1. Field of the Invention
The present invention relates to a serial axial fan.
2. Description of the Related Art
Electronic devices, such as personal computers (PCs) or servers, are commonly provided with a cooling fan for ventilation inside a case thereof and to cool electronic components contained therein. In particular, for use in comparatively large electronic devices such as servers, cooling fans that produce an air flow with high static pressure have been desired. One type of such cooling fans in current use are serial axial fans composed of two axial fans connected in series along a central axis such that impellers of the two axial fans rotate in opposite directions.
For example, in a serial axial fan described in JP-A-2008-95701, a vertical section of each blade of each impeller forms smaller angles with a rotational plane of the impeller at radially outward positions than at radially inward positions.
JP-A-2007-303432 discloses a counter-rotating blower in which a solidity ratio of a downstream axial fan in relation to an upstream axial fan is set in a range of 0.6 to 0.9. It is suggested that, according to this counter-rotating blower, setting a workload ratio of the downstream axial fan in relation to the upstream axial fan in a range of 0.6 to 0.9 will additionally reduce a decrease in air blowing efficiency.
Japanese Patent No. 4128194 discloses a counter-rotating axial blower in which an axial dimension of a first case provided in an inlet-side fan is larger than an axial dimension of a second case provided in an outlet-side fan.
JP-A 03-156193 discloses a counter-rotating ventilator in which a distance between a first impeller and a second impeller is set to 1.2 to 1.7 times an outer diameter of the impellers to achieve noise reduction.
The proportion of a workload of the impeller to a given power consumption is greatest at a radially outer portion of the impeller of axial fans. In the axial fan described in JP-A 2008-95701, the angle formed by each blade with the rotational plane of the impeller is arranged to be smaller at the radially outer portion thereof than at a radially inner portion thereof in order to increase air suction efficiency. This makes it difficult to generate most of work by the radially outer portion of the impeller.
A counter-rotating serial axial fan produces more noise than individual fans because of interference of blades of an inlet-side impeller and blades of an outlet-side impeller with each other. Accordingly, additional noise reduction is desired in accordance with an improvement in a “static pressure-air flow volume characteristic” of the serial axial fan.
Preferred embodiments of the present invention provide an improvement in the static pressure-air flow volume characteristic of serial axial fans and also to reduce an increase in noise.
According to a preferred embodiment of the present invention, a serial axial fan including a first axial fan and a second axial fan connected to the first axial fan along a central axis of the first axial fan is provided. The first axial fan preferably includes a first motor portion; a first impeller having a plurality of first blades extending radially outward to be centered about the central axis and arranged at regular intervals in a circumferential direction, and arranged to rotate about the central axis due to action of the first motor portion to produce an air flow along the central axis and toward the second axial fan; and a first housing surrounding an outer circumference of the first impeller. The second axial fan preferably includes a second motor portion; a second impeller having a plurality of second blades extending radially outward to be centered about the central axis and arranged at regular intervals in the circumferential direction, and arranged to rotate about the central axis due to the action of the second motor portion in an opposite direction to that in which the first impeller rotates, to produce an air flow in the same direction as that of the air flow produced by the first impeller; and a second housing surrounding an outer circumference of the second impeller. In the first impeller, an angle formed by a rotational plane of the first impeller with a chord of each first blade on an imaginary cylindrical surface centered about the central axis increases as a radius of the imaginary cylindrical surface increases.
Other features, elements, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the present invention with reference to the attached drawings.
In the following description, an upper side with respect to a direction parallel or substantially parallel to a central axis J1 will be referred to simply as an “upper side”, “above”, etc., whereas a lower side with respect to the direction parallel or substantially parallel to the central axis J1 will be referred to simply as a “lower side”, “below”, etc. Note that terms referring to “upward”, “downward”, “left”, “right”, etc., as used in the description of the present invention to describe relative positions or directions of different members are simply used with reference to the accompanying drawings, and should not be construed as describing relative positions or directions of those members when actually installed in a device.
In the serial axial fan 1 as illustrated in
The first axial fan 2 preferably includes a first impeller 21, a first motor portion 22, a first housing 23, a first base portion 24, and a plurality of first support ribs 25. The first motor portion 22 causes the first impeller 21 to rotate about the central axis J1. The first housing 23, shown in section, surrounds an outer circumference of the first impeller 21. The first base portion 24 is arranged to be adjacent to the second axial fan 3 and to support the first motor portion 22. The first support ribs 25 join the first base portion 24 to the first housing 23. In the present preferred embodiment, the number of first support ribs 25 is preferably four, but any desirable number of support ribs could be used. The first housing 23, the first base portion 24, and the first support ribs 25 are preferably produced by resin injection molding as a single integral member, but could be made from separate pieces or by any other suitable method.
