JP2023136901A - Centrifugal air blower - Google Patents

Abstract

To provide a centrifugal air blower which has a ring member 54 and a cover case 221 having a plurality of communication paths 310, 320, 330, 340 and 350 for suppressing the flow-in of air which is blown out of an inter-blade flow passage 52a through a reverse flow passage 300 to a fan intake port 54a.SOLUTION: A ring member 54 is formed into an annular shape with a fan axial line CL as a center while having a fan intake port 54a into which air passing an air flow-in port 221a is sucked, and connected to one side in a fan axial line direction Dra of each of a plurality of blades 52. A turbo fan 18 blows out air which is sucked through the air flow-in port 221a and the fan intake port 54a to the outside in a radial direction with the fan axial line CL as a center through an air flow passage 54f and an inter-blade flow passage 52a. The ring member 54 and a cover case 221 form a reverse flow passage 300 being a clearance between the ring member and the cover case.SELECTED DRAWING: Figure 1

Description

The present invention relates to a centrifugal blower device.

BACKGROUND ART Conventionally, a centrifugal blower has been proposed that has a labyrinth structure in which a reverse flow path provided between a ring member and a cover case part is formed in a labyrinth shape (see, for example, Patent Document 1).

A centrifugal blower includes a plurality of blades arranged in the circumferential direction, a ring member connected to one side in the axial direction of each of the plurality of blades, and a ring member connected to one side in the axial direction of each of the plurality of blades. A centrifugal fan having a main plate connected to the other side of the direction.

A centrifugal blower includes a scroll casing that houses a centrifugal fan. The ring member forms a fan ventilation path together with the main plate and the plurality of blades.

As the centrifugal fan rotates, it blows air sucked in through the air inlet of the scroll casing and the fan inlet of the ring member outward in the radial direction about the fan axis through the fan ventilation passage.

The scroll casing has a cover case portion that forms an air inlet and is formed to cover the ring member from one side in the axial direction.

The ring member and the cover case portion form a labyrinth structure in which the backflow path is formed in a labyrinth shape in order to prevent the air blown out from the fan ventilation path from flowing into the air intake port through the backflow path.

Therefore, the main flow is the air flow that flows from one side of the air inlet in the axial direction through the air inlet and the fan intake port to the fan ventilation path, and the air flow that flows from the reverse flow path to the fan ventilation path through the air intake port is the main flow. It is possible to suppress the occurrence of turbulence in the mainstream due to mixing.

Japanese Patent Application Publication No. 2018-168852

In the centrifugal blower described in Patent Document 1, as described above, the ring member and the cover case part are used to prevent the air blown from the fan ventilation path from flowing into the air intake port through the reverse flow path. , constitutes a labyrinth structure in which the reverse flow path is formed in a labyrinth shape.

The present inventors used a communication path that circulates air between either the case outer cavity or the fan ventilation path and the backflow path, so that the air blown out from the fan ventilation path is inhaled through the backflow path. We considered suppressing the inflow into the mouth. The case outer cavity is a cavity formed on the outside of the cover case part.

In view of the above-mentioned points, the present invention utilizes a communication path that allows air to flow between one of the fan ventilation path and the case outer cavity and the backflow path, so that air from the fan ventilation path passes through the backflow path to the air intake port. It is an object of the present invention to provide a centrifugal blower device that suppresses the flow of air into the air.

In order to achieve the above object, the invention according to claim 1 provides a centrifugal blower, comprising:
When the direction in which the axis line (CL) extends is defined as the axial direction (DRa), a rotating shaft (14) formed to extend in the axial direction and rotate around the axis;
a centrifugal fan (18) supported by a rotating shaft and rotating together with the rotating shaft;
A casing (12) having an air inlet (221a) that opens on one side in the axial direction and housing a centrifugal fan and a rotating shaft on the other side in the axial direction with respect to the air inlet,
The centrifugal fan is
a plurality of blades (52) arranged in a circumferential direction centered on the axis;
The air inlet (54a) is disposed on one side of the plurality of blades in the axial direction, and has an air inlet (54a) through which air passing through the air inlet is sucked, and is formed in an annular shape centered on the axis; a ring member (54) connected to one side in the axial direction of each of the plurality of blades;
A main plate (56) disposed on the other side of the plurality of blades in the axial direction and connected to the other side of each of the plurality of blades in the axial direction,
The ring member forms a fan ventilation path (54f, 52a) together with the main plate and the plurality of blades,
As the centrifugal fan rotates, it blows out the air sucked in through the air inlet and air intake through the fan ventilation radially outward from the axis.
The casing has a cover case part (221) formed to cover the ring member from one side in the axial direction,
The ring member and the cover case portion form a reverse flow path (300) that is a gap between them,
A case outer cavity (500) is formed on the outer side of the cover case part,
The ring member or the cover case part is configured to connect either the case outer cavity (500) or the fan ventilation passage to prevent the air blown out from the fan ventilation passage from flowing into the air intake port through the reverse flow passage. One or more communication paths (310, 320, 330, 340, 350, 350b) are formed to allow air to flow between the flow path and the reverse flow path.

As described above, by using the communicating path that allows air to flow between the fan ventilation path or the case outer cavity and the backflow path, it is possible to ensure that air from the fan ventilation path flows into the air intake port through the backflow path. A suppressing centrifugal blower device can be provided.

Note that the reference numerals in parentheses attached to each component etc. indicate an example of the correspondence between the component etc. and specific components etc. described in the embodiments to be described later.

FIG. 2 is a perspective view of the centrifugal blower according to the first embodiment, viewed from one side in the fan axis direction. FIG. 2 is a cross-sectional view of the centrifugal blower according to the first embodiment of FIG. 1 taken along a plane including the fan axis; in particular, it is a cross-sectional view showing the configuration of a ring member, a main plate, a plurality of blades, and a reverse flow path of the turbo fan. . 3 is a sectional view taken along line III-III in FIG. 2. FIG. FIG. 3 is an enlarged partial cross-sectional view of the turbofan and the reverse flow path in the first embodiment of FIG. 2. FIG. FIG. 5 is an enlarged partial cross-sectional view of a reverse flow path and its surroundings in the turbofan in the first embodiment of FIG. 4. FIG. FIG. 5 is a view of a plurality of communication passages provided in the cover case portion of the centrifugal blower according to the first embodiment of FIG. 4 from one side in the fan axis direction. FIG. 5 is a partially enlarged view of the vicinity of the inlet of the communication path and the reverse flow path in the cover case part of the centrifugal blower according to the first embodiment of FIG. 4; FIG. 5 is a view of a plurality of communication passages provided in the cover case portion of the centrifugal blower according to the first embodiment of FIG. 4 from one side in the fan axis direction. FIG. 5 is a partially enlarged view of the communication path and its surroundings in the cover case part of the centrifugal blower according to the first embodiment of FIG. 4; FIG. 5 is a view of a plurality of communication passages provided in the cover case portion of the centrifugal blower according to the first embodiment of FIG. 4 from one side in the fan axis direction. FIG. 5 is a view of a plurality of communication passages provided in a ring member of the centrifugal blower according to the first embodiment of FIG. 4 from one side in the fan axis direction. FIG. 5 is a view of a plurality of communication passages provided in a ring member of the centrifugal blower according to the first embodiment of FIG. 4 from one side in the fan axis direction. The inter-blade flow path formed between two adjacent blades of the plurality of blades of the centrifugal blower according to the first embodiment of FIG. 1, and the two blades viewed from one side in the fan axis direction. This is a diagram. It is a cross-sectional view taken along a cross section including the fan axis of the centrifugal blower according to the second embodiment, showing a communication path formed in a cylindrical portion and a curved portion of a ring member. It is a sectional view which shows the structure of each of a ring member, a cover case part, a reverse flow path, and a discharge flow path among the sectional views cut|disconnected by the cross section containing a fan axis line of the centrifugal air blower in 3rd Embodiment. It is a sectional view which shows each structure of a ring member, a cover case part, and a reverse flow path among the sectional views cut|disconnected by the cross section containing a fan axis line of the centrifugal air blower in 4th Embodiment. It is a sectional view showing a communication path provided in a cover case part of a centrifugal blower in a fifth embodiment. It is a sectional view showing a communication path provided in a cover case part of a centrifugal blower in a sixth embodiment. It is a sectional view showing the communication path provided in the ring member of the centrifugal blower in a 7th embodiment. FIG. 5 is an enlarged partial cross-sectional view of a reverse flow path and its surroundings in the turbofan in the eighth embodiment of FIG. 4;

Embodiments of the present invention will be described below based on the drawings. In each of the following embodiments, parts that are the same or equivalent are given the same reference numerals in the drawings to simplify the explanation.

(First embodiment)
A centrifugal blower device 10 of this embodiment shown in FIGS. 1, 2, etc. is used in a vehicle air conditioner. The centrifugal blower 10 is a turbo blower. Specifically, as shown in FIGS. 1 and 2, the centrifugal blower 10 includes a scroll casing 12, a shroud 13, a rotating shaft 14, a rotating shaft housing 15, an electric motor 16, a turbo fan 18, a bearing 28, and a bearing. It is equipped with a housing 29 and the like.

