This application is a U.S. National Phase Application under 35 U.S.C. 371 of International Application No. PCT/JP2015/000392 filed on Jan. 29, 2015 and published in Japanese as WO 2015/136829 A1 on Sep. 17, 2015. This application is based on and claims the benefit of priority from Japanese Patent Application No. 2014-051818 filed on Mar. 14, 2014. The entire disclosures of all of the above applications are incorporated herein by reference.
The present disclosure relates to a structure of centrifugal multiblade blower rotated by an electric motor, in particular, to a structure of an impeller of the centrifugal multiblade blower.
Patent Literature 1 describes a centrifugal multiblade blower such as sirocco fan or turbo fan. The blower is equipped with an electric motor and an impeller rotated by the electric motor to blow off air outward in a radial direction.
The impeller has plural blades arranged around a rotation shaft of the electric motor, and a main plate holding the blades and transmitting the rotation power generated by the electric motor to the blades. The main plate has a main part in which plural penetration holes are arranged in the circumferential direction, and a blockade part closing the penetration holes. In the blower of Patent Literature 1, noise resulting from the penetration hole of the main plate is restricted, and water is prevented from entering the electric motor through the penetration hole of the main plate.
Patent Literature 1: JP 2010-53814 A
A passage through which air flows from the blower is generally made of resin material and rubber material. A piping forming the passage is mainly made of, for example, resin material, and a sealing material in the passage is mainly made of rubber material. Moreover, an electric motor with a brush is adopted as a drive source of the blower in many cases, and copper powder which is wear powder is generated from the brush and a commutator of the electric motor. The copper powder flows with the air from the blower, and adheres to the resin material or the rubber material downstream of the blower in the air flow.
It is well-known that resin material and rubber material deteriorate if in contact with metal, in particular, copper. The degradation in resin material and rubber material resulting from copper is called as copper harm. The copper harm will be generated if copper powder flowing out of the blower as mentioned above adheres to resin material or rubber material. The copper harm is one of the issues in an air-conditioner for a vehicle where the blower of Patent Literature 1 is used.
It is possible to implement a measure of improving the resin material and the rubber material, which are affected by the copper powder, to withstand the copper harm. However, in order to implement such a measure, it will be necessary to add an additive to the resin material for improving the property withstanding the copper harm. The addition of additive causes a cost rise, for example, in resin material. Inventors, on the other hand, discover a phenomenon in which the wear powder adheres to a main plate of an impeller, and study to increase wear powder caught by the main plate in order to reduce wear powder flowing to the downstream of the impeller in the air flow.
The present disclosure has an object to provide a centrifugal multiblade blower in which copper powder is restricted from flowing downstream of the impeller in a flow of air by the main plate of the impeller that can catch copper powder flowing from the electric motor with the brush.
According to an aspect of the present disclosure, a centrifugal multiblade blower includes: an electric motor having a motor rotation shaft that rotates at a motor axial center, a commutator that rotates with the motor rotation shaft, and a brush in contact with the commutator; and an impeller having a main plate connected with the motor rotation shaft to rotate integrally with the motor rotation shaft, and a plurality of blades connected with the main plate and arranged around the motor axial center. The impeller blows off air outward in a radial direction by being rotated by the electric motor.
The main plate has one surface adjacent to the electric motor in a thickness direction of the main plate. The one surface is in contact with air passing through inside of the electric motor. The one surface has an uneven part with an uneven surface shape. The uneven surface shape of the uneven part is formed in manner that, among a whole surface of the uneven part, a total surface area of a surface facing inward in the radial direction relative to an imaginary plane perpendicular to the motor axial center and having a center at the motor axial center is larger than an imaginary smooth surface assumed that the uneven surface shape of the uneven part is a smooth surface having no uneven part.
Accordingly, the total surface area is increased to be larger than the imaginary smooth surface. Therefore, it is possible to catch more copper powder flowing from the electric motor by the main plate of the impeller, compared with a case where the surface is a smooth surface having no uneven part. As a result, it is possible to suppress copper powder from flowing downstream of the impeller in the air flow.
