DE112016002180T5 - centrifugal blower - Google Patents

Abstract

The inside of a blower housing (10, 10A to 10E) of a centrifugal blower (1) comprises a discharge air flow path (13) located on an airflow downstream side from a trailing edge (21b) of each of the vanes (21a) of a centrifugal fan (20, 20A to 20C). 20E) extends radially outward in a radial direction of a rotary shaft (20a). The exhaust air flow path (13) includes an adjacent air flow path (131, 131A to 131C) adjacent to the trailing edge (21b) of each of the plurality of vanes (21). When the length of the wing (21) at the trailing edge (21b) in the axial direction is taken as the wing height (Lb), and the length at the trailing edge (21b) of the centrifugal fan (20, 20A to 20C, 20E) in the axial direction when the fan height (Lf) is assumed, the length (La) of the adjacent air flow path in the axial direction is greater than or equal to the blade height (Lb) and less than or equal to the fan height (Lf).

Description

Reference to related application

This application is based on the Japanese Patent Application No. 2015-99311 , filed on May 14, 2015, the disclosure of which is incorporated herein by reference.

Technical area

The present disclosure relates to a centrifugal fan that blows air.

Background Art

A hitherto known centrifugal blower is constructed such that a centrifugal fan is accommodated inside a volute casing with a spiral venting train (see, for example, Patent Document 1). Patent Document 1 discloses that a height of a wall surface that lies opposite to a centrifugal fan in the volute casing is changed starting from a nose portion of the volute casing which is closest to the fan.

Document of the prior art

Patent document

• Patent Document 1: JP2014-132164A

Summary of the invention

The inventors have made studies on the use of a type of blower housing (perfect blow-off housing) which is opened over its entire circumference and blows air from the entire circumference, instead of the spiral housing for a centrifugal blower.

The inventors have found that when a centrifugal blower includes the perfect blow-off case and when a height of a wall surface against a centrifugal fan is intentionally changed in the circumferential direction to reduce noise as in Patent Document 1, the noise tends to be increased.

The inventors have made serious researches on the cause of such noise increase. As a result, it is found that when the height of the wall surface with respect to the centrifugal fan is changed in the circumferential direction, in a shape of an air flow path defined by the housing and the centrifugal fan, a sudden expansion or a sudden contraction occurs in the air flow path, which is defined by the housing and the centrifugal fan. Due to the sudden expansion or the sudden contraction, an unstable vortex occurs in the air flow path defined by the housing and the centrifugal fan, resulting in an increase in noise.

It is an object of the present disclosure to provide a centrifugal blower capable of suppressing noises generated due to a shape of an air flow path defined by a blower case opened over the entire circumference thereof, and a centrifugal fan.

The disclosure is directed to a centrifugal blower that includes a centrifugal fan that draws air from one side in an axial direction of a rotary shaft and discharges the air in a radial direction of the rotary shaft to the outside, and a fan housing that accommodates the centrifugal fan and over its entire circumference the rotary shaft is open around.

In one aspect of the present disclosure, a centrifugal fan of a centrifugal fan includes a plurality of vanes juxtaposed in a circumferential direction of a rotating shaft, a fairing connecting between first sides (the one side) in an axial direction of the vanes, and a main plate interposed between second Sides (the other sides) in the axial direction of the wing connects and is connected to the rotary shaft.

The interior of the blower housing includes a discharge air flow path that extends outward in a radial direction of the rotating shaft on an airflow downstream side from a trailing edge of each of the wings. In addition, the exhaust air flow path includes an adjacent air flow path adjacent to the trailing edge of each of the vanes.

When the length in the axial direction of each of the flights is assumed to be the wing height at the trailing edge and when the length in the axial direction of the centrifugal fan at the trailing edge is taken as the fan height, the length in the axial direction of the adjacent air flow path is greater than or equal to the blade height and less than or equal to the fan height.

In this way, the length in the axial direction of the air flow path adjacent to the centrifugal fan in the fan housing is set between the sash height at the trailing edge of the sash and the fan height, thereby reducing the shape of the air flow path defined by the fan Centrifugal fan and the blower housing is defined, has essentially no sudden expansion and no sudden contraction.

Consequently, the centrifugal blower with the blower housing opened over its entire circumference and the centrifugal fan make it possible to suppress noises generated due to the shape of the air flow path defined by the blower housing and the centrifugal fan.

The term "adjacent airflow path adjacent to the trailing edge of each of the plurality of blades" includes not only the airflow path in direct contact with the trailing edge of the blade, but also an airflow path that is not in contact with the trailing edge of the blade while at a predetermined distance is in an adjacent relationship to the trailing edge of the wing.

In another aspect of the present disclosure, a centrifugal fan of a centrifugal fan includes a plurality of vanes juxtaposed in a circumferential direction of a rotating shaft, a fairing connecting between first sides in an axial direction of the vanes, and a main plate interposed between second sides in the axial direction the wing connects and is connected to the rotary shaft. The interior of the blower housing includes a discharge airflow path that extends outward in a radial direction of the rotating shaft on an airflow downstream side of a trailing edge of each of the wings. In addition, the exhaust air flow path includes an adjacent air flow path adjacent to the trailing edge of each of the vanes. It is assumed that a length in the axial direction of the discharge air flow path at a position closest to the trailing edge of each of the blades is an air flow path height, a length in the axial direction of each of the blades at the trailing edge is the blade height, and the length in the axial direction of the centrifugal fan at the trailing edge is the fan height. At this time, the air flow path height of the adjacent air flow path is greater than or equal to the blade height and less than or equal to the fan height.

This also allows the shape of the air flow path defined by the centrifugal fan and blower housing to have substantially no sudden expansion and no sudden contraction. Consequently, the centrifugal blower with the blower housing opened over its entire circumference and the centrifugal fan make it possible to suppress noises generated due to the shape of the air flow path defined by the blower housing and the centrifugal fan.