Note that the arrow DRa in FIG. 2 indicates the fan axis direction in which the axis of the rotating shaft 14 extends. The fan axis CL coincides with the axis of the rotating shaft 14. The fan axial direction DRa is also called the axial direction of the rotating shaft 14. An arrow DRr in FIG. 2 indicates a fan radial direction centered on the fan axis CL. The fan radial direction DRr is also referred to as the radial direction centered on the fan axis CL.

The scroll casing 12 is a housing of the centrifugal blower 10. Scroll casing 12 protects electric motor 16 and turbofan 18 from dust and dirt outside centrifugal blower 10 . The scroll casing 12 accommodates an electric motor 16 and a turbo fan 18 on the other side in the fan axis direction DRa with respect to an air inlet 221a, which will be described later.

Scroll casing 12 has a first casing member 22 and a second casing member 24. The first casing member 22 is made of a resin material. The first casing member 22 is formed into a substantially cylindrical shape.

Here, the first casing member 22 has a larger radial dimension than the turbo fan 18. The first casing member 22 has a cover case part 221 and a peripheral part 222.

The cover case portion 221 is disposed on one side of the turbo fan 18 in the fan axis direction DRa. Specifically, the cover case portion 221 is disposed on one side of the ring member 54 of the turbo fan 18 in the fan axis direction DRa. The cover case portion 221 is formed to cover the ring member 54 of the turbo fan 18 from one side in the fan axis direction DRa.

The cover case portion 221 forms an air inlet 221a that opens in the fan axis direction DRa. The air inlet 221a is a casing intake hole that sucks air into the scroll casing 12. Air is sucked into the turbo fan 18 through this air inlet 221a.

The cover case part 221 has a bell mouth part 221b that forms the periphery of the air inlet 221a. This bell mouth portion 221b smoothly guides air flowing into the air inlet 221a from the outside of the centrifugal blower 10 into the air inlet 221a. In other words, the bell mouth portion 221b forms the air inlet 221a.

The peripheral portion 222 is disposed on the outside in the radial direction with respect to the cover case portion 221 with respect to the fan axis CL. The peripheral portion 222 is formed in a circumferential direction centered on the fan axis CL.

The peripheral portion 222 constitutes an air outlet 222a that blows out the airflow blown out from the plurality of inter-blade flow paths 52a of the turbo fan 18 toward the other side in the fan axis direction DRa. The air outlet 222a is formed circumferentially around the fan axis CL.

The second casing member 24 is made of a resin material.

As shown in FIG. 2, the second casing member 24 also functions as a housing that covers the turbo fan 18 and the electric motor 16. The second casing member 24 is disposed on the other side of the turbo fan 18 and the electric motor 16 in the fan axis direction DRa.

The shroud 13 is arranged on one side of the scroll casing 12 in the fan axis direction DRa. The shroud 13 guides the airflow flowing from one side in the fan axis direction DRa so as to collect it at the air inlet 221a of the scroll casing 12.

Each of the rotating shaft 14 and the rotating shaft housing 15 is made of metal such as iron, stainless steel, or brass. The rotating shaft 14 is a bar member formed into a cylindrical shape centered on the fan axis CL.

The rotating shaft 14 is supported by a bearing 28 so as to be rotatable about the fan axis CL. Bearing 28 is supported by bearing housing 29. Bearing housing 29 is fixed to second casing member 24 . Therefore, the rotating shaft 14 is rotatably supported by the second casing member 24 via the bearing 28 and the bearing housing 29.

The rotating shaft housing 15 is fixed to one side of the rotating shaft 14 in the fan axis direction DRa. The rotating shaft housing 15 is fitted into an inner peripheral hole 56a of the main plate 56 of the turbo fan 18.

As a result, one side of the rotating shaft 14 in the fan axis direction DRa is supported by the main plate 56 of the turbo fan 18 . That is, the rotating shaft 14 and the rotating shaft housing 15 rotate integrally with the turbo fan 18 about the fan axis CL.

The electric motor 16 is an outer rotor type brushless DC motor. The electric motor 16 includes a rotor housing 161 and a stator 163.

The rotor housing 161 is disposed outside the stator 163 in the fan radial direction DRr. The rotor housing 161 is supported by the main plate 56 of the turbofan 18. The rotor housing 161 is formed into a cylindrical shape centered on the fan axis CL. The rotor housing 161 supports a plurality of permanent magnets 161a. The plurality of permanent magnets 161a are arranged in a circumferential direction centered on the fan axis CL.

Therefore, the rotor housing 161 and the plurality of permanent magnets 161a rotate integrally with the turbo fan 18 about the fan axis CL.

Stator 163 includes a stator coil and a stator core. The stator 163 is arranged radially inward with respect to the plurality of permanent magnets 161a with gaps between them and the fan axis CL.

Stator 163 is fixed to second casing member 24 via bearing housing 29 . In this way, the electric motor 16 is held by the second casing member 24 while being disposed inside the scroll casing 12 .

In the electric motor 16 configured as described above, when the stator coil of the stator 163 is energized from an external control circuit such as an inverter device, a rotating magnetic field is generated by the stator coil 163a. The rotating magnetic field generated by this stator coil 163a generates rotational force to the plurality of permanent magnets 161a.

Therefore, the rotor housing 161 rotates about the fan axis CL due to the rotational force generated in the plurality of permanent magnets 161a. Accordingly, the electric motor 16 is energized to rotate the turbo fan 18 to which the rotor housing 161 is fixed about the fan axis CL.

As shown in FIGS. 2 and 3, the turbo fan 18 is an impeller applied to the centrifugal blower 10. The turbo fan 18 is a centrifugal fan that rotates on one side DRf in the fan rotation direction about the fan axis CL in FIG. 3 .

That is, by rotating around the fan axis CL, the turbo fan 18 sucks air from one side in the fan axis direction DRa through the air inlet 221a and the fan intake port 54a, as indicated by the arrow FLm in FIG. In addition, the turbo fan 18 blows out the sucked air radially outward with respect to the turbo fan 18 about the fan axis CL.

Specifically, the turbofan 18 has a plurality of blades 52, a ring member 54, and a main plate 56. The plurality of wings 52, ring member 54, and main plate 56 are made of resin material.

The plurality of blades 52 are arranged at equal intervals in a circumferential direction centered on the fan axis CL. Specifically, the plurality of blades 52 are arranged in a line in the circumferential direction centering on the fan axis CL, with a space between them that allows air to flow. As shown in FIGS. 2 and 3, the plurality of blades 52 form a plurality of inter-blade flow paths 52a through which air flows between adjacent blades 52, respectively.

As shown in FIGS. 2, 4, and 5, the ring member 54 is disposed on one side of the plurality of blades 52 in the fan axial direction DRa. The ring member 54 is formed to cover the plurality of blades 52 from one side in the fan axis direction DRa. The ring member 54 is connected to one side of each of the plurality of blades 52 in the fan axis direction DRa.

The ring member 54 has a shape that expands into a disk shape in the fan radial direction DRr. The ring member 54 forms a fan intake port (that is, an air intake port) 54a on the inner circumferential side centered on the fan axis CL. That is, the ring member 54 has a fan intake port 54a and is formed in a ring shape centered on the fan axis CL.

The fan intake port 54a plays a role of guiding the air sucked into the air inlet 221a of the scroll casing 12 to the plurality of interblade flow paths 52a through an air flow path (that is, an intake ventilation path) 54f. The ring member 54 is connected to one side of each of the plurality of blades 52 in the fan axis direction DRa.

Specifically, the ring member 54 includes a cylindrical portion 54d and a curved portion 54e, as shown in FIG. The cylindrical portion 54d is a suction port forming portion formed in a cylindrical shape centered on the fan axis CL.

As shown in FIG. 2, the cylindrical portion 54d has an inner wall 540 formed on the radially inner side of the cylindrical portion 54d with the fan axis CL as the center. The inner wall 540 is formed to extend straight in the fan axial direction DRa.

Here, the inner wall 540 forms a fan intake port 54a and an air flow path 54f for guiding air taken in from the fan intake port 54a to the plurality of interblade flow paths 52a. The air flow path 54f is formed radially inward of the cylindrical portion 54d of the ring member 54 with the fan axis CL as the center.

In this embodiment, the air flow path 54f, together with a plurality of inter-blade flow paths 52a described later, forms a fan ventilation path that blows air flowing into the fan intake port 54a radially outward with the fan axis CL as the center. .

The curved portion 54e is disposed on the other side of the cylindrical portion 54d in the fan axis direction DRa. The curved portion 54e is formed to cover the plurality of blades 52 from one side in the fan axis direction DRa.

Therefore, the curved portion 54e is formed to cover the plurality of interblade flow paths 52a from one side in the fan axis direction DRa. That is, the curved portion 54e forms a plurality of inter-blade flow paths 52a together with the main plate 56 and the plurality of blades 52.

Specifically, as shown in FIG. 5, the curved portion 54e has a diameter centered on the fan axis CL as it goes from the other end of the cylindrical portion 54d in the fan axis direction DRa to the other side in the fan axis direction DRa. The directional dimension is larger.