The first impeller 21 is arranged to produce a flow of air toward the second axial fan 3 along the central axis J1. The first impeller 21 preferably includes a cup 212, which is substantially defined by the shape of a covered cylinder, and a plurality of first blades 211. The cup 212 covers a rotating portion of the first motor portion 22. In the present preferred embodiment, the number of first blades 21 is preferably five, but any desirable number of first blades 21 could be used. The cup 212 and the first blades 211 are preferably produced by resin injection molding as a single integral member, but could be made from separate pieces or by any other suitable method.
The structure of the second axial fan 3 is substantially similar to that of the first axial fan 2 but turned upside down. The second axial fan 3 preferably includes a second impeller 31, a second motor portion 32, a second housing 33, a second base portion 34, and a plurality of second support ribs 35. The second motor portion 32 causes the second impeller 31 to rotate about the central axis J1. The second housing 33 surrounds an outer circumference of the second impeller 31, and is connected to the first housing 23 along the central axis J1. The second base portion 34 is preferably substantially disc-shaped, and centered on the central axis J1, and supports the second motor portion 32. The second base portion 34 is in contact with the first base portion 24, which is also preferably substantially disc-shaped. The second support ribs 35 join the second base portion 34 to the second housing 33. In the present preferred embodiment, the number of second support ribs 35 is four, but any desirable number of support ribs could be used. The second housing 33, the second base portion 34, and the second support ribs 35 are produced by resin injection molding as a single integral member, but could be made from separate pieces or by any other suitable method.
The second impeller 31 includes a cup 312 and a plurality of second blades 311. The cup 312 covers a rotating portion of the second motor portion 32. In the present preferred embodiment, the number of second blades 311 is five, but any desirable number of second blades could be used. The cup 312 and the second blades 311 are produced by resin injection molding as a single integral member however, but could be made from separate pieces or by any other suitable method. The axial dimension, i.e., the dimension along the central axis J1, of the second impeller 31 is preferably smaller than that of the first impeller 21. In other words, the height H1, i.e., the dimension along the central axis J1, of the first blades 211 is greater than the height H2 of the second blades 311.
According to
In the second axial fan 3, the second motor portion 32 causes the second impeller 31 to rotate about the central axis J1 in a direction opposite to the direction in which the first impeller 21 rotates. This results in a flow of air in the same direction as that of the air flow produced by the rotation of the first impeller 21 along the central axis J1, whereby the air is sent downward out of the serial axial fan 1.
The term “chord” as used herein in reference to the blades of the impellers is defined as follows. First, the section of the blade taken on the imaginary cylindrical surface centered about the central axis of the impeller is developed on a plane. Next, the leading and trailing edges of the blade are joined by a straight line in the section developed on the plane. This straight line is defined as a “chord”. This definition of the term “chord” complies with common blade terminology.
As shown in
Meanwhile, the length of the chords L1 to L4 also increases as the radial position thereof moves outward. The dimension (i.e., height) of the first blade 211 in the direction parallel or substantially parallel to the central axis J1, across its width between the leading and trailing edges 2111 and 2112, also increases in a radially outward direction.
Moreover, as illustrated in
Regarding the second blades 311 as illustrated in
Axial fans having the above-described blade shape and used singly generally suffer an increase in a whirl component of exiting air resulting in a substantial amount of air being blown radially outward, and thus leading to a decrease in static pressure. In the serial axial fan 1, however, a whirl component of the air produced by the first axial fan 2 can be converted in the second axial fan 3 into an airflow traveling in an axial direction, as described below. This contributes to improving a “static pressure-air flow volume characteristic” while increasing a workload of the radially outer portion of the blades for a given power consumption.
The solid line in
The broken line in
The serial axial fan 1, in which the angle defined by the radially outer portion of each first blade 211 with the rotational plane of the corresponding impeller is large, accordingly suffers an increase in the whirl component of the air flow produced by the first blades 211. However, the second axial fan 3 in the serial axial fan 1 serves to convert the whirl component into the airflow traveling in the axial direction, thereby preventing a reduction in the static pressure. Because of this, as illustrated in
In
Hereinafter, the ratio (c1/t1) of the chord length c1 of the first blade 211 to the pitch t1 of the first blades 211 at a given radial position will be referred to as a “first solidity”. In addition, the ratio (c2/t2) of the chord length c2 of the second blade 311 to the pitch t2 of the second blades 311 at the same radial position will be referred to as a “second solidity”. In designing the first and second impellers 21 and 31, several radial positions are specified as reference positions. The shapes of the first and second blades 211 and 311 are determined such that the first solidity is greater than the second solidity at each of the reference positions.