Hereinafter, embodiments will be described according to the drawings. Same or equivalent portions among respective embodiments below are labeled with same reference numerals in the drawings.
A first embodiment is described.
The blower 10 is received in an air-conditioning case (not shown) made of resin material, and an air passage through which the air-conditioning air flows is formed downstream of the blower 10 in a flow of air by the air-conditioning case. An evaporator (not shown) which cools the air-conditioning air is disposed downstream of the blower 10 in the flow of air in the air passage. Air leak is prevented by a seal material made of rubber around the evaporator. In
As shown in
Although illustration is omitted, the scroll casing is a product made of resin material, and receives the impeller 14 and forms an air gathering channel 20 defined to surround the impeller 14 to gather and blow off air flowing out of the impeller 14. The scroll casing has an intake port for drawing air, which is opened to one side in the axial direction of the motor axial center MC1. A bell mouth is formed around the outer edge of the intake port, and extends toward the inner circumference of the impeller 14 to lead the intake air to the intake port.
The electric motor 12 is a direct current motor with a brush, and is used for driving the blower of the air-conditioner for a vehicle. The electric motor 12 includes a motor rotation shaft 121, a housing 122, a yoke 123, a commutator 124, a brush 125, a motor stator 126, and a motor rotor 127.
The motor rotation shaft 121 is an axial component extending in the axial direction of the motor axial center MC1, i.e., the motor axial center MC1 direction, and is rotated at the motor axial center MC1. The motor rotation shaft 121 is projected from the housing 122 toward the intake port of the scroll casing.
The housing 122 and the yoke 123 are joined to each other to constitute a case of the electric motor 12 as a whole. The housing 122 is arranged adjacent to the intake port in the motor axial center MC1 direction relative to the yoke 123. The commutator 124 and the brush 125 are received inside the housing 122.
The yoke 123 is made of magnetic member such as iron, and has a side wall 123a forming a cylinder shape with a center corresponding to the motor axial center MC1 and a yoke bottom 123b closing an end of the side wall 123a opposite from the housing 122. The yoke bottom 123b has a projection part 123c projected in the motor axial center MC1 direction. The motor stator 126 and the motor rotor 127 are received inside the yoke 123.
The yoke bottom 123b has plural cooling wind introduction holes (through holes) 123d as air feed port for taking in a cooling wind inside of the electric motor 12. The housing 122 has plural cooling wind outlet pores (through holes) 122a as air exit port for discharging the cooling wind which is air flowed through inside of the electric motor 12. The cooling wind outlet pore 122a is formed so that the cooling wind is blown out in the direction along the motor axial center MC1 toward one surface 141a (refer to
The cooling wind is taken in from the adjacency of the air blow-off port of the air gathering channel 20 of the scroll casing, and flows into the electric motor 12 from the cooling wind introduction hole 123d as shown in an arrow FL1, then flows out of the cooling wind outlet pore 122a. The cooling wind which flows in the arrow FL1 inside the electric motor 12 cools components received in the housing 122 and the yoke 123, for example, the commutator 124, the brush 125, the motor stator 126, and the motor rotor 127.
The motor rotor 127 is a well-known part for a direct-current motor with a brush, and is fixed to the motor rotation shaft 121 to rotate integrally with the motor rotation shaft 121. The motor rotor 127 has plural coils arranged around the perimeter of the motor rotation shaft 121. Each of the coils of the motor rotor 127 is electrically connected to the commutator 124.
The motor stator 126 is a well-known part for a direct-current motor with a brush, and is made of plural permanent magnets fixed to the inner surface of the side wall 123a of the yoke 123. A slight clearance is defined between the motor stator 126 and the motor rotor 127 in a motor radial direction which is a radial direction around the motor axial center MC1. The motor stator 126 is disposed around the motor axial center MC1. In other words, the motor stator 126 is arranged to surround the outer side of the motor rotor 127.