Here, the radially inner side of the curved portion 54e centered on the fan axis CL forms a plurality of inter-blade flow paths 52a together with the main plate 56 and the plurality of blades 52, as shown in FIGS. 2 and 5. An inner wall 541 is formed.

The inner wall 541 of the curved portion 54e is formed in an arc shape convex toward the other side in the fan axis direction DRa in the ring member 54 including the fan axis CL. The inner wall 541 of the curved portion 54e is formed so as to smoothly move outward in the radial direction about the fan axis CL as it goes from one side to the other side in the fan axis direction DRa.

The ring member 54 and the cover case part 221 of this embodiment constitute a reverse flow path 300, which is a gap between them, as shown in FIG. The reverse flow path 300 is formed in an annular shape centered on the fan axis CL. The reverse flow path 300 constitutes a flow path that allows the air flow blown out from the outlet 400 of the plurality of inter-blade flow paths 52a to flow into the fan intake port 54a of the ring member 54, as indicated by the arrow FLf.

As shown in FIGS. 4 and 5, the inlet 300a of the reverse flow path 300 is disposed between the outer end of the ring member 54 in the fan radial direction DRr and the inner end of the peripheral portion 222 in the fan radial direction DRr. has been done.

Specifically, the inlet 300a of the reverse flow path 300 is formed in a portion adjacent to the outlet 400 of the plurality of interblade flow paths 52a. The outlet 300b of the reverse flow path 300 is arranged between the inner end of the ring member 54 in the fan radial direction DRr and the inner end of the cover case part 221 in the fan radial direction DRr.

The ring member 54 and the cover case part 221 constitute a labyrinth structure that configures the reverse flow path 300 in a labyrinth shape. This serves to suppress the airflow blown out from the plurality of interblade flow paths 52 a through the reverse flow path 300 from flowing into the fan intake port 54 a of the ring member 54 .

In this embodiment, in order to suppress the airflow from flowing backward through the reverse flow path 300, the ring member 54 is provided with a plurality of communication paths 310, 320, and 330, as will be described later. The cover case portion 221 is provided with a plurality of communication passages 340 and 350.

The main plate 56 is fixed to the rotary shaft 14 via the rotary shaft housing 15, which is rotatable about the fan axis CL. The main plate 56 is connected to the other side of each of the plurality of blades 52 in the fan axis direction DRa. The main plate 56 is formed so as to move from the inside to the outside in the fan radial direction DRr as it progresses from one side to the other side in the fan axial direction DRa.

In this embodiment, the ring member 54, together with the main plate 56 and the plurality of blades 52, constitutes an air flow path 54f and a plurality of inter-blade flow paths 52a.

Next, regarding the plurality of communication paths 310, 320, 330 in the ring member 54 of this embodiment and the plurality of communication paths 340, 350 in the cover case part 221, FIGS. 5, 6, 7, 8, 9, This will be explained with reference to FIGS. 10, 11, 12, 13, and 14.

First, the inlet 300a of the reverse flow path 300 is formed at a location adjacent to the outlet 400 of the plurality of inter-blade flow paths 52a, as shown in FIGS. 5 and 7.

The inlet 300a is formed between the inlet-side inner wall (that is, the inlet flow path wall) 300c of the peripheral portion 222 and the radially outer end of the ring member 54 centered on the fan axis CL. The inlet-side inner wall 300c is disposed on the outside of the ring member 54 in the fan radial direction DRr via the inlet 300a.

Here, as shown in FIG. 5, the inlet-side inner wall 300c forming the inlet 300a of the peripheral portion 222 is formed along the fan axis direction DRa in a cross-sectional view of the centrifugal blower 10 including the fan axis CL. ing. The inlet-side inner wall 300c guides air flowing into the inlet 300a from the outlet 400 of the plurality of inter-blade flow paths 52a to flow into the plurality of communication paths 310, as described later.

As shown in FIG. 7, the plurality of communication passages 310 are each formed by an inner wall 310a of the communication passage. The plurality of communication passage inner walls 310a are each formed so as to extend along the fan axis direction DRa continuously from the inlet side inner wall 300c in a cross-sectional view of the centrifugal blower 10 including the fan axis line CL.

Here, the plurality of communication passage inner walls 310a each guide the air flowing from the outlet 400 of the plurality of inter-blade flow passages 52a to the inlet 300a of the reverse flow passage 300 to the case outer cavity 500 as indicated by the arrow FRa in FIG. do.

That is, the plurality of communication passage inner walls 310a and the inlet side inner wall 300c guide the air flowing into the inlet 300a from the plurality of inter-blade flow passages 52a through the plurality of communication passages 310 to the case outer cavity 500.

The case outer cavity 500 is formed outside the cover case part 221 and between the cover case part 221 and the shroud 13. The case outer cavity 500 of this embodiment is open to the atmosphere. As shown in FIG. 6, the plurality of communication passages 310 are arranged at equal intervals in the circumferential direction with the fan axis CL as the center.
In this embodiment, the plurality of communication passages 320 in the ring member 54 communicate between the case outer cavity 500 and the backflow passage 300, respectively. Each of the plurality of communication passages 320 is opened on the outlet 300b side with respect to the plurality of communication passages 310 of the reverse flow passage 300. As shown in FIG. 8, the plurality of communication passages 320 are arranged at equal intervals in the circumferential direction centering on the fan axis CL.

Each of the plurality of communication passages 320 generates an air flow flowing from the case outer cavity 500 into the reverse flow passage 300, as indicated by FRb in FIG. Specifically, the communication passage inner walls 320a forming the plurality of communication passages 320 in the ring member 54 are each formed continuously from the labyrinth wall 410 of the reverse flow passage 300 along the fan axis direction DRa.

As shown in FIGS. 5 and 9, the labyrinth wall 410 of the reverse flow path 300 is a part of an inner wall that constitutes a labyrinth structure that forms the reverse flow path 300 in a labyrinth shape, and is formed along the fan axis direction DRa. has been done. The labyrinth wall 410 guides the air flowing from the inlet 300a toward the outlet 300b in the reverse flow path 300 so as to flow along the fan axis direction DRa as indicated by the arrow FRc.

The communication passage inner wall 320a of the ring member 54 of this embodiment guides the air flowing from the case outer cavity 500 to the backflow path 300 so as to collide with the air flowing along the labyrinth wall 410 of the backflow path 300. do.

In this embodiment, the plurality of communication passages 330 in the ring member 54 communicate between the case outer cavity 500 and the backflow passage 300, respectively. Each of the plurality of communication passages 330 is opened on the outlet 300b side with respect to the plurality of communication passages 320 among the reverse flow passages 300.

As shown in FIG. 10, the plurality of communication passages 330 are arranged at equal intervals in the circumferential direction centering on the fan axis CL. Each of the plurality of communication passages 330 allows air to flow from the case outer cavity 500 toward the reverse flow passage 300. Each of the plurality of communication paths 330 generates air that collides with the air flowing from the inlet 300a toward the outlet 300b in the reverse flow path 300.

The plurality of communication passages 340 in the cover case part 221 of this embodiment are provided in the cylindrical part 54d of the ring member 54. As shown in FIG. 11, the plurality of communicating passages 340 are arranged at equal intervals in the circumferential direction with the fan axis CL as the center.

Each of the plurality of communication paths 340 communicates with the air flow path 54f and the reverse flow path 300. Each of the plurality of communication paths 340 generates an air flow flowing from the air flow path 54f to the reverse flow path 300, as indicated by an arrow FLd in FIG.

The plurality of communication paths 350 in the cover case portion 221 are each provided in the curved portion 54e of the ring member 54. As shown in FIG. 12, the plurality of communicating passages 350 are arranged at equal intervals in the circumferential direction with the fan axis CL as the center.

Each of the plurality of communication passages 350 communicates between the corresponding inter-blade flow passage 52a among the plurality of inter-blade flow passages 52a and the reverse flow passage 300. Each of the plurality of communication passages 350 generates an airflow that flows from the reverse flow passage 300 into the corresponding inter-blade flow passage 52a of the plurality of inter-blade flow passages 52a, as indicated by the arrow FLe in FIG.

Here, when the turbo fan 18 rotates to one side DRf in the rotation direction and blows out the air sucked in through the inter-blade flow path 52a, as shown in FIG. Negative pressure is generated in region 520 on one side. On the other hand, positive pressure is generated in the region 521 on the other side of the interblade flow path 52a.

Here, the region 520 on one side is formed on one side DRf of the inter-blade flow path 52a in the rotational direction with respect to the centerline ST in the rotational direction. The other side region 521 is formed on the other side of the inter-blade flow path 52a in the rotational direction with respect to the centerline ST in the rotational direction.

The center line ST is a portion of the plurality of wings 52 that is the same distance from one wing 52 and the other wing 52 among two adjacent wings 52.

Therefore, the static pressure in the region 520 on one side of the interblade flow path 52a is lower than in the region 521 on the other side.

In contrast, in the present embodiment, the communication passage 350 communicates between the region 520 on one side of the inter-blade passage 52a and the reverse passage 300. Therefore, compared to the case where the communication passage 350 communicates between the region 521 on the other side of the inter-blade flow passage 52a and the reverse flow passage 300, the communication passage 350 connects the reverse flow passage 300 to the inter-blade flow passage 52a. The amount of flowing air can be increased.