Brief description of the drawings

The foregoing and other objects, features and advantages of the present disclosure will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:

1 Fig. 10 is a perspective view illustrating an appearance of a centrifugal blower of a first embodiment;

2 Fig. 10 is a sectional view in an axial direction of the centrifugal blower of the first embodiment;

3 is an enlarged view of a section 111 from 2 ;

4 Fig. 10 is an enlarged view illustrating an air flow in a main part of a centrifugal blower of a comparative example;

5 Fig. 10 is an enlarged view illustrating an air flow in a main part of the centrifugal blower of the first embodiment;

6 Fig. 10 is a sectional view in an axial direction of a centrifugal blower of a second embodiment;

7 Fig. 10 is a sectional view in an axial direction of a centrifugal blower of a third embodiment;

8th Fig. 10 is a sectional view in an axial direction of a centrifugal blower of a fourth embodiment;

9 Fig. 10 is a sectional view in an axial direction of a centrifugal blower of a fifth embodiment; and

10 is a sectional view in an axial direction of a centrifugal blower of a sixth embodiment.

Description of embodiments

Hereinafter, embodiments of the disclosure will be described with reference to drawings. In each of the following embodiments, portions that are the same as or equivalent to those described in the foregoing embodiment will be denoted by the same reference numerals, and their description may be omitted. When only a portion of a component is described in each of the embodiments, it is believed that other portions of the component are similar to those of one component corresponding component described in the previous embodiment.

First Embodiment

A centrifugal fan 1 A first embodiment will be described with reference to FIG 1 to 5 described. An arrow AD in 2 shows an axial direction of a rotary shaft 20a a centrifugal fan 20 to be described later. An arrow RD in 2 shows a radial direction of the rotary shaft 20a of the centrifugal fan 20 to be described later. The same applies to other drawings except 2 , 2 shows a part of a sectional shape of the centrifugal blower 1 running along an in 1 shown line II-II is cut.

The centrifugal fan 1 the in 1 and 2 The first embodiment shown serves as an air blowing device applied to a vehicle as a moving body. The centrifugal fan 1 The first embodiment is used, for example, as an air blower of an indoor air conditioner for air conditioning a passenger compartment or an air blower of a seat air conditioner provided in a seat.

As in 2 shown is the centrifugal fan 1 of the first embodiment is constructed as a flat fan in which the dimension in the radial direction RD of the rotary shaft 20a larger than the dimension in the axial direction AD of the rotary shaft 20a is to improve the mountability in a vehicle.

The centrifugal fan 1 The first embodiment comprises main components with a blower housing 10 Building an outer shell, a centrifugal fan 20 in the blower housing 10 is included, and an electric motor 30 ,

The blower housing 10 is a container housing containing the centrifugal fan 20 and the electric motor 30 receives. The blower housing 10 The first embodiment has a fan cover 11 and an engine cover 12 , The fan cover 11 and the engine cover 12 are each other with a gap in the axial direction AD of the rotary shaft 20a arranged opposite. In the first embodiment, build the fan cover 11 and the engine cover 12 a pair of wall portions facing each other in the axial direction AD of the rotary shaft 20a opposite, up.

The fan cover 11 is on a first side (the one side) in the axial direction AD of the rotary shaft 20a arranged. The fan cover 11 is a cover that forms part of the centrifugal fan 20 covering from the first side in the axial direction AD. The fan cover 11 is made of an annular element with an opening in its center. The fan cover 11 is coarse in a fan-side inner peripheral portion 111 , a fan-side step section 112 and a fan-side outer peripheral portion 113 divided.

The fan-side inner peripheral portion 111 is an interior section of the fan cover 11 which is in the axial direction AD with wings 21 of the centrifugal fan 20 overlaps. The fan-side inner peripheral portion 111 has a shape that extends along the radial direction RD to the wings 21 of the centrifugal fan 20 to cover. The fan-side inner peripheral portion 111 has a circular air intake 111 in its center, which penetrates it in the axial direction AD.

The fan-side outer peripheral portion 113 is a section of the fan cover 11 on a side farther outward in the radial direction RD than the fan-side inner peripheral portion 111 , The fan-side outer peripheral portion 113 has a shape that extends along the radial direction RD. The fan-side outer peripheral portion 113 has several projections 113a on an outer side in the radial direction RD. As in 1 shown, the fan-side outer peripheral portion 113 the first embodiment three projections 113a with a predetermined distance in its circumferential direction.

The projections 113a are in the axial direction AD to a side of an engine cover 12 in front. Each of the tabs 113a has at its end portion on the side of the engine cover 12 a screw hole through which an unillustrated screw is inserted around the fan cover 11 with the engine cover 12 connect to.

Returning to 2 connects the fan-side step section 112 the fan-side inner peripheral portion 111 with the fan-side outer peripheral portion 113 , The fan-side step section 112 has a shape that extends along the axial direction AD, so that a step between the fan-side inner peripheral portion 111 and the fan-side outer peripheral portion 113 is formed.

The engine cover 12 is on a second side (the other side) in the axial direction AD of the rotary shaft 20a arranged. The engine cover 12 covers the electric motor 30 from the second side in the axial direction AD. The engine cover 12 is made of a disc-like element. The engine cover 12 is coarse in a motor-side inner peripheral portion 121 , an engine-side step portion 122 and a motor-side outer peripheral portion 123 divided.

The motor-side inner peripheral portion 121 is an inside portion of the engine cover 12 , which in the axial direction AD with the electric motor 12 overlaps. The motor-side inner peripheral portion 121 has a through hole in its middle 121 that penetrates it in the axial direction AD.

The motor-side outer peripheral portion 123 is a section of the engine cover 12 on a farther outer side in the radial direction RD than the motor-side inner peripheral portion 121 , The motor-side outer peripheral portion 123 has in areas that on the fan side outer peripheral portion 113 trained protrusions 113a correspond, screw holes, are used by the screws not shown.

The motor-side step section 122 connects the motor-side inner peripheral portion 121 with the motor-side outer peripheral portion 123 , The motor-side step section 122 has a shape that extends along the axial direction AD, so that between the motor-side inner peripheral portion 121 and the motor-side outer peripheral portion 123 a step is formed.

In the blower housing 10 The first embodiment, the fan cover 11 and the engine cover 12 in a state in which the projections 113a the fan cover 11 against the engine cover 12 bumped together with unshown screws.