The commutator 124 and the brush 125 are well-known parts for a direct-current motor with a brush, and are made of conductors. Concretely, the conductor forming the commutator 124 and the brush 125 is a copper component containing carbon. The commutator 124 and the brush 125 are in contact with each other to secure the electric connection state. The commutator 124 is fixed to the motor rotation shaft 121, and rotates integrally with the motor rotation shaft 121. The brush 125 is fixed to the housing 122, and is biased to press against the commutator 124 from the outer side of the commutator 124 in the motor radial direction. Therefore, when rotating with the motor rotation shaft 121, the commutator 124 slides in contact with the brush 125, thereby causing the sliding friction. The sliding friction produces wear powder PD of copper and carbon which are main materials of the commutator 124 and the brush 125. The wear powder PD flows out of the cooling wind outlet pore 122a together with the cooling wind flowing in the arrows FL1 and FL2.
The holder 16 is a motor support component for fixing the electric motor 12 to the scroll casing, and is fixed to the scroll casing. The holder 16 is, for example, a component made of resin material fabricated by injection molding. The holder 16 has a yoke insertion part 161 in an approximately cylinder shape in which the yoke 123 of the electric motor 12 is inserted, and a holder bottom 162 disposed at the bottom side of the yoke insertion part 161. The holder 16 has an air passage 16a which leads the cooling wind of the electric motor 12 from the adjacency of the air blow-off port of the air gathering channel 20 of the scroll casing to the cooling wind introduction holes 123d of the electric motor 12.
The projection part 123c of the yoke 123 is inserted into the holder bottom 162 in the motor axial center MC1 direction. The side wall 123a of the yoke 123 is press-fitted to the yoke insertion part 161 of the holder 16 in the motor axial center MC1 direction. The yoke 123 of the electric motor 12 is fixed to the holder 16, for example, by a screw.
The impeller 14 includes the main plate 141, a connecting boss part 142, a side board 143, and plural blades 144. The impeller 14 is rotated by the electric motor 12 around the motor axial center MC1, such that air drawn from the intake port of the scroll casing is blown off outward in the motor radial direction. That is, air is blown off to the air gathering channel 20 of the scroll casing.
The impeller 14 is a product made of resin, such as polypropylene (PP), ABS or PBT. Therefore, the impeller 14 is charged in minus by friction with air. Moreover, the resin which forms the impeller 14 is improved in the property of withstanding copper harm, for example, by adding an additive.
The blades 144 are tabular blades arranged in the circumferential direction around the motor axial center MC1. A first end 144a of the blade 144 in the motor axial center MC1 direction adjacent to the intake port of the scroll casing is connected with the annular side board 143, thereby connecting the first ends 144a of the blades 144 mutually. A second end 144b of the blade 144 in the motor axial center MC1 direction far from the intake port of the scroll casing is connected with the main plate 141, thereby connecting the second ends 144b of the blades 144 mutually.
The central part 141c of the main plate 141 is connected with the connecting boss part 142, and the peripheral part 141d of the main plate 141 is connected with the second end 144b of the blade 144. The motor rotation shaft 121 is inserted in the center of the connecting boss part 142, and the connecting boss part 142 is fixed to the motor rotation shaft 121 by plastically deforming. Thereby, the main plate 141 is connected with the motor rotation shaft 121, and rotates integrally with the motor rotation shaft 121. That is, the rotation power of the electric motor 12 is transmitted to the impeller 14 from the motor rotation shaft 121.
The impeller 14 is rotated in an arrow direction ARrt by the electric motor 12, and air is drawn to the inner side of the annular side board 143 from the air suction part 145 located adjacent to the first end in the motor axial center MC1 direction. The drawn air is blown off from between the blades 144 outward in the motor radial direction.