Next, the operation of the centrifugal blower 10 of this embodiment will be explained.

First, the electric motor 16 is energized to rotate the turbo fan 18 about the fan axis CL via the rotating shaft 14 . Therefore, the turbo fan 18 sucks air from one side in the fan axis direction DRa. In this case, air is collected by the shroud 13 from one side in the fan axial direction DRa, and the collected air passes through the air inlet 221a, the fan intake port 54a, and the air flow path 54f as a main stream to the plurality of inter-blade flow paths 52a. There will be an influx.

At this time, the centrifugal force of the turbo fan 18 causes the air to be blown out from the plurality of inter-blade flow paths 52a to the outside in the radial direction around the fan axis CL. This blown air is guided by the peripheral portion 222 and flows toward the other side in the fan axis direction DRa.

At this time, the pressure near the outlet 400 of the plurality of interblade flow paths 52a becomes higher than atmospheric pressure. On the other hand, the pressure near the air inlet 221a and fan intake port 54a of the cover case portion 221 is lower than atmospheric pressure.

Therefore, a part of the air blown out from the outlet 400 of the plurality of inter-blade flow paths 52a is blown out from the outlet 300b through the reverse flow path 300, as indicated by the arrow FLf in FIG. This blown air flows into the plurality of inter-blade flow paths 52a through the air inlet 221a, the fan intake port 54a, and the air flow path 54f.

At this time, when air flows into the reverse flow path 300, a pressure loss occurs due to the labyrinth structure constituted by the ring member 54 and the cover case part 221 described above.

Here, a part of the air flowing from the outlet 400 of the plurality of inter-blade flow paths 52a to the inlet 300a of the reverse flow path 300 is transferred to the inlet side inner wall 300c and the plurality of communication path inner walls, as shown by the arrow FKLa in FIGS. 5 and 7. 310a and flows into the case outer cavity 500.

That is, a portion of the air flowing from the outlet 400 of the plurality of inter-blade flow paths 52a to the inlet 300a of the reverse flow path 300 flows into the case outer cavity 500 through the plurality of communication paths 310. The case outer cavity 500 of this embodiment is open to the atmosphere.

On the other hand, among the air flowing from the outlet 400 of the plurality of inter-blade flow paths 52a to the inlet 300a of the reverse flow path 300 of the reverse flow path 300, the remaining air other than the air flowing into the case outer cavity 500 through the plurality of communication paths 310, It flows toward the outlet 300b of the reverse flow path 300.

At this time, a pressure loss occurs due to the labyrinth structure constituted by the ring member 54 and the cover case part 221. Therefore, the static pressure near the plurality of communication paths 320 in the reverse flow path 300 becomes lower than atmospheric pressure. Therefore, air flows from the case outer cavity 500 into the reverse flow path 300 through the plurality of communication paths 320.

Specifically, air flows from the case outer cavity 500 into the backflow path 300 along each of the plurality of communication path inner walls 320a, as indicated by arrow FLb in FIG. That is, air from the case outer cavity 500 is guided by the plurality of communication passage inner walls 320a and flows in the fan axis direction DRa, so that the air flows from the case outer cavity 500 into the reverse flow passage 300.

On the other hand, air flowing from the inlet 300a to the outlet 300b side of the backflow path 300 flows along the labyrinth wall 410 of the backflow path 300 on one side in the fan axis direction DRa, as indicated by the arrow FLc.

Therefore, the air flowing from the case outer cavity 500 to the backflow path 300 along the communication path inner wall 320a of each communication path 320 flows from the inlet 300a of the backflow path 300 toward the outlet 300b side. collide with the air.

That is, the air flowing from the inlet 300a toward the outlet 300b of the backflow path 300 collides with the air flowing into the backflow path 300 from the case outer cavity 500 through the plurality of communication paths 320. Therefore, a pressure loss occurs in the air flowing from the inlet 300a toward the outlet 300b in the reverse flow path 300.

Further, the static pressure near the plurality of communication paths 330 in the reverse flow path 300 may become lower than atmospheric pressure due to the pressure loss caused by the labyrinth structure described above.

In this case, an air flow is generated that flows from the case outer cavity 500 to the reverse flow path 300 through the plurality of communication paths 330. Therefore, the air flowing from the case outer cavity 500 to the backflow path 300 through the plurality of communication paths 330 collides with the air flowing from the inlet 300a to the outlet 300b side of the backflow path 300.

Therefore, the airflow flowing from the case outer cavity 500 to the backflow path 300 through the plurality of communication paths 330 can cause a pressure loss in the air flowing from the inlet 300a to the outlet 300b side of the backflow path 300.

Further, when the air sucked from the air inlet 221a and the fan intake port 54a flows through the air flow path 54f, the air flows at high speed along the inner wall 540 of the cylindrical portion 54d of the ring member 54 in the other direction of the fan axis direction DRa. flows to the side.

Therefore, the static pressure near the inner wall 540 of the cylindrical portion 54d of the ring member 54 is higher than the static pressure within the reverse flow path 300. Therefore, an air flow is generated that flows from the air flow path 54f of the cylindrical portion 54d of the ring member 54 into the reverse flow path 300 through the plurality of communicating paths 340 as indicated by the arrow FLd in FIG.

Thereby, the air flowing from the air flow path 54f through the plurality of communication paths 340 into the reverse flow path 300 can collide with the air flowing from the inlet 300a toward the outlet 300b in the reverse flow path 300. Therefore, pressure loss can be generated in the air flowing from the inlet 300a toward the outlet 300b in the reverse flow path 300.

Further, as described above, the curved portion 54e of the ring member 54 extends outward in the fan radial direction DRr from the end of the cylindrical portion 54d on the other side in the fan axial direction DRa toward the other side in the fan axial direction DRa. It is formed.

On the other hand, the air flowing from the air flow path 54f to the plurality of inter-blade flow paths 52a separates from the inner wall 541 of the curved portion 54e and flows. Therefore, the static pressure near the inner wall 541 of the curved portion 54e among the plurality of interblade flow paths 52a is lower than the static pressure in the reverse flow path 300. Therefore, an air flow is generated that flows from inside the reverse flow path 300 to the plurality of inter-blade flow paths 52a through the plurality of communicating paths 350, as indicated by the arrow FLe in FIG.

According to the present embodiment described above, the centrifugal blower device 10 is formed to extend in the fan axis direction DRa, and rotates about the fan axis CL, when the direction in which the fan axis CL extends is the fan axis direction DRa. A rotating shaft 14 is provided. The centrifugal blower 10 includes a turbo fan 18 as a centrifugal fan that is supported by a rotating shaft 14 and rotates together with the rotating shaft 14 .

The centrifugal blower 10 has an air inlet 221a that opens on one side in the fan axis direction DRa, and a scroll housing the turbo fan 18 and the rotating shaft 14 on the other side of the fan axis direction DRa with respect to the air inlet 221a. A casing 12 is provided.

The turbo fan 18 has a plurality of blades 52 arranged at equal intervals in a circumferential direction centered on the fan axis CL, and is arranged on one side of the fan axis direction DRa with respect to the plurality of blades 52. A ring member 54 is provided.

The ring member 54 has a fan intake port 54a through which air passing through the air inflow port 221a is taken in, and is formed in an annular shape centered on the fan axis CL, and has a fan axis direction DRa of each of the plurality of blades 52. is connected to one side of the

The turbo fan 18 includes a main plate 56 that is disposed on the other side of the plurality of blades 52 in the fan axis direction DRa and that is connected to the other side of each of the plurality of blades 52 in the fan axis direction DRa. .

The main plate 56, the ring member 54, and the plurality of blades 52 form an air flow path 54f and a plurality of inter-blade flow paths 52a. The air flow path 54f and the plurality of inter-blade flow paths 52a constitute a fan ventilation path.

As the turbo fan 18 rotates, it blows air sucked in through the air inlet 221a and the fan intake port 54a radially outward about the fan axis CL through the air flow path 54f and the plurality of interblade flow paths 52a.

The scroll casing 12 has a cover case portion 221 formed to cover the ring member 54 from one side in the fan axis direction DRa. The ring member 54 and the cover case part 221 form a reverse flow path 300 which is a gap therebetween. A case outer cavity 500 is provided on the outer side of the cover case portion 221.

The ring member 54 and the cover case part 221 are configured as shown in (a) to (d) in order to suppress the air blown out from the plurality of inter-blade flow paths 52a from flowing into the fan intake port 54a through the reverse flow path 300. and has a plurality of communication paths 310, 320, 330, 340, and 350.

(a) The ring member 54 includes a plurality of communication passages 310 that communicate between the reverse flow path 300 and the case outer cavity 500 and allow air to flow from the reverse flow passage 300 to the case outer cavity 500.

This allows air to flow out from the reverse flow path 300 to the case outer cavity 500 through the plurality of communication paths 310 . Therefore, it is possible to reduce the flow rate of the air blown out from the plurality of inter-blade flow paths 52a through the reverse flow path 300 and flowing back to the fan intake port 54a of the turbo fan 18.