The fan cover 11 and the engine cover 12 can be attached to each other by an element other than the screw. In addition, the fan cover 11 and the engine cover 12 can not be constructed to be connected to each other, but can be connected, for example, to a strut used to drive the centrifugal fan 1 to attach to systems.

The blower housing 10 has a discharge air flow path 13 through which the centrifugal fan 20 discharged air flows, between the fan-side outer peripheral portion 113 and the motor-side outer peripheral portion 123 , The exhaust air flow path 13 is an air flow path inside the blower housing 10 located on an airflow downstream side of the trailing edge 21b every wing 21 of the centrifugal fan 20 extends outward in the radial direction RD. The exhaust air flow path 13 will be described later in detail.

An air blow-off section 14 for blowing air to the outside is between the outer ends of the fan-side outer peripheral portion 113 and the motor-side outer peripheral portion 123 provided. The air blow-off section 14 is over the entire circumference of the blower housing 10 around the rotary shaft 20a around along the side surface of the centrifugal blower 1 open. In the area of the projection 113a will blow off the blower housing 10 through the lead 113a with special needs. Consequently, the state in which the Luftabblasabschnitt 14 over the entire circumference of the blower housing 10 open, a condition in which the air outlet 14 essentially over the entire circumference of the blower housing 10 is open.

The centrifugal fan 20 sucks air from the first side in the axial direction AD of the rotary shaft 20a and gives the air in the radial direction RD of the rotary shaft 20a outwards. In the first embodiment, a back fan (turbo fan) in which the exhaust side of the fan is turned backward with respect to the rotational direction of the fan is called the centrifugal fan 20 used.

The centrifugal fan 20 includes several wings 21 in the circumferential direction of the rotary shaft 20a are arranged side by side, a panel 22 between the first sides in the axial direction AD of the wings 21 connects, and a main plate 23 between the second sides in the axial direction AD of the wings 21 combines.

An air flow path through which air flows is between the mutually adjacent wings 21 provided. Every wing 21 has a leading edge 21a , which builds up an air inflow section, and a trailing edge 21b that builds up an air outflow section.

The costume 22 is made of an annular element with an opening in its center. The costume 11 has an air intake opening 221 for guiding the from the air intake 111 sucked air into the centrifugal fan 20 , The costume 22 is from the fan-side inner peripheral portion 111 separated, and the inner surface side of the panel 22 opposite the main plate 23 is the first side in the axial direction AD of each wing 21 connected.

The main plate 23 is made of a conical element that faces one side of the air intake 111 is recessed in the axial direction AD. The main plate 23 has a hub section 231 for the connection of the rotary shaft 20a in their midst. The main plate 23 is from the engine-side inner peripheral portion 121 separated, and theirs paneling 22 opposite surface side is with the second side in the axial direction AD of the wing 21 connected.

The rotary shaft 20a is made of a cylindrical rod-like element. The rotary shaft 20a is in relation to the engine cover 12 about a camp 20b held in the through hole 121 the engine cover 12 is arranged. The rotary shaft 20a stands from the through hole 121 to one side of the main plate 23 in front. A section of the rotary shaft 20a that is to the side of the main plate 23 protrudes, is with the main plate 23 connected so that the main plate 23 integral with the rotary shaft 20a rotates.

The electric motor 30 drives the centrifugal fan 20 turning on. The electric motor 30 The first embodiment is on the back of the surface of the main plate 23 opposite the wings 21 and the disguise 22 arranged. In particular, the electric motor 30 the first embodiment arranged in a space between the main plate 23 and the motor-side inner peripheral portion 121 the engine cover 12 is trained.

In the first embodiment, a brushless DC rotor DC motor is used as the electric motor 30 used. The electric motor 30 includes a stator 31 that with the engine cover 12 connected, a coil 32 around the stator 31 is wound, a rotor 33 connected to the back surface of the main plate 23 is connected, and a permanent magnet 34 on the inside circumference of the rotor 33 opposite the coil 32 is arranged.

In the electric motor 30 The first embodiment is the stator 31 , the sink 32 , the rotor 33 and the permanent magnet 34 arranged in the radial direction RD side by side, so that they are the bearing 20b overlap in the radial direction RD. This leads to a small body size of the electric motor 30 in the axial direction AD.

The exhaust air flow path 13 The first embodiment will now be described. The exhaust air flow path 13 of the first embodiment extends along the radial direction RD so that the length in the axial direction AD is substantially uniform over the entire area in the radial direction RD.

The exhaust air flow path 13 The first embodiment has an adjacent air flow path 131 adjacent to the trailing edge 21b every wing 21 , In particular, the adjacent air flow path 131 in the exhaust air flow path 13 closer to the fan side step portion 112 and the engine-side step portion 122 as at the blow-off section 14 ,

The dimension in the axial direction AD of the adjacent air flow path 131 is determined such that a sudden expansion or sudden contraction in the air flow path through the centrifugal fan 20 and the blower housing 10 is defined, does not occur.

As in 3 is shown, the dimension La in the axial direction AD of the adjacent air flow path 131 with respect to the dimension (wing height Lb) in the axial direction AD of each wing 21 at the rear edge 21b and the dimension (fan height Lf) in the axial direction AD of the centrifugal fan 20 at the rear edge 21b certainly. The fan height Lf is obtained by the thickness of the panel 22 and the thickness of the main plate 23 in the axial direction AD are added to the wing height Lb. The dimension La in the axial direction AD of the adjacent air flow path 131 corresponds to the length of each wing 21 of the centrifugal fan 20 in the axial direction AD at the position closest to the trailing edge 21b in the exhaust air flow path 13 , In the following description, the length of the exhaust air flow path can be determined 13 in the axial direction AD at the position closest to the trailing edge 21b every wing 21 of the centrifugal fan 20 simply referred to as air flow path height La.

