JP2018040340A - Centrifugal blower - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce variations in the air velocity and air volume of an air current reaching a discharge hole, in a centrifugal blower in which the discharge hole is not formed in at least one of predetermined directions of centrifugal directions of a fan.SOLUTION: In a centrifugal blower 100, a width W1 from one wall part along a rotation axis direction in a basic extended space to the other wall part is set greater than a width W2 from one wall part along a rotation axis direction in an inside space of a basic inflow space to the other wall part. The inside space is positioned on the side of the rotation axis with respect to an internal space S1 of a recess 2h in the basic inflow space.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a centrifugal blower.

  Conventionally, a centrifugal blower has been used. For example, a centrifugal blower is widely used as a blower for a vehicle because of relatively low noise even at high wind pressure.

  As a centrifugal blower for vehicles, the thing of patent documents 1 is proposed. The centrifugal blower includes a rotating circular fan and a fan case having a wall portion that encloses and houses the fan. The fan rotates to generate wind that flows in the centrifugal direction around the rotation axis. The wall portion has one wall portion located on one side of the fan, the other wall portion located on the other side of the fan, and a side wall portion connected to each of the one wall portion and the other wall portion. A ventilation space is formed by the internal space surrounded by the one wall portion, the other wall portion, and the side wall portion.

  The side wall portion is located in a region outside the fan in the centrifugal direction around the rotation axis, and is formed so that the wall surface of the side wall portion is arranged concentrically with respect to the circular shape of the fan. This centrifugal direction is a straight direction perpendicular to the rotation axis of the fan. Hereinafter, this direction is referred to as the centrifugal direction of the fan.

  Further, the wall portion has an inlet for introducing air outside the fan case into the ventilation space, and an outlet for discharging the air passing through the ventilation space to the outside of the fan case. The introduction port is formed in one wall portion, and the discharge port is formed in the other wall portion. The discharge port is disposed over the entire circumference in the rotation direction of the fan between the fan and the side wall surface in the centrifugal direction of the fan. In this centrifugal blower, the wind blown in the centrifugal direction of the fan is applied to the side wall surface of the fan case and turned in the direction of the rotation axis of the fan, and is discharged as wind flowing in the direction of the rotation axis of the fan. It is provided to the blown object (for example, an occupant) through the outlet.

  As described above, particularly in the centrifugal blower described in Patent Document 1, the wall surface of the side wall portion is arranged concentrically with respect to the circular shape of the fan, and the side wall portion is arranged over the entire circumference in the rotation direction of the fan. ing. Thereby, in this centrifugal blower, the wind speed of the wind blown in the centrifugal direction of the fan and passing through the ventilation space to the discharge port becomes uniform over the entire circumference in the fan rotation direction. For this reason, in this centrifugal blower, wind with a spatially uniform wind speed and volume is provided to the blown object.

JP-A-10-292925

  The centrifugal blower as described above is required to be downsized. In particular, since the fan must have a certain size in the centrifugal direction of the fan, it is desirable to prevent the size of the fan case from increasing in the centrifugal direction as much as possible. That is, the fan case is required to be downsized in the centrifugal direction of the fan.

  However, in order to increase the amount of wind supplied to the outside, the width of the discharge hole needs to be set to be somewhat wide. For this reason, in the centrifugal blower as described above, since a wide discharge hole is formed, it is necessary to set a wide space between the fan and the side wall portion. It becomes a problem.

  Then, this inventor examined the centrifugal blower of the structure which made small the physique in a predetermined direction among the centrifugal directions of a fan. Specifically, first, the width of the fan and the side wall portion is narrowed without forming a discharge hole on one side and the other side in the predetermined direction with respect to the fan, and in the centrifugal direction of the fan with respect to the fan. A centrifugal blower having a configuration in which a discharge hole is formed only in a part of a linear direction orthogonal to a predetermined direction was examined.

  According to the centrifugal blower having such a configuration, the distance between the fan and the side wall portion in the portion where there is no discharge hole when viewed from the rotation shaft of the fan is the fan in the portion where the discharge hole is viewed from the rotation shaft of the fan. The fan case can be reduced in size by shortening the distance between the side wall and the side wall.