(b) The ring member 54 has a plurality of communication passages 320 and a plurality of communication passages 330 that communicate between the case outer cavity 500 and the reverse flow passage 300 and allow air to flow from the case outer cavity 500 into the reverse flow passage 300. Be prepared.

As a result, the plurality of communication passages 320 and the plurality of communication passages 330 allow the air flowing from the case outer cavity 500 to the backflow path 300 to be directed from the air flowing inside the backflow path 300 from the inlet 300a to the outlet 300b. can be caused to collide. Therefore, pressure loss can be imparted to the air flowing in the reverse flow path 300 from the inlet 300a to the outlet 300b.

(c) The cylindrical portion 54d of the ring member 54 includes a plurality of communicating paths 340 that communicate between the reverse flow path 300 and the air flow path 54f and allow air to flow from the air flow path 54f to the reverse flow path 300.

Thereby, the air flowing into the reverse flow path 300 from the air flow path 54f by the plurality of communicating paths 340 can be made to collide with the air flowing inside the reverse flow path 300 from the inlet 300a toward the outlet 300b. Therefore, pressure loss can be imparted to the air flowing in the reverse flow path 300 from the inlet 300a to the outlet 300b.

(d) The inner wall 541 of the curved portion 54e is formed in an arc shape convex toward the other side in the fan axis direction DRa in the ring member 54 including the fan axis CL. The inner wall 541 forms a plurality of inter-blade flow paths 52a together with the main plate 56 and the plurality of blades 52.

The inner wall 541 of the curved portion 54e is formed so as to smoothly move outward in the radial direction about the fan axis CL as it goes from one side to the other side in the fan axis direction DRa.

Here, the curved portion 54e includes a plurality of communication paths 350 that communicate between the reverse flow path 300 and the inter-blade flow path 52a and allow air to flow from the reverse flow path 300 to the inter-blade flow path 52a.

Thereby, air can be circulated from the reverse flow path 300 to the interblade flow path 52a through the plurality of communication paths 350. Therefore, the flow rate of air flowing from the reverse flow path 300 to the fan intake port 54a of the ring member 54 can be reduced.

As described above, the flow rate of air flowing from the reverse flow path 300 to the fan intake port 54a of the ring member 54 can be reduced, and pressure loss can be applied to the air flowing from the reverse flow path 300 to the fan intake port 54a of the ring member 54.

Therefore, the air turbulence caused by mixing the air flowing from the reverse flow path 300 to the fan intake port 54a with the main flow of air flowing from one side of the fan axis direction DRa to the air inlet 221a and the fan intake port 54a. The occurrence can be suppressed. Therefore, it is possible to suppress a decrease in blower efficiency and generation of noise.

In this embodiment configured in this way, the following effects (e), (f), (g), and (h) can be obtained.

(e) The plurality of communication passages 310 are arranged in the circumferential direction with the fan axis CL as the center. The plurality of communicating passages 320 are each arranged in a circumferential direction centering on the fan axis CL. The plurality of communication passages 330 are each arranged in a circumferential direction centering on the fan axis CL.

The plurality of communicating passages 340 are each arranged in a circumferential direction centering on the fan axis CL. The plurality of communicating passages 350 are each arranged in a circumferential direction centering on the fan axis CL. This makes it possible to equalize the static pressure distribution in the circumferential direction around the fan axis CL in the reverse flow path 300.

(f) The cover case portion 221 has a communication passage inner wall 310a that forms a communication passage 310. The scroll casing 12 is disposed radially outward from the ring member about the axis, and has an inlet-side inner wall 300c that forms an inlet 300a of the reverse flow path 300 together with the ring member 54.

The inlet side inner wall 300c is formed along the fan axis direction DRa.

The communication passage inner wall 310a is formed continuously from the inlet-side inner wall 300c along the fan axis direction DRa (i.e., a predetermined direction), and guides the air flowing from the inlet 300a along the inlet-side inner wall 300c to the case outer cavity. do.

Therefore, the air flowing into the reverse flow path 300 from the inlet 300a can smoothly flow out into the case outer cavity 500.

(g) The cover case portion 221 constitutes a labyrinth wall 410 that is formed along the fan axis direction DRa (ie, a predetermined direction) in order to configure the reverse flow path 300 in a maze shape. The cover case portion 221 has a communication passage inner wall 320a that is formed continuously from the labyrinth wall 410 along the fan axis direction DRa and forms a communication passage 320.

The communication path inner wall 320a guides the air flowing into the backflow path 300 from the case outer cavity 500 so that it collides with the air flowing along the labyrinth wall 410 in the backflow path 300. Therefore, the air flowing into the backflow path 300 from the case outer cavity 500 can smoothly collide with the air flowing along the labyrinth wall 410 in the backflow path 300.

(h) When the turbo fan 18 rotates to one side DRf in the rotation direction and blows out the air sucked in through the inter-blade flow path 52a, negative pressure is generated in the region 520 on one side of the inter-blade flow path 52a. Occur. The region 520 on one side is a region formed on one side DRf in the rotational direction with respect to the centerline ST in the rotational direction in the inter-blade flow path 52a.

On the other hand, positive pressure is generated in the region 521 on the other side of the interblade flow path 52a. The other side region 521 is a region formed on the other side of the inter-blade flow path 52a in the rotational direction with respect to the center line ST. Therefore, the static pressure in the region 520 on one side of the interblade flow path 52a is lower than in the region 521 on the other side.

Therefore, the communication path 350 communicates between the region 520 on one side of the inter-blade flow path 52a and the reverse flow path 300. Therefore, compared to the case where the communication passage 350 communicates between the region 521 on the other side of the inter-blade flow passage 52a and the reverse flow passage 300, the communication passage 350 connects the reverse flow passage 300 to the inter-blade flow passage 52a. The amount of flowing air can be increased.

Therefore, air turbulence occurs due to the air flowing from the reverse flow path 300 to the fan intake port 54a being mixed with the main flow of air flowing from one side of the fan axis direction DRa to the air inlet 221a and the fan intake port 54a. The occurrence of this can be further suppressed.

(Second embodiment)
In the first embodiment described above, an example has been described in which a plurality of communicating passages 350 are provided in the curved portion 54e of the ring member 54. However, instead of this, a second embodiment of the centrifugal blower 10 in which a plurality of communication passages 350a and a plurality of communication passages 350b are provided in the curved portion 54e of the ring member 54 will be described with reference to FIG.

This embodiment includes a plurality of communication passages 350a and a plurality of communication passages 350b in place of the plurality of communication passages 350 in the curved portion 54e of the ring member 54 of the first embodiment. The plurality of communication passages 350a and the plurality of communication passages 350b communicate between the reverse flow passage 300 and the plurality of interblade flow passages 52a, respectively. This embodiment is different from the first embodiment except for the plurality of communication passages 350a and the plurality of communication passages 350b, and the other configurations are the same.

Therefore, in this embodiment, the plurality of communication paths 350a and the plurality of communication paths 350b will be mainly described.

In a cross-sectional view of the ring member 54 including the fan axis CL, as shown in FIG. 14, a changing point 600 is provided on the inner wall 541 of the curved portion 54e that forms the plurality of interblade flow paths 52a.

The inner wall 541 is formed so as to move smoothly outward in the radial direction about the fan axis CL from the other end of the inner wall 540 of the cylindrical portion 54d in the fan axis direction DRa toward the other side in the fan axis direction DRa. has been done.

In this embodiment, in a cross-sectional view of the ring member 54 including the fan axis CL, the narrow angle formed between the tangent to the inner wall 541 and the fan axis, which is the axis of the rotating shaft 14, is defined as an inner wall angle. Here, the narrow angle (that is, the inner wall angle) is set to be greater than or equal to 0 degrees and less than 90 degrees.

The inner wall angle α1 formed between the tangent S1 of the inner wall 541 that is in contact with the change point 600 and the fan axis CLa is 3.5 degrees.

In this embodiment, the inner wall angle of the inner wall 541 becomes smaller than 3.5 degrees as it goes from the change point 600 to one side in the fan axis direction DRa. On the other hand, the inner wall angle becomes larger than 3.5 degrees from the change point 600 of the inner wall 541 toward the other side in the fan axis direction DRa.

However, "3.5 degrees" may be any angle within a predetermined range that takes into account general manufacturing errors, and is not limited to the strictly determined "3.5 degrees."

In the turbo fan 18 of the centrifugal blower 10 configured in this manner, an air flow that separates from the inner wall 541 may occur near the inner wall 541 of the curved portion 54e among the plurality of inter-blade flow paths 52a. Generally, the larger the inner wall angle is, the more likely airflow that separates from the inner wall 541 will occur.

In particular, separation of the airflow from the inner wall 541 of the curved portion 54e is likely to occur on the other side of the fan axis direction DRa than the change point 600 in the vicinity of the inner wall 541 of the curved portion 54e in the plurality of inter-blade flow paths 52a. That is, in the vicinity of the inner wall 541 of the curved portion 54e, on the downstream side of the airflow from the change point 600, separation of the airflow is particularly likely to occur.