A dimension La in the axial direction AD of the adjacent air flow path 131 of the first embodiment is set equal to or greater than the blade height Lb and less than or equal to the fan height Lf. In other words, the air flow path height La is the adjacent air flow path 131 greater than or equal to the wing height Lb and less than or equal to the fan height. The dimension La in the axial direction AD of the adjacent air flow path 131 is set within a range in which the numeric expression F1 is satisfied. Lb ≤ La ≤ Lf (F1)

The dimension La in the axial direction AD of the adjacent air flow path 131 is preferably set to a dimension closer to the dimension of the blade height Lb than to the dimension of the fan height Lf. Specifically, the dimension La becomes in the axial direction AD of the adjacent air flow path 131 preferably set within a range in which the numerical expression F2 is satisfied. La - Lb <Lf - La (F2)

It is even more preferable that the dimension La in the axial direction AD of the adjacent air flow path 131 is substantially equal to the wing height Lb (La ≈ Lb).

The operation of the centrifugal blower 1 The first embodiment will now be described. When electric power to the electric motor 30 is fed, the electric motor drives the centrifugal fan 20 turning on. As a result, the centrifugal fan rotates 20 around the rotary shaft 20a and sucks, as if by fat arrows in 2 indicated, through the air intake opening 111 Air from one side in the axial direction AD. The centrifugal fan 20 blows through the air intake 111 sucked air in the radial direction RD to the outside.

4 Fig. 10 is a sectional view showing a main part of a centrifugal blower as a comparative example of the first embodiment. In the centrifugal blower of the comparative example, as in 4 is shown, the dimension La in the axial direction AD of the adjacent air flow path 131 larger than the fan height Lf. In the centrifugal fan of the comparative example, the shape of the air flow path expanded by the centrifugal fan expands 20 and the blower housing 10 is defined, suddenly. In the centrifugal blower having such a Luftströmungswegform is on the outlet side of the centrifugal fan 20 (ie in the neighborhood of the trailing edge 21b ) creates an unstable vortex that causes noise.

On the other hand, in the centrifugal blower 1 of the first embodiment, the dimension La in the axial direction AD of the adjacent air flow path 131 greater than or equal to the wing height Lb and less than or equal to the fan height Lf set. In other words, the air flow path height La is the adjacent air flow path 131 greater than or equal to the wing height Lb and less than or equal to the fan height. The centrifugal fan 1 The first embodiment can therefore, as in 5 shown the occurrence of unstable vortices in the adjacent air flow path 131 suppress.

In the centrifugal fan 1 In the first embodiment as described above, the axial dimension (length) of the air flow path becomes adjacent to the centrifugal fan 20 in the blower housing 10 between the wing height Lb at the trailing edge 21b of the grand piano 21 and the fan height Lf set. In other words, the air flow path height La is the adjacent air flow path 131 greater than or equal to the wing height Lb and less than or equal to the fan height.

Consequently, the shape of the air flow path passing through the centrifugal fan 20 and the blower housing 10 is defined, a form that has essentially no sudden expansion and no sudden contraction.

Thus, the centrifugal fan 1 In the first embodiment, noises due to the shape of the air flow path passing through the blower housing 10 and the centrifugal fan 20 is defined in the centrifugal fan 1 be generated, which is the open over its entire circumference fan housing 10 and the centrifugal fan 20 includes, suppress.

In the first embodiment, the adjacent air flow path becomes 131 by a pair of wall portions (fan-side outer peripheral portion 113 and motor-side outer peripheral portion 123 ) formed in the axial direction AD of the blower housing 10 are opposite. This makes it possible to increase the body size of each of the sections that make up the adjacent airflow path 131 define, in the axial direction AD of the blower housing 10 to downsize. Such a structure is preferable for a case where the centrifugal blower 1 is placed in a place in which a storage space is limited, such as inside a vehicle seat.

In addition, the electric motor 30 in the first embodiment on the back of the main plate 23 arranged. Consequently, the electric motor causes 30 even no disturbance of the air flow, which makes it possible the occurrence of noise compared to the case where the electric motor 30 on the surface side of the main plate 23 is arranged to suppress.

In the first embodiment, the discharge air flow path 13 a shape extending along the radial direction RD so that the length in the axial direction AD is substantially uniform over the entire area in the radial direction RD. As a result, the entire area of the exhaust air flow path becomes 13 set to be a height between the wing height Lb at the trailing edge 21b of the grand piano 21 and the fan height Lf has. Consequently, it is possible to suppress the occurrence of noise while the body size of the centrifugal blower 1 is reduced.

Second Embodiment

A second embodiment will now be described with reference to FIG 6 described. The second embodiment differs from the first embodiment in that an adjacent air flow path 131A through the disguise 22 a centrifugal fan 20A and the main plate 23 is defined. In the second embodiment, descriptions of portions corresponding to those of FIGS first embodiment are similar or equivalent, omitted or simplified.

As in 6 shown, contains a blower housing 10A the second embodiment not the fan-side step portion 112 and the motor-side step section 122 provided in the first embodiment. In particular, in the fan housing 10A the second embodiment of the fan-side inner peripheral portion 111 and the fan-side outer peripheral portion 113 continuously formed, and the motor-side inner peripheral portion 121 and the motor-side outer peripheral portion 123 are also continuously formed.

In the centrifugal fan 20A In the second embodiment, the fairing extends 22 and the main plate 23 from the trailing edge 21b every wing 21 in the radial direction RD to the outside.

In particular, the disguise has 22 The second embodiment, a fairing side extension portion 222 extending in the radial direction RD from the trailing edge 21b of the grand piano 21 extends to the outside. in the second embodiment, the siding-side extension portion builds 222 a first extension portion extending from the trailing edge 21b of the grand piano 21 in the radial direction RD of the rotary shaft 20a extends to the outside.

The main plate 23 The second embodiment has a main slat-side extension portion 232 that is from the trailing edge 21b every wing 21 extends outward in the radial direction RD. In the second embodiment, the main-plate-side extension portion is constructed 232 a second extending portion extending from the trailing edge 21b of the grand piano 21 in the radial direction RD of the rotary shaft 20a extends to the outside.

The entire area of the exhaust air flow path 13 the second embodiment including the adjacent air flow path 131A is constructed by an air flow path, which is between the fairing side extension portion 222 and the main-plate-side extension portion 232 is trained.