  However, as a result of the study, it has become clear that it is difficult to provide a uniform wind speed and a uniform wind volume as in the centrifugal blower of Patent Document 1 when this configuration is adopted. That is, in the case of this configuration, the wind speed and the amount of the wind that is blown in the centrifugal direction of the fan and passes through the ventilation space to the discharge hole are not uniform in the rotation direction of the fan.

  In view of the above points, the present invention reduces variations in the wind speed and the amount of wind reaching the discharge hole in a centrifugal blower having a structure in which no discharge hole is formed in at least one of the predetermined directions of the centrifugal direction of the fan. The purpose is to do.

  In order to achieve the above object, according to the first aspect of the present invention, in the centrifugal fan (100), from one wall portion (2a) to the other wall portion (2b) along the rotation axis direction (PD) in the basic expansion space. Is wider than the width (W2) from one wall (2a) to the other wall (2b) along the rotation axis direction (PD) in the inner space in the basic inflow space. . This inner space is a space located closer to the rotation axis (P) than the inner space (S1) of the recess (2h) in the basic inflow space.

  For this reason, according to this centrifugal blower, even in a configuration in which no discharge port is provided on the side of the fan in the predetermined direction, which is the centrifugal direction, variations in wind speed and air volume can be suppressed. That is, according to this centrifugal blower, even if the physique in the predetermined direction is reduced, variations in wind speed and air volume can be suppressed.

  In addition, the code | symbol in the bracket | parenthesis of each part described in this column and the claim shows the correspondence with the specific means as described in embodiment mentioned later.

It is a figure showing the section composition of the centrifugal blower concerning a 1st embodiment of this indication. It is a figure which shows the II-II cross section in FIG. 1 of the centrifugal air blower shown in FIG. It is a figure which shows the III-III cross section in FIG. 1 of the centrifugal air blower shown in FIG. It is a figure which shows the IV-IV cross section in FIG. 1 of the centrifugal air blower shown in FIG. It is a figure which shows the VV cross section in FIG. 1 of the centrifugal air blower shown in FIG. It is a figure which shows typically the flow of the wind which flows through the ventilation space of the centrifugal air blower shown in FIG. It is a figure showing the section composition of the centrifugal air blower concerning a 2nd embodiment of this indication. It is a figure which shows the VIII-VIII cross section in FIG. 7 of the centrifugal air blower shown in FIG. It is a figure which shows the IX-IX cross section in FIG. 7 of the centrifugal air blower shown in FIG. It is a figure which shows the XX cross section in FIG. 7 of the centrifugal air blower shown in FIG. It is a figure which shows typically the flow of the wind which flows through the ventilation space of the centrifugal air blower shown in FIG. It is a figure corresponding to Drawing 4 in a 1st embodiment about a centrifugal blower concerning other embodiments of this indication. It is a figure corresponding to Drawing 4 in a 1st embodiment about a centrifugal blower concerning other embodiments of this indication. It is a figure corresponding to Drawing 4 in a 1st embodiment about a centrifugal blower concerning other embodiments of this indication. It is a figure corresponding to Drawing 4 in a 1st embodiment about a centrifugal blower concerning other embodiments of this indication. It is a figure corresponding to Drawing 4 in a 1st embodiment about a centrifugal blower concerning other embodiments of this indication.

  Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. In the following embodiments, parts that are the same or equivalent to each other will be described with the same reference numerals.

(First embodiment)
A centrifugal blower 100 according to a first embodiment of the present disclosure will be described with reference to FIGS. FIG. 1 shows a cross section taken along line II in FIG. In FIG. 1 and FIG. 6, the broken line with the reference numeral 20 indicates the outer edge of the extended portion 20. In FIG. 1 and FIG. 6, the broken line with the reference numeral 22 indicates the outer edge of the extended portion 22. In FIG. 6, an arrow indicated by a solid line without a sign indicates the direction of the flowing wind.

  Centrifugal blower 100 according to the present embodiment is a blower that blows introduced air into a vehicle interior. For example, a part of an air conditioner mounted inside a dashboard arranged on the front side of the vehicle interior (that is, Used as a blower). As shown in FIG. 2, the centrifugal blower 100 according to the present embodiment includes a fan 1, a fan case 2 that houses the fan 1, and an electric motor 3 that rotationally drives the fan 1. In the centrifugal blower 100, an energization amount corresponding to an air volume set by an operation panel (not shown) is supplied to the electric motor 3, and the fan 1 rotates at a rotation speed corresponding to the energization amount.