The central part 141c of the main plate 141 connected with the connecting boss part 142 has a cross-sectional form depressed upward in
Next, the impeller 14 is further explained using
Since the main plate 141 is tabular as shown in
The main plate 141 has an uneven part 146 which constitutes an uneven surface shape on the one surface 141a. The surface shape of the uneven part 146 is shown in
The cross-sectional form of the protrusion part 146a is explained in detail. The protrusion part 146a is formed so that the cross-sectional form of the protrusion part 146a taken along a plane containing the motor axial center MC1, which is shown in
One 146b of the protrusion surfaces 146b, 146c is a first protrusion surface 146b facing inward in the motor radial direction relative to a radial direction plane PLr (refer to
In contrast, the other surface 146c of the pair of protrusion surfaces 146b, 146c is a second protrusion surface 146c facing outward in the motor radial direction with respect to the radial direction plane PLr (refer to
Thus, the main plate 141 has the uneven part 146. Among a whole surface of the uneven part 146, a total surface area of the uneven part 146 facing inward in the motor radial direction than the radial direction plane PLr, i.e., except the second protrusion surface 146c, is larger than an imaginary smooth surface PLsm (refer to
The top part 146d of the protrusion part 146a and a lowermost part 146e which is a base end of the protrusion part 146a are rounded with a minute corner R having, for example, a curvature radius of about 0.1 mm or larger in the cross-sectional form of
As shown in
When the uneven part 146 is compared with the yoke 123 of the electric motor 12 in
As shown in
As mentioned above, according to this embodiment, the main plate 141 of the impeller 14 has the uneven part 146 on the one surface 141a adjacent to the electric motor 12 in the thickness direction of the main plate 141. The surface shape of the uneven part 146 is formed such that the total surface area of the surface facing inward in the motor radial direction than the radial direction plane PLr, among the whole surface of the uneven part 146, is larger than the imaginary smooth surface PLsm (refer to
According to this embodiment, since the impeller 14 is a component made of resin material, minus charging occurs due to friction between air and the impeller 14 while the impeller 14 is rotated based on a relation of triboelectric series. Therefore, wear powder PD emitted from the electric motor 12 can be drawn to the one surface 141a of the impeller 14 electrified with static electricity. Further, the wear powder PD is forced on the one surface 141a of the main plate 141 of the impeller 14 by the cooling wind blown off from the cooling wind outlet pore 122a of the electric motor 12, and adheres to the one surface 141a. Therefore, the impeller 14 that is a product made of resin material can catch much wear powder PD from the electric motor 12.
The copper powder which is wear powder PD adhering to the main plate 141 of the impeller 14 can be fixed on the one surface 141a of the main plate 141 due to action such as Coulomb force or intermolecular force working among minute particles to be drawn to each other. Since many wear powder PD can be caught with the impeller 14, the wear powder PD can be restricted from dispersing into the air gathering channel 20 of the scroll casing. As a result, the product life of the air-conditioner for a vehicle can be increased by restricting copper harm resulting from copper adhering to a rubber component and a resin component located downstream of the impeller 14 in the flow of air. Alternatively, it is unnecessary to add an additive for preventing the copper harm to the rubber component and the resin component. In this case, it is possible to reduce the cost of the air-conditioner for a vehicle.
According to this embodiment, the uneven part 146 of the main plate 141 is located adjacent to the electric motor 12 and includes the protrusion parts 146a extending in the motor circumferential direction. The protrusion part 146a is formed so that the cross-sectional form of the protrusion part 146a taken along the plane containing the motor axial center MC1 has the shape of tapering triangle. Therefore, the area of the main plate 141 adjacent to the electric motor 12 can be increased, and many wear powder PD can be made to adhere to the main plate 141. The surface area of the main plate 141 adjacent to the electric motor 12 can be easily increased without enlarging the size of the impeller 14.
According to this embodiment, the first protrusion surface 146b of the pair of protrusion surfaces 146b, 146c which constitute the surface of the protrusion part 146a is a surface facing inward in the motor radial direction relative to the radial direction plane PLr (refer to
According to this embodiment, the second protrusion surface 146c of the pair of protrusion surfaces 146b, 146c is a surface facing outward in the motor radial direction relative to the radial direction plane PLr. Therefore, it is possible to increase the surface area of the first protrusion surface 146b to which wear powder PD adheres easily in the uneven part 146 of the impeller 14. Therefore, the impeller 14 can be improved in performance catching the wear powder PD.