Therefore, in this embodiment, the plurality of communication passages 350a are each formed to open on the other side of the inner wall 541 of the curved portion 54e of the ring member 54 in the fan axis direction DRa than the change point 600. The plurality of communication passages 350a are arranged at equal intervals in the circumferential direction with the fan axis CL as the center.

Here, in the inter-blade flow path 52a, in the vicinity of the inner wall 541 of the curved portion 54e of the ring member 54, the area on the other side of the fan axis direction DRa from the change point 600 has more separation of airflow than in the reverse flow path 300. As a result, the static pressure becomes low. Therefore, each of the plurality of communication passages 350a generates an airflow flowing from inside the reverse flow passage 300 toward the plurality of inter-blade flow passages 52a.

In the present embodiment configured in this manner, each of the plurality of communication passages 350a directs air from the reverse flow passage 300 to the area on the other side in the fan axis direction DRa from the change point 600 in the vicinity of the inner wall 541 of the curved portion 54e. It can flow.

Therefore, the plurality of communication passages 350a directs the airflow from the reverse flow passage 300 to the airflow separation area formed in the area on the other side of the fan axis direction DRa from the change point 600 in the vicinity of the inner wall 541 of the curved portion 54e. can be supplied.

Further, in the present embodiment, each of the plurality of communication passages 350b is formed to open in a region on one side of the inner wall 541 of the curved portion 54e of the ring member 54 from the change point 600 in the fan axis direction DRa. . The plurality of communication passages 350b are arranged in the circumferential direction with the fan axis CL as the center.

Here, in the inter-blade flow path 52a, also in a region on one side of the fan axis direction DRa from the change point 600 in the vicinity of the inner wall 541 of the curved portion 54e, separation of the air flow occurs, compared to the inside of the reverse flow path 300. As a result, static pressure decreases.

Therefore, the plurality of communication passages 350b can be supplied from the reverse flow passage 300 to a region on one side of the inner wall 541 of the curved portion 54e in the fan axis direction DRa than the change point 600. Accordingly, this supplied air flow is supplied to the other side region of the inner wall 541 in the fan axis direction DRa than the change point 600.

As a result, air is blown out from the plurality of communication passages 350b to the air separation region formed upstream of the change point 600 and the air separation region formed downstream of the change point 600 in the inner wall 541. Air can be supplied.

According to the present embodiment described above, in the cross section of the ring member 54 that includes the fan axis, the inner wall 541 has a change point 600 where the inner wall angle α1 becomes 3.5 degrees. The inner wall angle becomes smaller toward one side of the inner wall 541 from the change point 600 in the fan axis direction DRa. The inner wall angle increases from the change point 600 of the inner wall 541 toward the other side in the fan axis direction DRa.

In the cross section of the ring member 54 that includes the fan axis CL, the narrow angle formed between the tangent of the curved portion 54e that is in contact with the inner wall 541 forming the interblade flow path 52a and the fan axes CLa, CLb, and CLc is defined as the inner wall. Let it be a corner.

The plurality of communication passages 350a are each formed to open on the other side of the inner wall 541 of the curved portion 54e of the ring member 54 in the fan axis direction DRa than the change point 600. Therefore, each of the plurality of communication passages 350a directs airflow from the reverse flow passage 300 to an airflow separation region formed on the other side of the fan axis direction DRa than the change point 600 of the inner wall 541 of the curved portion 54e. can be supplied.

The plurality of communication passages 350b are each formed to open a region on one side of the inner wall 541 of the curved portion 54e of the ring member 54 in the fan axis direction DRa from the change point 600. Therefore, the plurality of communication passages 350b supply airflow from the reverse flow passage 300 to a region on one side of the inner wall 541 of the curved portion 54e in the fan axis direction DRa than the change point 600.

Thereby, airflow can be supplied from a region on one side of the inner wall 541 in the fan axis direction DRa than the change point 600 to an airflow separation region formed in a region on the other side of the fan axis direction DRa.

As described above, the fan efficiency of the turbo fan 18 is improved by supplying airflow to the airflow separation regions formed on one side and the other side of the fan axis direction DRa from the change point 600 of the inner wall 541. can be done.

(Third embodiment)
In the centrifugal blower 10 of the third embodiment, FIG. 15 shows an example in which a discharge flow path 300d is added to the centrifugal blower 10 of the first embodiment to release a part of the air flowing out from the reverse flow path 300 to the atmosphere. Refer to and explain.

The centrifugal blower device 10 of this embodiment has a configuration in which a discharge channel 300d is added to the centrifugal blower device 10 of the first embodiment, and the configuration other than the discharge channel 300d is the same as that of the first embodiment. They are essentially the same. Therefore, in this embodiment, the discharge channel 300d will be mainly described.

In this embodiment, the scroll casing 12 includes a cover case part 221c formed to cover the cover case part 221. The cover case portion 221c is formed in an annular shape centered on the fan axis CL. Therefore, the discharge channel 300d is arranged between the cover case part 221c and the cover case part 221. The discharge flow path 300d is formed in an annular shape centered on the fan axis CL.

The radially inner side of the discharge flow path 300d centered on the fan axis CL is communicated with the radially inner side of the reverse flow path 300 centered on the fan axis CL. The radially outer side of the discharge flow path 300d centered on the fan axis CL is open to the atmosphere.

In this embodiment, the outlet 300b of the reverse flow path 300 is formed between the cover case part 221c and the cylindrical part 54d of the ring member 54.

Next, the operation of the centrifugal blower 10 of this embodiment will be explained with reference to FIG. 15.

First, as the turbo fan 18 rotates, air taken in from one side in the fan axial direction DRa through the air inlet 221a and the fan intake port 54a is transferred into a plurality of inter-blade flows. Blows out through outlet 400 of channel 52a.

At this time, a part of the air flowing out from the outlet 400 of the plurality of inter-blade flow paths 52a flows into the reverse flow path 300 from the inlet 300a, and this inflowing air flows within the reverse flow path 300 toward the outlet 300b. A part of the air flowing through the reverse flow path 300 is blown out from the outlet 300b as indicated by an arrow FTa, and this blown air flows into the plurality of inter-blade flow paths 52a through the fan intake port 54a.

Here, if the static pressure near the outlet 300b in the backflow path 300 is higher than atmospheric pressure, the rest of the air flowing in the backflow path 300 other than a part of the air flowing from the outlet 300b to the fan intake port 54a. The air flows into the atmosphere through the discharge channel 300d as indicated by the arrow FTb.

According to this embodiment described above, the centrifugal blower device 10 releases a part of the air flowing out from the reverse flow path 300 to the atmosphere through the release flow path 300d. Therefore, the flow rate of air flowing from the reverse flow path 300 to the air flow path 54f through the fan intake port 54a can be reduced.

Therefore, the air turbulence caused by mixing the air flowing from the reverse flow path 300 to the fan intake port 54a with the main flow of air flowing from one side of the fan axis direction DRa to the air inlet 221a and the fan intake port 54a. The occurrence can be suppressed. Therefore, it is possible to suppress a decrease in blower efficiency and generation of noise.

(Fourth embodiment)
In the fourth embodiment, in the cylindrical portion 54d of the ring member 54 of the centrifugal blower 10 of the first embodiment, a guide portion 54k guides the air flowing through the reverse flow path 300 to the outside in the radial direction around the fan axis CL. An example will be described with reference to FIG. 16.

The centrifugal blower 10 of this embodiment has a configuration in which a guide portion 54k is added to the cylindrical portion 54d of the ring member 54 of the centrifugal blower 10 of the first embodiment. Therefore, in the centrifugal blower 10 of this embodiment, the vicinity of the guide portion 54k of the ring member 54 will be mainly described below.

The guide portion 54k is formed to protrude outward in the radial direction about the fan axis CL from one end of the cylindrical portion 54d of the ring member 54 in the fan axis direction DRa. The guide portion 54k plays a role of guiding the air flowing through the reverse flow path 300 from the inlet 300a toward the outlet 300b to the outside in the radial direction about the fan axis CL. The cylindrical portion 54d constitutes an inlet forming portion that forms the fan inlet 54a.

Here, a communication hole 300e is provided between the guide portion 54k and the cover case portion 221, which communicates between the inside of the reverse flow path 300 and the case outer cavity 500. The case outer cavity 500 of this embodiment is open to the atmosphere.

Next, the operation of the centrifugal blower 10 of this embodiment will be explained.

First, as in the first embodiment, as the turbofan 18 rotates, a portion of the air flowing out from the outlet 400 of the plurality of interblade flow paths 52a flows into the reverse flow path 300 from the inlet 300a, and this inflow The air flows inside the reverse flow path 300 toward the outlet 300b.

The air flowing in this reverse flow path 300 is guided by the guide portion 54k so as to flow outward in the radial direction around the fan axis CL.

This guided air is led to the case outer cavity 500 through the communication hole 300e, as indicated by the arrow FTc. That is, the guide portion 54k guides the air flowing in the reverse flow path 300 to the atmosphere through the communication hole 300e and the case outer cavity 500.

According to the present embodiment described above, the ring member 54 includes the cylindrical portion 54d that forms the fan intake port 54a, and the guide portion 54k that is formed to protrude outward in the fan radial direction DRr from the cylindrical portion 54d. Be prepared.