The adjacent air flow path 131A The second embodiment is in the discharge air flow path 13 closer to the trailing edge 21b every wing 21 as at the Luftabblasabschnitt 14 , The dimension La in the axial direction Ad of the adjacent air flow path 131A of the second embodiment is substantially equal to the wing height Lb (La ≈ Lb). In other words, the air flow path height La is the adjacent air flow path 131A essentially equal to the wing height Lb.

Other constructions are the same as those of the first embodiment. The centrifugal fan 1 The second embodiment is constructed such that the adjacent air flow path 131A through the respective extension sections 222 and 232 the disguise 22 and the main plate 23 is defined. As a result, the adjacent air flow path has 131A a continuous form. It is therefore possible to reduce the noise generated due to the shape of the air flow path through the blower housing 10A and the centrifugal fan 20 is defined, continue to suppress.

The structure of the second embodiment makes it possible to reverse the flow of the centrifugal fan 20 discharged air to the side of the air intake opening 111 of the centrifugal fan 20 through a gap between the panel 22 and the fan cover 11 of the blower housing 10A is designed to suppress.

The structure of the second embodiment also makes it possible to prevent the entry of foreign matters such as water through a gap existing between the main plate 23 and the engine cover 12 of the blower housing 10A is formed in a side of an electric motor 12 to suppress.

Third Embodiment

A third embodiment will now be described with reference to FIG 7 described. The third embodiment differs from the first and second embodiments in that an adjacent air flow path 131B through the main plate 23 a centrifugal fan 20B and the fan cover 11 a blower housing 10B is defined. In the third embodiment, descriptions of portions that are similar or equivalent to those of the first or second embodiment will be omitted or simplified.

As in 7 shown includes the blower housing 10B the third embodiment, not the motor-side step portion 122 the first embodiment. In particular, the fan housing has 10B the third embodiment, the motor-side inner peripheral portion 121 and the motor-side outer peripheral portion 123 in a continuous manner.

In a centrifugal fan 20B In the third embodiment, the main plate extends 23 in the radial direction RD from the trailing edge 21b every wing 21 outward. In particular, the main plate has 23 the third embodiment a main plate side extension portion 232 extending in the radial direction RD from the trailing edge 21b of the grand piano 21 extends to the outside. In the third embodiment, the main-plate-side extension portion is constructed 232 an extension section 232 up, extending from the trailing edge 21b of the grand piano 21 in the radial direction RD of the rotary shaft 20a extends to the outside. In addition, the fan cover builds 11 in the third embodiment, a wall portion closer to the fairing 22 as at the main plate 23 is.

The entire area of the exhaust air flow path 13 the third embodiment including the adjacent air flow path 131B is constructed by an air flow path which is between the fan-side outer peripheral portion 113 and the main-plate-side extension portion 232 is trained. The adjacent air flow path 131B The third embodiment is in the discharge air flow path 13 closer to the fan side step portion 112 as at the Luftabblasabschnitt 14 ,

The dimension La in the axial direction AD of the adjacent air flow path 131B of the third embodiment is set equal to or greater than the blade height Lb and less than or equal to the fan height Lf. In other words, the air flow path height La is the adjacent air flow path 131B is greater than or equal to the blade height Lb and less than or equal to the fan height Lf. In the third embodiment, the dimension La becomes in the axial direction AD of the adjacent airflow path 131B also preferably set so as to be closer to the wing height Lb than to the fan height Lf.

Other constructions are the same as those of the first or second embodiment. The centrifugal fan 1 The third embodiment is constructed such that the adjacent air flow path 131B through the fan-side outer peripheral portion 113 of the blower housing 10B and the main-plate side extension portion 232 the main plate 23 is defined.

As a result, one side has the main plate 23 the adjacent air flow path 131B a continuous form. It is therefore possible to reduce the noise due to the shape of the air flow path passing through the blower housing 10B and the centrifugal fan 20B is formed, continue to suppress.

In addition, the structure of the third embodiment makes it possible to prevent foreign matters such as water from entering through a gap existing between the main plate 23 and the engine cover 12 of the blower housing 10B is formed in a side of the electric motor 30 to suppress.

Fourth Embodiment

A fourth embodiment will now be described with reference to FIG 8th described. The fourth embodiment differs from the first to third embodiments in that an adjacent air flow path 131C through the disguise 22 a centrifugal fan 20C and the engine cover 12 a blower housing 10C is defined. In the fourth embodiment, descriptions of portions that are similar or equivalent to those of at least one of the first to third embodiments are omitted or simplified.

As in 8th is shown, the fan-side step section 112 the first embodiment in a fan housing 10C omitted in the fourth embodiment. In particular, the fan housing has 10C the fourth embodiment, the fan-side inner peripheral portion 111 and the fan-side outer peripheral portion 113 in a continuous manner.

In the centrifugal fan 20C In the fourth embodiment, the fairing extends 22 from the trailing edge 21b every wing 21 in the radial direction RD to the outside. In particular, the disguise has 22 the fourth embodiment, a fairing side extension portion 222 that is from the trailing edge 21b of the grand piano 21 extends outward in the radial direction RD.

In the fourth embodiment, the trim side extension portion builds 222 an extension portion extending from the trailing edge 21b of the grand piano 21 extends outward in the radial direction RD. In addition, the engine cover builds 12 in the fourth embodiment, a wall portion closer to the main plate 23 as at the disguise 22 on.

The entire area of the exhaust air flow path 13 the fourth embodiment including the adjacent air flow path 13C is constructed by an air flow path which is between the engine-side outer peripheral portion 121 and the trim side extension portion 222 is trained. The adjacent air flow path 13C The fourth embodiment is in the discharge air flow path 13 closer to the engine-side step section 122 as at the Luftabblasabschnitt 14 ,

The dimension La in the axial direction AD of the adjacent air flow path 131C of the fourth embodiment is greater than or equal to the wing height Lb and less than or equal to the Fan height Lf set. In other words, the air flow path height La is the adjacent air flow path 131C greater than or equal to the wing height Lb and less than or equal to the fan height. In the fourth embodiment, the dimension La becomes in the axial direction AD of the adjacent air flow path 131C Also set such that it is closer to the wing height Lb than at the fan height Lf.