According to this embodiment, since each of the protrusion parts 146a which constitute the uneven part 146 has the shape of a ring around the motor axial center MC1, the uneven part 146 is formed not to increase the off-center of the impeller 14 relative to the motor axial center MC1. In other words, the uneven part 146 is formed such that the center-of-gravity position of the impeller 14 does not move away from the motor axial center MC1, while the protrusion part 146a is formed. Therefore, the surface area can be increased on the one surface 141a of the impeller 14 by keeping the rotation balance when the impeller 14 rotates. The amount of the wear powder PD which adheres to the one surface 141a can be increased.
According to this embodiment, the cooling wind outlet pore 122a of the electric motor 12 is the through hole passing through the housing in parallel with motor axial center MC1. In other words, the cooling wind outlet pore 122a is formed so that air is blown out toward the one surface 141a of the main plate 141 of the impeller 14 in the direction along the motor axial center MC1. Therefore, compared with a case where air is blown out from the cooling wind outlet pore 122a outward in the motor radial direction, it takes long time for the circulating air out of the cooling wind outlet pore 122a to flow into the air gathering channel 20 of the scroll casing. Thereby, the amount of wear powder PD which adheres to the one surface 141a of the impeller 14 can be increased.
According to this embodiment, the radial ribs 147 extending in the motor radial direction are defined on the main plate 141 of the impeller 14 adjacent to the electric motor 12. Thus, the air which flowed out of the cooling wind outlet pore 122a of the electric motor 12 is agitated by rotation of the impeller 14, and stagnation arises in the flow of air. Therefore, the wear powder PD which flowed out of the electric motor 12 with the air easily stays at the stagnant part such that the performance of the impeller 14 which catches wear powder PD can be improved.
A second embodiment is described. In this embodiment, a point different from the first embodiment is mainly explained, and explanation of a portion the same or equal to the first embodiment is omitted or simplified. This is the same in the third embodiment and the subsequent embodiments mentioned below.
Therefore, according to this embodiment, compared with the first embodiment, the same effects can be acquired as the first embodiment while the amount of the wear powder PD (refer to
A third embodiment is described. A point different from the first embodiment is mainly explained.
As shown in
The connection rib 148 is configured to couple the first protrusion surface 146b of one protrusion part 146a and the second protrusion surface 146c of the other protrusion part 146a, where the one protrusion part 146a and the other protrusion part 146a are adjacent to each other in the motor radial direction.
According to this embodiment, the uneven part 146 of the impeller 14 has the connection ribs 148 which connect the adjacent protrusion parts 146a in the motor radial direction. Since the main plate 141 of the impeller 14 has the uneven part 146, the thickness of the main plate 141 is uneven. Therefore, when fabricating the impeller 14 by injection molding, a difference is easily generated in the amount of contraction depending on the position in the main plate 141. As opposed to this, the difference in the amount of contraction can be reduced by the connection rib 148 connecting the adjacent protrusion parts 146a in the motor radial direction. The difference in the amount of contraction can be suppressed by the connection rib 148. Specifically, at a time of fabricating the impeller 14, the contraction of the main plate 141 is restricted in the motor radial direction, and it is possible to improve the property of removing the die at the time of fabrication.
According to this embodiment, the wear powder PD (refer to
A fourth embodiment is described. A point different from the second embodiment is mainly explained.
The uneven part 146 of this embodiment has plural concave portions 149 defined in the one surface 141a of the main plate 141, instead of the protrusion parts 146a (refer to
In detail, as shown in
The first side 149b is a surface parallel to the thickness direction of the main plate 141. In other words, the first side 149b is a surface perpendicular to the one surface 141a of the main plate 141.
The second side 149c is a cylindrical surface parallel to the motor axial center MC1. The third side 149d and the fourth side 149e are planes parallel to a plane PLc which passes through the center of the bottom surface 149a and which includes the motor axial center MC1 (refer to
The bottom surface 149a is formed so that the cross-sectional form becomes parallel to the one surface 141a.
