification of the embodiment of the present invention shown in
Below, referring to
The casing 31 has an air inlet 13 at one surface of the multi-blade fan 16 in the axial direction. If the motor 34 rotates, the multi-blade fan 16 sucks in the air from the air inlet 13 to the center part of the multi-blade fan 16. In the centrifugal blower, the air is sucked into the center part of the multi-blade fan, then is given kinetic energy (dynamic pressure) by this multi-blade fan, has part of the dynamic pressure converted to static pressure inside of the casing while passing through the scroll chamber 30, and is discharged from the air outlet 20.
In the centrifugal blower in the other embodiment of the present invention, the spiral forming the scroll casing is shaped with an expansion angle of the spiral of a range of angle of 2° to 6° from the spiral start part 1a as the starting point. A large number of blades 2 are arranged in the circumferential direction at constant intervals to form a fan wheel. The air inlet 13 is provided in the axial direction of the fan wheel. The electric motor 34 is a drive means for driving rotation of the multi-blade fan 16. This electric motor 34 is fixed to the casing 31 housing the multi-blade fan 16.
As shown in
The casing 31 is formed in a substantially spiral shape so that the axis of rotation O of the multi-blade fan 16 is positioned at the center axis L of the scroll chamber.
At one end of the casing 31 in the axial direction of the axis of rotation O (opposite side from motor 34, here, referred to as “upward”), an air inlet 13 is formed for introducing air. At the outer edges of this air inlet 13, a bell mouth is provided which guides intake air smoothly to the multi-blade fan 16. The center axis L of the scroll chamber and the axis of rotation O of the multi-blade fan 16 match.
If the multi-blade fan 16 sucks in air from the air inlet 13 to the center part of the multi-blade fan 16, the air is sucked into the center part of the multi-blade fan, then is given kinetic energy (dynamic pressure) by this multi-blade fan and is discharged from the fan outlet (outlet of blades 2) to the scroll chamber 30.
The chamber bottom part of the scroll chamber 30, formed in a spiral shape at the outer circumference side of the multi-blade fan, will be explained with reference to
W2 indicates the width of the chamber bottom part 101 of the scroll chamber 30 in the radial direction of the multi-blade fan 16 (also referred to as the “width of the case bottom surface”), while W1 indicates the distance between the outlet tips T of the blades 2 (outermost circumference of multi-blade fan 16) and the outermost circumference inner surface of the top surface 10 of the scroll chamber 30 or the width of the top surface of the scroll chamber 30 (also referred to as the “width of the case top surface”). The widths W1 and W2 of the case top surface and case bottom surface of the scroll chamber 30 may be made the same or different.
Next, the backflow prevention rib 3 will be explained. In the other embodiment of the present invention, at the top end of the fan outlet, the backflow prevention rib 3 is set in the casing 31 forming the scroll chamber 30 over a range of an angle φ from the spiral start part 1a to the circumferential direction centered about the axis of the fan wheel of near 0° to 45°. “Near 0°” indicates a range of around 0° to 2 or 3°. At the very least, a range of 0° to 45° may be included. Further, the maximum width h2 of the backflow prevention rib 3, measured from the top end of the fan outlet downward in the axial direction, is made a range of 0.1 to 0.3h1 with respect to the fan outlet length h1. As shown in
The W in
In the other embodiment of the present invention, the widths W1 and W2 of the top surface and bottom surface of the scroll chamber 30 may be made different. In the other embodiment of the present invention, as shown in
Next, another embodiment of the present invention will be explained.
In the other embodiment of the present invention, as shown in
The inventors visually analyzed the flow in the casing 31 and the flow between blades and accumulated further research findings. As a result, they learned that the range in which the noise level rises due to backflow is ±45 degrees from the spiral start 0 degree. According to the present embodiment, it is possible to prevent the air flow discharged from the multi-blade fan 16 from striking the wall surfaces of the casing 31 in the scroll chamber 30, or from striking the top of the fan wheel in the axial direction, or to prevent entry of backflow between the blades. In the entire range of use of the blower, it is possible to improve the noise to 0.8 dB and the efficiency to 1.5 pt.
If the maximum width h2 of the backflow prevention rib 3, measured downward in the axial direction from the top end of the fan outlet, is in a range of 0.1 to 0.3h1 with respect to the fan outlet length h1, a greater effect is exhibited. If 0.1h1 or less, the effect is reduced and the backflow ends up entering between the blades. Further, if 0.3h1 or more, the performance in obstructing and interfering with the air flow discharged from the multi-blade fan 16 and the noise level may both deteriorate.
In the scroll chamber 30, in the chamber bottom part 101 of the spiral start part 1a, the distance L1 between the fan outlet tips T and the inner wall surface of the casing 31 (see
As shown in
In the embodiments of
The above embodiments of the backflow prevention rib 3 of the present invention may be applied to a two-layer inside/outside air air-conditioning unit comprised of two multi-blade fans 16 joined at an opposite side from the air inlet 13.
The foregoing description of the embodiments has been provided for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosure. Individual elements or features of a particular embodiment are generally not limited to that particular embodiment, but, where applicable, are interchangeable and can be used in a selected embodiment, even if not specifically shown or described. The same may also be varied in many ways. Such variations are not to be regarded as a departure from the disclosure, and all such modifications are intended to be included within the scope of the disclosure.
Number | Date | Country | Kind |
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2010-193541 | Aug 2010 | JP | national |
2010-195772 | Sep 2010 | JP | national |
2011-111261 | May 2011 | JP | national |
This application is a divisional of U.S. patent application Ser. No. 13/199,400 filed on Aug. 29, 2011. This application claims the benefit and priority of Japanese Serial No. 2011-111261, filed May 18, 2011, Japanese Serial No. 2010-195772, filed Sep. 1, 2010, and, Japanese Serial No. 2010-193541 filed Aug. 31, 2010. The entire disclosures of each of the above applications are incorporated herein by reference.
Number | Date | Country | |
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Parent | 13199400 | Aug 2011 | US |
Child | 14956832 | US |