  In the following, the rotation axis of the fan 1 (namely, a virtual straight line extending in the direction of the rotation axis 3a of the electric motor 3 described later) is referred to as the rotation axis P, and the direction of the rotation axis P (namely, the rotation axis of the electric motor 3). The direction in which 3a extends is referred to as the rotation axis direction PD.

  As shown in FIGS. 1 and 2, the fan 1 is a centrifugal multiblade fan that rotates to generate a wind that flows in a centrifugal direction CD around the rotation axis P. The fan 1 is fixed to the rotating shaft 3a of the electric motor 3, and rotates with the rotation of the rotating shaft 3a. The material of the fan 1 is not particularly limited, but here it is made of resin. As shown in FIG. 1, the fan 1 has a plurality of blades 1 a arranged around the rotation shaft 3 a of the electric motor 3. Each blade 1a has one axial end (air suction side) connected to each other via a side plate 1b shown in FIG. 2, and the other axial end is connected to a rotating shaft 3a via a main plate (not shown). ing. As shown in FIG. 1, the fan 1 is configured so that the outer edge thereof is substantially circular, and is arranged at the approximate center of the fan case 2.

  As shown in FIGS. 1 and 2, the fan case 2 is a case in which the fan 1 is enclosed and accommodated, and a ventilation space S that is a space for passing the wind generated by the rotation of the fan 1 is formed inside. is there. As shown in FIG. 2, the fan case 2 has one wall portion 2 a located on one side in the rotational axis direction PD with the fan 1 as a reference, and the other wall located on the other side in the rotational axis direction PD with the fan 1 as a reference. Part 2b. Further, the fan case 2 has a side wall portion 2c located in a region outside the fan 1 in the centrifugal direction CD. The one wall portion 2 a, the other wall portion 2 b, and the side wall portion 2 c contain the fan 1 so as to surround the fan 1. In the centrifugal blower 100 according to the present embodiment, the space surrounded by the one wall portion 2a, the other wall portion 2b, and the side wall portion 2c forms a ventilation space S that is a space for passing air. .

  In the following, the direction of the arrow of the symbol CD1 in FIG. 1 is referred to as a first direction CD1, the direction of the arrow of the symbol CD2 in FIG. 1 is referred to as a second direction CD2, and the direction of the arrow of the symbol CD3 in FIG. The direction of the arrow indicated by the symbol CD4 in FIG. 1 is referred to as a fourth direction CD4.

  The first direction CD1 is a direction on one side of a predetermined direction in the centrifugal direction CD. Specifically, the first direction CD1 is a direction from the rotation axis P toward the wind flow upstream end of the basic expansion space while being orthogonal to the rotation axis P. The basic expansion space will be described later.

  The second direction CD2 is a direction on one side of the rotation axis direction PD and a direction orthogonal to the predetermined direction. Specifically, the second direction CD2 is a direction from the rotation axis P toward the internal space S11 of the discharge port 2e while being orthogonal to the rotation axis P. The first direction CD1 is a direction that is shifted by 90 ° to the reverse rotation side of the fan 1 around the rotation axis P with respect to the second direction CD2 while being orthogonal to the rotation axis P. The second direction CD2 corresponds to the basic predetermined direction.

  The third direction CD3 is the direction opposite to the first direction CD1. The fourth direction CD4 is the direction opposite to the second direction CD2. The third direction CD3 is a direction shifted by 90 ° to the reverse rotation side of the fan 1 around the rotation axis P with respect to the fourth direction CD4 while being orthogonal to the rotation axis P. The fourth direction CD4 corresponds to the additional predetermined direction.

  The first direction CD1, the second direction CD2, the third direction CD3, and the fourth direction CD4 are the first direction CD1, the second direction CD2, the third direction CD3, and the fourth direction CD4 in the rotational direction RD of the fan 1. They are in order.

  As shown in FIGS. 2 and 3, the one wall portion 2a includes a portion 2aa located on the first orientation CD1 side with respect to the rotation axis P, a portion 2ab located on the second orientation CD2 side, and a third It has a portion 2ac located on the direction CD3 side and a portion 2ad located on the fourth direction CD4 side. In the following, the portion 2aa is referred to as one first wall portion 2aa, the portion 2ab is referred to as one second wall portion 2ab, the portion 2ac is referred to as one third wall portion 2ac, and the portion 2ad is referred to as one fourth wall portion 2ad. Called.