Other constructions are the same as the at least one of the first to third embodiments. The centrifugal fan 1 The fourth embodiment is constructed such that the adjacent air flow path 131C through the motor-side outer peripheral portion 123 of the blower housing 10C and the trim side extension portion 222 the disguise 22 is defined. As a result, the adjacent air flow path has 13C on his side of the panel 22 a continuous form. It is therefore possible to reduce the noise generated due to the shape of the air flow path through the blower housing 10C and the centrifugal fan 20C is defined, continue to suppress.

In addition, the structure of the fourth embodiment makes possible the reverse flow of the centrifugal fan 20C Air discharged through a gap between the panel 22 and the fan cover 11 of the blower housing 10C is formed, to the side of the air intake opening 111 of the centrifugal fan 20C to suppress.

Fifth Embodiment

A fifth embodiment will now be described with reference to FIG 9 described. The fifth embodiment differs from the first embodiment in that the shape of the exhaust air flow path 13 is changed. In the fifth embodiment, descriptions of portions that are similar or equivalent to those of the first embodiment will be omitted or simplified.

A blower housing 10D of the fifth embodiment is formed such that the fan-side outer peripheral portion 113 and the motor-side outer peripheral portion 123 in the radial direction RD toward the outside are gradually away from each other. In particular, the fan-side outer peripheral portion 113 shaped such that its position in the axial direction AD toward the outer side in the radial direction RD gradually from the engine cover 12 is away. Similarly, the motor-side outer peripheral portion 123 shaped so that its position in the axial direction AD toward the outside in the radial direction RD gradually from the fan cover 11 is away.

The length in the axial direction AD of the discharge air flow path 13 of the fifth embodiment gradually increases toward the airflow downstream side. The exhaust air flow path 13 of the fifth embodiment has in the vicinity of the trailing edge 21b every wing 21 the smallest length in the axial direction AD. In addition, the exhaust air flow path has 13 of the fifth embodiment, the largest length in the axial direction AD in the vicinity of the Luftabblasabschnitts 14 , In addition, in the exhaust air flow path 13 of the fifth embodiment has a length Lc in the axial direction AD in the vicinity of the Luftabblasabschnitts 14 less than or equal to the maximum length Lfmax in the axial direction AD of the centrifugal fan 20 fixed (Lc <Lfmax).

Other constructions are the same as those of the first embodiment. In the centrifugal fan 1 In the fifth embodiment, the length of the exhaust air flow path becomes 13 is gradually increased in the axial direction AD in the direction of the airflow downstream side. This makes it possible to suddenly expand between an outlet side of the exhaust air flow path 13 and a discharge target space in which air is discharged. As a result, it is possible to detect the occurrence of noise between the outlet side of the discharge air flow path 13 and the discharge target space to be discharged into the air.

In the fifth embodiment, the length becomes in the axial direction AD of the discharge air flow path 13 less than or equal to the maximum length in the axial direction AD of the centrifugal fan 20 established. Consequently, it is possible to suppress the occurrence of noise while the body size of the centrifugal blower 1 is reduced. For example, such a structure is preferable for a case where the centrifugal blower 1 is placed in a place with a storage room, which is limited as inside a vehicle seat.

Sixth Embodiment

A sixth embodiment will now be described with reference to FIG 10 described. The sixth embodiment differs from the second embodiment in that the shape of the exhaust air flow path 13 is changed. In the sixth embodiment, descriptions of portions that are similar or equivalent to those of the second embodiment will be omitted or simplified.

A blower housing 10E of the sixth embodiment is shaped such that the fan-side outer peripheral portion 113 and the motor-side outer peripheral portion 123 are gradually away from each other in the radial direction RD. In particular, the fan side Outer peripheral portion 113 shaped such that its position in the axial direction AD toward the outer side in the radial direction RD gradually from the engine cover 12 is away. Similarly, the motor-side outer peripheral portion 123 shaped so that its position in the axial direction AD toward the outside in the radial direction RD gradually from the fan cover 11 is away.

A centrifugal fan 20E of the sixth embodiment is shaped such that the fairing side extension portion 222 and the main-plate-side extension portion 232 as in the fan-side outer peripheral portion 113 and the motor-side outer peripheral portion 123 are gradually away from each other in the direction of the outside in the radial direction RD. In particular, the trim side extension portion 222 shaped such that its position in the axial direction AD as in the fan-side outer peripheral portion 113 toward the outside in the radial direction RD gradually from the engine cover 12 is away. The main plate side extension section 232 is formed such that its position in the axial direction AD as in the motor-side outer peripheral portion 123 in the radial direction RD gradually from the fan cover 11 The length in the axial direction AD of the exhaust air flow path is away toward the outside 13 of the sixth embodiment gradually increases toward the airflow downstream side. The exhaust air flow path 13 The sixth embodiment has near the trailing edge 21b every wing 21 the smallest length in the axial direction AD. The exhaust air flow path 13 of the sixth embodiment has the largest length in the axial direction AD in the vicinity of the Luftabblasabschnitts 14 , In addition, in the exhaust air flow path 13 of the sixth embodiment has a length Ld in the axial direction AD near the Luftabblasabschnitts 14 less than or equal to the maximum length Lfmax in the axial direction AD of the centrifugal fan 20 fixed (Ld <Lfmax).

Other constructions are the same as those of the second embodiment. In the centrifugal fan 1 In the sixth embodiment, the length becomes in the axial direction AD of the discharge air flow path 13 gradually increased in the direction of the airflow downstream side as in the fifth embodiment. Thus, the structure of the sixth embodiment provides similar results to those of the fifth embodiment.

In addition, the length becomes in the axial direction AD of the discharge air flow path 13 in the sixth embodiment as in the fifth embodiment, less than or equal to the maximum length in the axial direction AD of the centrifugal fan 20 established. The structure of the sixth embodiment, therefore, further provides the results similar to those of the fifth embodiment.