Since the bottom surface 149a and the four sides 149b, 149c, 149d, 149e are formed as mentioned above, the bottom surface 149a and the second side 149c are surfaces facing inward in the motor radial direction than the radial direction plane PLr (refer to
Therefore, the surface shape of the uneven part 146 is formed so that the total surface area of the surface facing inward in the motor radial direction than the radial direction plane PLr, of the whole surface of the uneven part 146, is larger than the imaginary smooth surface PLsm (refer to
According to this embodiment, when the impeller 14 rotates, since air stagnates near the third side 149d or the fourth side 149e of the concave portion 149, wear powder PD (refer to
In this embodiment mentioned above, the wear powder PD (refer to
In each embodiment, the blower 10 is a sirocco fan, and may be a turbofan or a radial fan.
In each embodiment, the blower 10 is used for an air-conditioner for a vehicle, and may be used for other uses.
In the first to third embodiments, the top part 146d and the lowermost part 146e of the protrusion part 146a of the main plate 141 of the impeller 14 has the minute roundness, and may not have the minute roundness.
In the first embodiment, as shown in
In the first to third embodiments, the triangle cross-sectional form is the same in the size among the protrusion parts 146a on the main plate 141 of the impeller 14 as shown in
In the first to third embodiments, the uneven part 146 of the impeller 14 is constituted by the protrusion parts 146a continuously arranged adjacent to each other as shown in
In each embodiment, the cooling wind outlet pore 122a is a penetration hole passing through the casing in parallel with the motor axial center MC1, such that air is blown out toward the main plate 141 of the impeller 14 in the direction along the motor axial center MC1. A guide rib 128 may be further arranged around the cooling wind outlet pore 122a of the electric motor 12 to guide the flow of air to be blown in the direction along the motor axial center MC1.
As shown in
In the first embodiment, the uneven part 146 is formed in the shape of concentric circles around the motor axial center MC1, and may not be the concentric circles as long as the center-off of the impeller 14 relative to the motor axial center MC1 is not increased. For example, the uneven part 146 may be formed in a point symmetry shape at a center corresponding to the motor axial center MC1, or in a line symmetry shape at a center corresponding to the plane containing the motor axial center MC1. This is the same as in the second to fourth embodiments.
In each embodiment, the wear powder PD is generated by friction when the commutator 124 slides in contact with the brush 125. However, the wear powder PD is not limited to be fine particles.
It should be appreciated that the present disclosure is not limited to the embodiments described above and can be modified appropriately within the scope of the appended claims. The embodiments above are not irrelevant to one another and can be combined appropriately unless a combination is obviously impossible. In the respective embodiments above, it goes without saying that elements forming the embodiments are not necessarily essential unless specified as being essential or deemed as being apparently essential in principle. In a case where a reference is made to the components of the respective embodiments as to numerical values, such as the number, values, amounts, and ranges, the components are not limited to the numerical values unless specified as being essential or deemed as being apparently essential in principle. Also, in a case where a reference is made to the components of the respective embodiments above as to shapes and positional relations, the components are not limited to the shapes and the positional relations unless explicitly specified or limited to particular shapes and positional relations in principle.
Number | Date | Country | Kind |
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2014-051818 | Mar 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/000392 | 1/29/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/136829 | 9/17/2015 | WO | A |
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20070065277 | Muller et al. | Mar 2007 | A1 |
20110116928 | Czulak | May 2011 | A1 |
Number | Date | Country |
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H07004396 | Jan 1995 | JP |
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2002202098 | Jul 2002 | JP |
2003328999 | Nov 2003 | JP |
2010053814 | Mar 2010 | JP |
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Entry |
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International Search Report and Written Opinion (in Japanese with English Translation) for PCT/JP2015/000392, dated Apr. 28, 2015; ISA/JP. |
Number | Date | Country | |
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20160305435 A1 | Oct 2016 | US |