  As shown in FIGS. 2 and 3, the other wall 2b includes a portion 2ba located on the first orientation CD1 side with respect to the rotation axis P, a portion 2bb located on the second orientation CD2 side, and a third It has a portion 2bc located on the direction CD3 side and a portion 2bd located on the fourth direction CD4 side. In the following, the portion 2ba is referred to as the other first wall portion 2ba, the portion 2bb is referred to as the other second wall portion 2bb, the portion 2bc is referred to as the other third wall portion 2bc, and the portion 2bd is referred to as the other fourth wall portion 2bd. Called.

  As shown in FIG. 2, the fan case 2 has two inlets 2 d for introducing external air into the ventilation space S and two for discharging the air passing through the ventilation space S to the outside of the fan case 2. Outlets 2e and 2f. One of the two discharge ports 2e and 2f (that is, the discharge port on the second direction CD2 side) 2e is formed as a part of the other second wall portion 2bb. Of the two discharge ports 2e and 2f, the other (that is, the discharge port on the second direction CD2 side) 2f is formed as a part of the other fourth wall portion 2bd.

  That is, the internal space S10 of the introduction port 2d corresponds to an introduction hole for introducing external air into the ventilation space S. The internal space S11 of the discharge port 2e corresponds to a basic discharge hole for discharging the wind that has passed through the ventilation space S to the outside. Further, the internal space S12 of the discharge port 2f corresponds to an additional discharge hole for discharging the wind that has passed through the ventilation space S to the outside.

  In the present embodiment, in a predetermined space in the ventilation space S, the wind after exiting the fan 1 and before flowing into the internal space S11 of the discharge port 2e passes. This predetermined space is a space in the ventilation space S that is shifted to the reverse rotation side of the fan 1 around the rotation axis P with respect to the internal space S11 of the discharge port 2e. The predetermined space corresponds to a basic inflow space. Hereinafter, the predetermined space that is shifted to the reverse rotation side of the fan 1 around the rotation axis P with respect to the internal space S11 of the discharge port 2e is referred to as a basic inflow space.

  Further, in the present embodiment, in a predetermined space in the ventilation space S, the wind that has passed through the fan 1 and before flowing into the internal space S12 of the discharge port 2f passes. This predetermined space is a space in the ventilation space S that is shifted to the reverse rotation side of the fan 1 around the rotation axis P with respect to the internal space S12 of the discharge port 2f. The predetermined space corresponds to an additional inflow space. Hereinafter, the predetermined space that is shifted to the reverse rotation side of the fan 1 around the rotation axis P with respect to the internal space S12 of the discharge port 2f is referred to as an additional inflow space.

  The inlet 2d is opened so that the one side in the rotation axis direction PD is the upstream side of the wind and the other side in the rotation axis direction PD is the downstream side of the wind. The two outlets 2e and 2f are opened such that the one side in the rotation axis direction PD is the upstream side of the wind and the other side in the rotation axis direction PD is the downstream side of the wind. That is, the internal space S10 of the introduction port 2d is formed by the one wall portion 2a. Further, the internal space S11 of the discharge port 2e is formed by the other wall portion 2b. The internal space S12 of the discharge port 2f is formed by the other wall 2b.

  For this reason, in this centrifugal blower 100, compared with the case where the discharge port is opened in the opposite direction (that is, the other side is the upstream side of the wind and the one side is the downstream side of the wind), The wind introduced from 2d can be provided from the discharge ports 2e and 2f with little pressure loss.

  The material of the fan case 2 is not particularly limited, but here it is made of resin.