• (1) Wenngleich die vorstehend beschriebenen Ausführungsformen mit einem Beispiel beschrieben wurden, in dem das Zentrifugalgebläse 1 auf Luftblaseinrichtungen in einem Fahrzeug angewendet wird, ist die Offenbarung nicht darauf beschränkt. Zum Beispiel kann das Zentrifugalgebläse 1 auf Luftblaseinrichtungen einer ortsfesten Klimaanlage angewendet werden, die in Haushalten, Fabriken und ähnlichen verwendet wird.
• (2) Wenngleich die vorstehend beschriebenen Ausführungsformen mit einem Beispiel beschrieben wurden, in dem ein Rückwärtsventilator als der Zentrifugalventilator 20 verwendet wird, ist die Offenbarung nicht darauf beschränkt. Zum Beispiel kann ein Radialventilator, in dem eine Auslassseite eines Ventilators in die Radialrichtung RD gewandt ist, verwendet werden.
• (3) Wenngleich die vorstehend beschriebenen Ausführungsformen mit einem Beispiel beschrieben wurden, in dem ein bürstenloser Außenrotor-Gleichstrommotor als der Elektromotor 30 verwendet wird, ist die Offenbarung nicht darauf beschränkt. Ein Innenrotor-Gleichstrommotor kann als der Elektromotor 30 verwendet werden. Außerdem kann ein Wechselstrommotor als der Elektromotor 30 verwendet werden.
• (4) Wenngleich bevorzugt wird, dass der Elektromotor 30 wie in den vorstehend beschriebenen Ausführungsformen auf der Rückseite der Hauptplatte 23 angeordnet ist, ist die Offenbarung nicht darauf beschränkt. Zum Beispiel kann der Elektromotor 30 auf der Oberflächenseite der Hauptplatte 23 angeordnet werden. Außerdem kann der Elektromotor 30 nicht im Inneren des Gebläsegehäuses 10 angeordnet werden, sondern kann wenigstens teilweise außerhalb des Gebläsegehäuses 10 angeordnet werden.
• (5) Wenngleich die vorstehend beschriebenen fünften und sechsten Ausführungsformen mit einem Beispiel beschrieben wurden, in dem die jeweiligen Längen in der Axialrichtung AD des Abgabeluftströmungswegs 13 in den Aufbauten der ersten und zweiten Ausführungsformen in Richtung der luftströmungsabwärtigen Seite allmählich vergrößert sind, ist die Offenbarung nicht darauf beschränkt. Zum Beispiel können die jeweiligen Längen in der Axialrichtung AD des Abgabeluftströmungswegs 13 in dem Aufbau der dritten oder vierten Ausführungsform in Richtung der luftströmungsabwärtigen Seite allmählich vergrößert werden.
• (6) Wenngleich es wünschenswert ist, dass die Länge in der Axialrichtung AD des Abgabeluftströmungswegs 13 wie in der vorstehend beschriebenen fünften oder sechsten Ausführungsform kleiner oder gleich der maximalen Länge in der Axialrichtung AD des Zentrifugalventilators 20 festgelegt wird, ist die Offenbarung nicht darauf beschränkt. Zum Beispiel kann die Länge in der Axialrichtung AD des Abgabeluftströmungswegs 13 teilweise länger als die maximale Länge in der Axialrichtung AD des Zentrifugalventilators 20 sein.
• (7) Es wird zu schätzen gewusst, dass in jeder der vorstehenden Ausführungsformen ein Bestandteilelement der Ausführungsform, abgesehen von dem speziell definierten Fall und für den Fall, in dem das Bestandteilelement aus Prinzip für unverzichtbar gehalten wird, nicht notwendigerweise unverzichtbar ist. Die vorstehend beschriebenen Ausführungsformen können innerhalb den möglichen Grenzen geeignet kombiniert werden.
• (8) Wenn in jeder der vorstehend beschriebenen Ausführungsformen ein numerischer Wert, wie etwa die Anzahl, ein numerischer Wert, eine Menge oder ein Bereich eines Bestandteilelements der Ausführungsform, erwähnt wird, ist der numerische Wert, abgesehen von dem Fall, in dem die Zahl insbesondere als unverzichtbar definiert wird, und für den Fall, in dem die Zahl aus Prinzip klar auf die erwähnte Zahl beschränkt ist, nicht auf eine spezifizierte Zahl beschränkt.
• (9) Wenn in jeder der vorstehend beschriebenen Ausführungsformen eine Form, eine Positionsbeziehung oder ähnliches eines Bestandteilelements beschrieben wird, hat das Bestandteilelement, abgesehen von dem speziell definierten Fall und für den Fall, in dem das Bestandteilelement aus Prinzip ausschließlich die Form, die Positionsbeziehung oder ähnliches hat, nicht ausschließlich die Form, die Positionsbeziehung oder ähnliches.

Although some embodiments of the disclosure have been described herein, the disclosure should not be so limited, and various modifications or changes to the embodiments may be made appropriately. For example, the embodiments may be modified as follows. The modifications of the embodiments described above will now be described.

• (1) Although the above-described embodiments have been described with an example in which the centrifugal blower 1 is applied to air blowers in a vehicle, the disclosure is not limited thereto. For example, the centrifugal fan 1 be applied to air blowers of a fixed air conditioner used in homes, factories and the like.
• (2) Although the above-described embodiments have been described with an example in which a backward fan is used as the centrifugal fan 20 is used, the disclosure is not limited thereto. For example, a centrifugal fan in which an outlet side of a fan faces in the radial direction RD may be used.
• (3) Although the above-described embodiments have been described with an example in which a brushless DC rotor DC motor as the electric motor 30 is used, the disclosure is not limited thereto. An inner rotor DC motor can be considered the electric motor 30 be used. Also, an AC motor may be the electric motor 30 be used.
• (4) Although it is preferred that the electric motor 30 as in the embodiments described above on the back of the main plate 23 is arranged, the disclosure is not limited thereto. For example, the electric motor 30 on the surface side of the main plate 23 to be ordered. In addition, the electric motor 30 not inside the blower housing 10 can be arranged, but can at least partially outside the fan housing 10 to be ordered.
• (5) Although the above-described fifth and sixth embodiments have been described with an example in which the respective lengths in the axial direction AD of the discharge air flow path 13 In the constructions of the first and second embodiments, in the direction of the airflow downstream side are gradually increased, the disclosure is not limited thereto. For example, the respective lengths in the axial direction AD of the exhaust air flow path 13 be gradually increased in the structure of the third or fourth embodiment in the direction of the air flow downstream side.
• (6) Although it is desirable that the length in the axial direction AD of the discharge air flow path 13 as in the fifth or sixth embodiment described above, less than or equal to the maximum length in the axial direction AD of the centrifugal fan 20 is set, the disclosure is not limited thereto. For example, the length in the axial direction AD of the exhaust air flow path may be 13 partially longer than the maximum length in the axial direction AD of the centrifugal fan 20 be.
• (7) It is appreciated that, in each of the above embodiments, a constituent element of the embodiment is not necessarily indispensable except for the specifically defined case and in the case where the constituent element is considered indispensable in principle. The above-described embodiments may be appropriately combined within the possible limits.
• (8) In each of the above-described embodiments, when a numerical value such as the number, a numerical value, a quantity or a range of a constituent element of the embodiment is mentioned, the numerical value is, except for the case where the numerical value is defined as indispensable, and in the case where the figure is clearly limited to the number mentioned, is not limited to a specified number.
• (9) In each of the above-described embodiments, when a shape, a positional relationship or the like of a constituent element is described, the constituent element has, except for the specifically defined case and in the case where the constituent element of principle only the shape, the positional relationship or has similar, not only the form, the positional relationship or the like.