As a result, in the serial axial fan 1, the first solidity is greater than the second solidity at almost every radial position. Hereinafter, the above-described relationship between the two impellers will be expressed as “the first solidity being greater than the second solidity”. Note here that the first solidity may not necessarily be greater than the second solidity at every radial position. The first solidity may be less than the second solidity at some radial positions, such as a top of the blades or a base of the blades near the cup, for example. In other words, the first solidity need only be greater than the second solidity for most of the first and second blades 211 and 311.
The solid line in
The broken line in
As illustrated in
The solid line in
The broken line in
As illustrated in
Referring to
The results of the measurement as indicated in
As described above, in the serial axial fan 1, the static pressure-air flow volume characteristic can be improved while reducing an increase in noise since the first solidity is greater than the second solidity and the number of first blades 211 is equal to the number of second blades 311. It is preferable that the diameter of the first and second impellers 21 and 31 be in the range of approximately 25 mm to approximately 200 mm inclusive, and that the inter-blade distance d be in the range of approximately 23 mm to approximately 30 mm inclusive, in order to further reduce the increase in noise.
Moreover, the fact that the angle defined by the chord of each of the first and second blades 211 and 311 with the rotational plane of the corresponding impeller increases as the radial position of the chord moves outward contributes to improving air blowing efficiency of the serial axial fan 1. Since the first and second housings 23 and 33 of the serial axial fan 1 are separate members, it is possible to construct each axial fan independently with ease.
As with the first blade 211 as illustrated in
In the serial axial fan 1a, the whirl component of air produced by the first axial fan 2 can be converted in the second axial fan 3 into an airflow traveling in the axial direction. This contributes to improving the static pressure-air flow volume characteristic while increasing a workload on the radially outer portion of the blades for a given power consumption.
While preferred embodiments of the present invention have been described above, it should be appreciated that the present invention is not limited to the above-described preferred embodiments, and that various variations are possible.
For example, as long as a sufficient static pressure-air flow volume characteristic is obtained, the angle defined by the chord of each second blade 311 of the second impeller 31 with the rotational plane of the impeller may decrease as the radial position of the chord moves outward in other preferred embodiments of the present invention.
The first and second base portions 24 and 34 of the serial axial fan 1 or la may not necessarily be in contact with each other. The first and second base portions 24 and 34 may be merely arranged in proximity to each other in other preferred embodiments of the present invention. Further, the first and second axial fans 2 and 3 may not necessarily be oriented in opposite directions so that they are arranged back to back with each other. For example, the second support ribs 35 of the second axial fan 3 may be arranged on an outlet side, or the first support ribs 25 of the first axial fan 2 may be arranged on an inlet side in other preferred embodiments of the present invention.
The first and second base portions 24 and 34 may not necessarily be arranged opposite to each other. For example, the first base portion 24 and the first support ribs 25 of the first axial fan 2 may be arranged on the inlet side, or the second base portion 34 and the second support ribs 35 of the second axial fan 3 may be arranged on the outlet side in other preferred embodiments of the present invention.
The number of first blades 211 and the number of second blades 311 are not limited to five. For example, the number of first blades 211 and the number of second blades 311 may be seven in other preferred embodiments of the present invention. The number of fans provided in the serial axial fan 1 or la may be greater than two. For example, an additional axial fan may be provided on the outlet side of the second axial fan 3 or on the inlet side of the first axial fan 2, or both on the outlet side of the second axial fan 3 and on the inlet side of the first axial fan 2 in other preferred embodiments of the present invention.
Preferred embodiments of the present invention are usable as cooling fans to cool electronic devices or the like, and also as other types of fans than the cooling fans.
While preferred embodiments of the present invention have been described above, it is to be understood by those skilled in the art that variations and modifications can be made without departing from the scope and spirit of the present invention. The scope of the present invention is therefore to be determined solely by the following claims.
Number | Date | Country | Kind |
---|---|---|---|
2008-224265 | Sep 2008 | JP | national |
2008-269522 | Oct 2008 | JP | national |