A communication hole 300e is formed between the guide portion 54k and the cover case portion 221, which communicates between the case outer space 500 and the inside of the reverse flow path 300.

The guide portion 54k guides the air flowing from the inlet 300a to the outlet 300b of the reverse flow path 300 to the outside of the fan radial direction DRr, thereby directing the air flowing in the reverse flow path 300 to the atmosphere through the communication hole 300e and the case outer cavity 500. It is designed to guide you towards. Therefore, the flow rate of air flowing from the reverse flow path 300 to the fan intake port 54a can be reduced.

Therefore, similar to the first embodiment, air flowing from the reverse flow path 300 to the fan intake port 54a is mixed with the main flow of air flowing from one side in the fan axis direction DRa to the air inlet 221a and the fan intake port 54a. It is possible to suppress the occurrence of air turbulence.

(Fifth embodiment)
In the first embodiment, each of the plurality of communication passage inner walls 310a is formed continuously from the inlet side inner wall 300c along the fan axis direction DRa in the cross-sectional view of the centrifugal blower 10 including the fan axis CL. I explained an example.

However, instead of this, in the sectional view of the centrifugal blower 10 including the fan axis CL, the present fifth embodiment is such that the plurality of communication passage inner walls 310a are formed to be inclined at an angle β1 with respect to the fan axis CLd. This will be explained with reference to FIG.

In the present embodiment, the plurality of communication passage inner walls 310a are each formed such that the passage cross-sectional area of the communication passage 310 increases as it advances from the other side to the one side in the fan axis direction DRa. The cross-sectional area of the communication passage 310 is the area of a cross section perpendicular to the axis Ta of the communication passage 310. The angle β1 is set to 45 degrees or less.

In this embodiment configured in this way, when air flows from the reverse flow path 300 to the outside of the cover case portion 221 through the plurality of communication paths 310, it is possible to prevent the communication path inner wall 310a from interfering with the air flow. can.

(Sixth embodiment)
In the first embodiment, an example has been described in which the communication passage inner wall 320a of each communication passage 320 is formed along the fan axis direction DRa from the labyrinth wall 410 of the reverse flow passage 300.

However, instead of this, in the cross-sectional view of the centrifugal blower 10 including the fan axis CL, the sixth embodiment is such that the communication passage inner wall 320a of each communication passage 320 is formed to be inclined with respect to the fan axis CLe. This will be explained with reference to FIG.

In this embodiment, the plurality of communication passage inner walls 320a are each formed such that the flow passage cross-sectional area of the communication passage 310 increases as it advances from the other side to the one side in the fan axis direction DRa. The cross-sectional area of the communication passage 320 is the area of a cross section of the communication passage 320 perpendicular to the axis Tb.

In this embodiment, air flows from the case outer cavity 500 into the backflow path 300 along the communication path inner wall 320a as shown by the arrow FLb in FIG. The air flowing to one side in the fan axis direction DRa collides with the fan.
At this time, the air flowing from the case outer cavity 500 into the backflow path 300 along the communication path inner wall 320a is different from the air flowing in the backflow path 300 along the labyrinth wall 410 to one side in the fan axis direction DRa. Can give pressure loss.
Here, a formation is formed between the air flowing from the case outer cavity 500 into the backflow path 300 along the communication path inner wall 320a and the air flowing to one side in the fan axis direction DRa along the labyrinth wall 410 of the backflow path 300. Let the angle β2 be the angle β2.
In this embodiment, the plurality of communication passage inner walls 320a are formed so that the angle β2 is a narrow angle of less than 90 degrees.
In this case, compared to the case where the angle β2 is 90 degrees or more, the air flowing from the case outer cavity 500 into the reverse flow path 300 is more sensitive to the air flowing along the labyrinth wall 410 to one side of the fan axis direction DRa. The pressure loss can be increased.
Thereby, the volume of air flowing from the inlet 300a to the outlet 300b in the backflow path 300 can be reduced. Therefore, the amount of air flowing into the fan intake port 54a through the reverse flow path 300 can be reduced.

(Seventh embodiment)
In the first embodiment, an example has been described in which the plurality of communication passage inner walls 350c forming the plurality of communication passages 350 in the ring member 54 are formed along the fan axis direction DRa.

However, instead of this, in the sectional view of the centrifugal blower 10 including the fan axis CL, the seventh embodiment is such that the plurality of communication passage inner walls 350c are formed to be inclined at an angle β3 with respect to the fan axis CLf. This will be explained with reference to FIG.

In the present embodiment, the plurality of communication passage inner walls 350c are each formed such that the passage cross-sectional area of the communication passage 350 increases as it advances from the other side to the one side in the fan axis direction DRa. The cross-sectional area of the communication passage 350 refers to the area of a cross section of the communication passage 350 perpendicular to the axis Tc. The angle β3 is set to be greater than zero degrees and less than 90 degrees.

In this embodiment configured in this way, it is possible to suppress air from flowing backward from the inter-blade flow path 52a to the reverse flow path 300 through the plurality of communication paths 350.

(Eighth embodiment)
In the first embodiment described above, an example has been described in which the case outer space 500 is open to the atmosphere. However, instead of this, an eighth embodiment in which the case outer cavity 500 is configured to be closed will be described with reference to FIG. 20.

In the centrifugal blower device 10 of this embodiment, as shown in FIG. 20, the scroll casing 12 includes a lid portion 500a that closes the case outer cavity 500. The lid portion 500a connects the peripheral edge portion 222 of the first casing member 22 and the shroud 13, thereby forming the case outer cavity 500 into a closed space.

The total flow passage cross-sectional area GA, which is the sum of the flow passage cross-sectional areas of the plurality of communication passages 320 and the flow passage cross-section areas of the plurality of communication passages 330, is the sum of the passage cross-sectional areas of the plurality of communication passages 310. This is smaller than the total flow path cross-sectional area GB, which is the added value.

Here, the total flow passage cross-sectional area GA is the sum of the total flow passage cross-sectional areas of one or more second communication passages. The total flow path cross-sectional area GB is an added value obtained by adding one or more first communication paths. The plurality of communication paths 310 constitute a first communication path. The plurality of communication paths 320 and the plurality of communication paths 330 constitute a second communication path.

The cross-sectional area of the communication passage 330 is the area of a cross section of the communication passage 330 perpendicular to the axis D3. The cross-sectional area of the communication passage 320 is the area of a cross section of the communication passage 320 perpendicular to the axis D2.

The cross-sectional area of the communication path 310 is the area of a cross section of the communication path 310 that is orthogonal to the axis D1.

Therefore, according to the present embodiment, compared to the case where the total flow path cross-sectional area GA is larger than the total flow path cross-sectional area GB, the case outer space 500 is The speed of the airflow flowing toward the counterflow path 300 can be increased.

According to the present embodiment described above, the total flow passage cross-sectional area GA, which is the sum of the flow passage cross-sectional area of the plurality of communication passages 320 and the passage cross-section area of the plurality of communication passages 330, is This is smaller than the total flow cross-sectional area GB, which is the sum of the cross-sectional areas of the passages 310.

Therefore, compared to the case where the total flow path cross-sectional area GA is larger than the total flow path cross-sectional area GB, air flows from the case outer cavity 500 toward the reverse flow path 300 through the plurality of communication passages 320 and the plurality of communication passages 330. can increase the speed of air flow.

Thereby, the pressure loss caused by colliding the air flowing into the reverse flow path 300 through the plurality of communication paths 330 and 320 with respect to the air flowing from the inlet 300a to the outlet 300b of the reverse flow path 300 can be increased. .

As described above, air turbulence occurs when the air flowing from the reverse flow path 300 to the fan intake port 54a mixes with the main flow of air flowing from one side of the fan axis direction DRa to the air inlet 221a and the fan intake port 54a. can be further suppressed.

(Other embodiments)
(1) In the first to eighth embodiments described above, an example has been described in which the centrifugal fan is the turbo fan 18, but instead, the centrifugal fan may be a sirocco fan other than the turbo fan 18, for example.

(2) In the eighth embodiment, an example in which the plurality of communication passages 310 and the plurality of communication passages 330 are provided in the cover case portion 221 has been described. However, instead of this, an example has been described in which a plurality of communication passages 310, a plurality of communication passages 320, and a plurality of communication passages 330 are provided in the cover case portion 221.

In this case, the sum S3 of the flow passage cross-sectional areas of the plurality of communication passages 320 and the passage cross-sectional area of the plurality of communication passages 330 is smaller than the sum S1 of the passage cross-sectional areas of the plurality of communication passages 310.

(3) In the first to eighth embodiments described above, an example has been described in which the centrifugal blower 10 is applied to a vehicle air conditioner. However, instead of this, the centrifugal blower device 10 may be applied to various devices other than a vehicle air conditioner (for example, a vehicle seat air conditioner).

(4) In the first embodiment, an example has been described in which the communication passage inner wall 310a and the inlet side inner wall 300c are each formed along the fan axis direction DRa as a predetermined direction.

However, the present invention is not limited thereto, and the communication passage inner wall 310a and the inlet-side inner wall 300c may each be formed along a direction other than the fan axis direction DRa.