Claims (10)

Centrifugal blower for blowing air, comprising: a centrifugal fan ( 20 . 20A to 20C . 20E ), the air from one side of a rotary shaft ( 20a ) sucks in its axial direction and discharges the air from the rotary shaft radially outward; and a blower housing ( 10 . 10A to 10E ) receiving the centrifugal fan and opening around the rotary shaft along an entire circumference of the blower housing, wherein: the centrifugal fan comprises: a plurality of vanes (14); 21 ) juxtaposed in a circumferential direction of the rotary shaft: a fairing ( 22 ) connecting the one side of the plurality of blades in the axial direction; and a main plate ( 23 ) connecting the other sides of the plurality of blades in the axial direction and connected to the rotary shaft; the blower housing has a discharge air flow path therein ( 13 ) located on an airflow downstream side of a trailing edge (FIG. 21b ) each of the plurality of wings extends radially outward from the rotary shaft; the exhaust air flow path an adjacent air flow path ( 131 . 131A to 131C ) adjacent the trailing edge of each of the plurality of wings; and if: a length of the trailing edge of each of the plurality of blades in the axial direction is a wing height (Lb); and a length of the centrifugal fan at the trailing edge in the axial direction is a fan height (Lf), a length (La) of the adjacent air flow path in the axial direction is greater than or equal to the blade height and smaller than or equal to the fan height. Centrifugal blower for blowing air, comprising: a centrifugal fan ( 20 . 20A to 20C . 20E ), the air from one side of a rotary shaft ( 20a ) sucks in its axial direction and discharges the air from the rotary shaft radially outward; and a blower housing ( 10 . 10A to 10E ) receiving the centrifugal fan and opening around the rotary shaft along an entire circumference of the blower housing, wherein: the centrifugal fan comprises: a plurality of vanes (14); 21 ) juxtaposed in a circumferential direction of the rotary shaft: a fairing ( 22 ) connecting the one side of the plurality of blades in the axial direction; and a main plate ( 23 ) connecting the other sides of the plurality of blades in the axial direction and connected to the rotary shaft; the blower housing has a discharge air flow path therein ( 13 ) located on an airflow downstream side of a trailing edge (FIG. 21b ) each of the plurality of wings extends radially outward from the rotary shaft; the exhaust air flow path an adjacent air flow path ( 131 . 131A to 131C ) adjacent the trailing edge of each of the plurality of wings; and when: a length of the exhaust air flow path in the axial direction at a position closest to the trailing edge of each of the plurality of vanes is an air flow path height (La); a length of the trailing edge of each of the plurality of blades in the axial direction is a wing height (Lb); and a length of the centrifugal fan at the trailing edge in the axial direction is a fan height (Lf), the air flow path height of the adjacent air flow path is greater than or equal to the sash height and less than or equal to the fan height. Centrifugal fan according to claim 1 or 2, wherein the adjacent air flow path ( 131 ) is an air flow path defined by a pair of wall sections ( 113 . 123 ) of the blower housing, which are opposed to each other in the axial direction. A centrifugal blower according to claim 1 or 2, wherein: an element of the cowling and the main plate has an extension portion (FIG. 222 . 232 ) extending radially outward from the trailing edge of each of the plurality of vanes; the blower housing ( 10B . 10C ) a pair of wall sections ( 113 . 123 ) opposed to each other in the axial direction; and the adjacent air flow path ( 131B . 131C ) is an air flow path defined by the extension portion and one of the pair of wall portions. A centrifugal fan according to claim 4, wherein: said one member is the main plate; and the adjacent air flow path ( 131B ) is an air flow path through the extension section ( 232 ) of the main plate and a wall section ( 11 ) of the pair of wall sections closer to the panel than to the main panel. A centrifugal blower according to claim 4, wherein: said one member is said cowl; and the adjacent air flow path ( 131C ) is an air flow path through the extension section ( 222 ) of the cladding and a wall section ( 12 ) of the pair of wall sections closer to the main panel than to the panel. A centrifugal fan as claimed in claim 1 or 2, wherein: the shroud comprises a first extending portion (Fig. 222 ) extending radially outward from the trailing edge of each of the plurality of vanes; the main plate has a second extension section ( 232 ) extending radially outward from the trailing edge of each of the plurality of vanes; and the adjacent air flow path ( 131A ) is an air flow path defined by the first extension portion and the second extension portion. A centrifugal fan according to any one of claims 1 to 7, further comprising an electric motor ( 30 ) rotating the centrifugal fan, the electric motor being disposed on a back side of a surface of the main plate opposite to the plural vanes and the cowl. A centrifugal blower according to any one of claims 1 to 8, wherein a length of the discharge air flow path in the axial direction in the direction of the airflow downstream side becomes larger. A centrifugal blower according to claim 9, wherein the length of the discharge air flow path in the axial direction is set equal to or less than a maximum length (Lfmax) of the centrifugal fan in the axial direction.

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