(5) In the first embodiment, an example has been described in which the communication passage inner wall 320a and the labyrinth wall 410 of the reverse flow passage 300 are each formed along the fan axis direction DRa.

However, instead of this, the communication passage inner wall 320a and the labyrinth wall 410 of the reverse flow passage 300 may each be formed along a direction other than the fan axis direction DRa.

(6) Note that the present invention is not limited to the embodiments described above, and can be modified as appropriate within the scope of the claims. Furthermore, the embodiments described above are not unrelated to each other, and can be combined as appropriate, except in cases where combination is clearly impossible. Furthermore, in each of the above embodiments, it goes without saying that the elements constituting the embodiments are not necessarily essential, except in cases where it is specifically stated that they are essential or where they are clearly considered essential in principle. stomach. In addition, in each of the above embodiments, when numerical values such as the number, numerical value, amount, range, etc. of the constituent elements of the embodiment are mentioned, when it is clearly stated that it is essential, or when it is clearly limited to a specific number in principle. It is not limited to that specific number, except in cases where In addition, in each of the above embodiments, when referring to the shape, positional relationship, etc. of constituent elements, etc., the shape, It is not limited to positional relationships, etc. Furthermore, in each of the above embodiments, if it is described that the external environment information of the vehicle (for example, the humidity outside the vehicle) is acquired from a sensor, that sensor is abolished and the external environment information is acquired from a server or cloud external to the vehicle. It is also possible to receive. Alternatively, it is also possible to eliminate the sensor, acquire relevant information related to the external environment information from a server or cloud external to the vehicle, and estimate the external environment information from the acquired relevant information.

10 Centrifugal blower 12 Scroll casing 18 Turbo fan 52 Blade 54 Ring member 54a Air suction port 221 Cover case part 300 Reverse flow path 310 Communication path 320 Communication path 330 Communication path 340 Communication path 350 Communication path 500 Case outer space 360 Change point

Claims (14)

A centrifugal blower device,
When the direction in which the axis line (CL) extends is defined as the axial direction (DRa), a rotating shaft (14) that is formed to extend in the axial direction and rotates around the axis;
a centrifugal fan (18) supported by the rotating shaft and rotating together with the rotating shaft;
A casing (12) having an air inlet (221a) that opens on one side in the axial direction and housing the centrifugal fan and the rotating shaft on the other side in the axial direction with respect to the air inlet. ,
The centrifugal fan is
a plurality of blades (52) arranged in a circumferential direction centered on the axis;
The air intake port (54a) is arranged on one side of the plurality of blades in the axial direction and is formed into an annular shape centered on the axis, and has an air intake port (54a) through which air passing through the air inflow port is taken in. and a ring member (54) connected to one side in the axial direction of each of the plurality of blades;
a main plate (56) disposed on the other side of the plurality of blades in the axial direction and connected to the other side of each of the plurality of blades in the axial direction;
The ring member forms a fan ventilation path (54f, 52a) together with the main plate and the plurality of blades,
The centrifugal fan, when rotated, blows air sucked in through the air inlet and the air suction port through the fan ventilation path outward in a radial direction about the axis;
The casing has a cover case part (221) formed to cover the ring member from one side in the axial direction,
The ring member and the cover case portion form a reverse flow path (300) that is a gap therebetween,
A case outer cavity (500) is formed on the outer side of the cover case part,
The ring member or the cover case portion is configured to connect the case outer cavity (500) and the A centrifugal blower forming one or more communication passages (310, 320, 330, 340, 350, 350b) for circulating air between one of the fan ventilation passages and the reverse flow passage. The one or more communication passages (310) are provided in the cover case portion, communicate between the backflow passage and the case outer cavity, and allow air to flow from the fan ventilation passage (52a) into the backflow passage. The centrifugal blower device according to claim 1, wherein the air is guided to the outer cavity of the case. The cover case part (221) has a communication passage inner wall (310a) that forms the one or more communication passages (310),
The casing has an inlet flow path wall (300c) that is disposed radially outward from the ring member with respect to the axis and forms an inlet (300a) of the reverse flow path together with the ring member,
The inlet channel wall is formed along a predetermined direction (DRa),
2. The inner wall of the communicating path is formed continuously from the inlet flow path wall in the predetermined direction, and guides air flowing from the inlet along the inlet flow path wall to the case outer cavity. The centrifugal blower device described in . When the one or more communication passages are one or more first communication passages, the cover case portion is provided on the outlet side of the reverse flow passage with respect to the first communication passage among the reverse flow passages, and The backflow path and the case outer cavity are communicated, and the air flowing from the case outer space into the backflow path is transferred from the inlet of the backflow path to the backflow path. The centrifugal blower device according to claim 2 or 3, wherein one or more second communication passages (320, 330) are formed to impinge on the air flowing toward the outlet. The casing is configured to close the case outer cavity,
According to claim 4, the sum of the cross-sectional areas of the one or more second communication passages is smaller than the sum of the cross-sectional areas of the one or more first communication passages. Centrifugal blower device as described. The one or more communication passages (320, 330) are provided in the cover case part, and communicate between the inside of the backflow passage and the case outer cavity, and from the case outer cavity to the backflow passage. The centrifugal blower device according to claim 1, wherein air is caused to flow in and the inflowing air is made to collide with air flowing from an inlet of the reverse flow path toward an outlet of the reverse flow path. The cover case part has a maze wall (410) formed along a predetermined direction (DRa) to configure the reverse flow path in a maze shape,
The cover case part has a communication passage inner wall (320a) that is formed continuously from the labyrinth wall and along the predetermined direction to form the one or more communication passages (320),
The centrifugal air blower according to claim 6, wherein the communication passage inner wall guides the air flowing into the reverse flow passage from the case outer cavity so as to collide with the air flowing along the labyrinth wall in the reverse flow passage. Device. The ring member includes an inlet forming part (54d) that forms the air inlet, and a guide part (54k) that is formed to protrude outward in a radial direction about the axis from the inlet forming part. and,
A communication hole (300e) is formed between the guide part and the cover case part, and the communication hole (300e) communicates between the case outer space and the reverse flow path;
The outer cavity of the case is open to the atmosphere,
The guide portion guides air flowing from the inlet (300a) of the reverse flow path toward the outlet (300b) of the reverse flow path to the outside in a radial direction centering on the axis. The centrifugal blower device according to claim 1, wherein the air flowing through the air is guided toward the atmosphere through the communication hole and the outer cavity of the case. The ring member includes a cylindrical portion (54d) forming the fan ventilation path (54f) and having a cylindrical shape centered on the axis,
The one or more communication passages (340) are provided in the cylindrical part and communicate between the fan ventilation passage and the backflow passage to direct air flowing from the fan ventilation passage into the backflow passage. The centrifugal blower device according to claim 1, wherein the air flowing from the inlet of the backflow path toward the outlet of the backflow path collides with the air. The ring member includes a cylindrical portion (54d) formed in a cylindrical shape centered on the axis to form an intake ventilation path (54f) as the fan ventilation path,
Between two adjacent blades of the plurality of blades, there is an inter-blade flow as the fan ventilation path that blows the air that has passed through the suction ventilation path (54f) outward in the radial direction around the axis. A road (52a) is provided,
In a cross section of the ring member that includes the axis, the ring member forms the inter-blade flow path together with the plurality of blades, is formed in an arc shape that is convex toward the other side in the axial direction, and is formed in an arc shape that is convex toward the other side of the axis. a curved portion (54e) having an inner wall (541) formed so as to extend outward in a radial direction around the axis as it approaches the other side;
The one or more communication passages (350) are provided in the curved portion, communicate between the reverse flow passage and the inter-blade flow passage, and blow air from the reverse flow passage to the inter-blade flow passage. The centrifugal blower device described in . When the centrifugal fan rotates to one side (DRf) in the rotation direction to blow out the sucked air from the inter-blade flow path, the center line (ST) of the inter-blade flow path in the rotation direction Negative pressure is generated in a region (520) on one side in the rotational direction, and positive pressure is generated in a region (521) on the other side in the rotational direction with respect to the centerline of the interblade flow path. occurs,
The centrifugal blower device according to claim 10, wherein the one or more communication paths communicate between the region on one side of the inter-blade flow path and the reverse flow path. In a cross section of the ring member that includes the axis, the inner wall angle is a narrow angle formed between the axis and a tangent of the curved portion that is in contact with the inner wall (541) forming the interblade flow path. ,
In a cross section of the ring member that includes the axis, the inner wall has a change point (600) at which the inner wall angle is 3.5 degrees, and one side of the inner wall from the change point in the axial direction The inner wall angle becomes smaller toward the inner wall, and the inner wall angle becomes larger toward the other side in the axial direction from the change point of the inner wall,
The centrifugal system according to claim 10 or 11, wherein the one or more communication passages (350a, 350b) open on one side of the inner wall in the axial direction with respect to the change point, or on the other side in the axial direction. Air blower. The centrifugal blower device according to any one of claims 1 to 12, wherein the one or more communication passages are arranged in a circumferential direction about the axis. The centrifugal blower device according to any one of claims 1 to 6 and 8 to 13, wherein the ring member and the cover case portion constitute a labyrinth structure that forms the reverse flow path in a labyrinth shape.

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