  In the present embodiment, as shown in FIGS. 3 and 4, the width W1 in the rotation axis direction PD of the ventilation space S is formed on the outer portion of the first wall portion 2aa located outside the fan 1 in the centrifugal direction CD. An extension portion 20 is formed to extend the. In other words, the expansion unit 20 expands the width W1 of the ventilation space S surrounded by the outer portion more than the width W2 of the ventilation space S surrounded by the inner portion located on the rotation axis P side than the outer portion. Is formed. The widths W1 and W2 here are widths in the rotation axis direction PD. More specifically, the extended portion 20 has a recessed portion 2h that is formed on a flat surface 2ga that is in contact with the ventilation space S in the first wall portion 2aa and is recessed on the one side in the rotation axis direction PD. The width W1 of the ventilation space S is expanded to the one side by the internal space S1. The internal space S1 of the recess 2h is a part of the basic inflow space and the basic expansion space. The recess 2h has a quadrangular cross-sectional shape. Moreover, as shown in FIG. 1, the outermost edge OE in the centrifugal direction CD of the expansion part 20 is directly connected to the side wall part 2ca on the first direction CD1 side. More specifically, the outermost edge OE in the centrifugal direction CD of the expansion part 20 is directly connected to the side wall part 2ca on the first direction CD1 side in the whole from the front side to the front side in the rotation direction RD. . That is, in the present embodiment, the whole of the basic expansion space from the upstream side to the downstream side is in contact with the side wall portion 2ca on the first direction CD1 side. In addition, the extended portion 20 is formed so that the width W1 is substantially constant from the near side to the far side in the rotational direction RD.

  In the present embodiment, as shown in FIGS. 3 and 4, the outer portion of the other first wall portion 2ba located outside the fan 1 in the centrifugal direction CD has a ventilation space S in the rotation axis direction PD. An extension portion 21 that extends the width W1 is formed. In other words, the expansion portion 21 expands the width W1 of the ventilation space S surrounded by the outer portion more than the width W2 of the ventilation space S surrounded by the inner portion located on the rotation axis P side than the outer portion. Is formed. The widths W1 and W2 here are widths in the rotation axis direction PD. More specifically, the extended portion 21 has a recessed portion 2i that is formed on the flat surface 2gb that is in contact with the ventilation space S of the other first wall portion 2ba and that is recessed on the other side in the rotational axis direction PD. The width W1 of the ventilation space S is expanded to the other side by the internal space S2. The internal space S2 of the recess 2i is a part of the basic inflow space and the basic expansion space. The recess 2i has a quadrangular cross-sectional shape. Moreover, as shown in FIG. 1, the outermost edge OE in the centrifugal direction CD of the expansion part 21 is directly connected to the side wall part 2ca on the first direction CD1 side. More specifically, the outermost edge OE in the centrifugal direction CD of the expansion part 21 is directly connected to the side wall part 2ca on the first direction CD1 side as a whole from the front side to the front side in the rotational direction RD. . That is, in the present embodiment, the whole of the basic expansion space from the upstream side to the downstream side is in contact with the side wall portion 2ca on the first direction CD1 side. In the present embodiment, as shown in FIGS. 3 and 4, the extended portion 20 and the extended portion 21 are disposed in substantially the same region in the centrifugal direction CD. Further, the extended portion 21 is formed so that the width W1 is substantially constant from the front side to the front side in the rotation direction RD.

  In other words, in the present embodiment, since the extended portions 20 and 21 are formed, the width W1 of the ventilation space S surrounded by the outer portion is set to the inner portion positioned on the rotation axis P side with respect to the outer portion. It expands more than the width W2 of the ventilation space S surrounded by.

  The entire space expanded including the internal space S1 of the recess 2h and the internal space S2 of the recess 2i is the basic expansion space. A space sandwiched between the internal space S1 and the internal space S2 is also a part of the basic expansion space.

  That is, in this embodiment, the width W1 from the one wall 2a to the other wall 2b along the rotation axis direction PD in the basic expansion space is equal to the one wall along the rotation axis direction PD in the inner space in the basic inflow space. It is wider than the width W2 from the portion 2a to the other wall portion 2b. This inner space is a space located closer to the rotation axis P than the inner space S1 of the recess 2h in the basic inflow space. The width W1 corresponds to the first width, and the width W2 corresponds to the second width.

  In the centrifugal blower 100 according to the present embodiment, first, the wind flowing from the fan 1 toward the side wall portion 2ca on the first direction CD1 side in the centrifugal direction CD of the fan 1 is on the side of the first direction CD1. Flows along the side wall portion 2ca of the second direction CD2 toward the side wall portion 2cb. Hereinafter, this wind flow is referred to as main flow 1.

  Further, the wind that flows from the fan 1 toward the side wall 2cb on the second direction CD2 side in the centrifugal direction CD of the fan 1 flows along the side wall 2cb on the second direction CD2 side toward the third direction CD3. To the side wall 2cc side. Hereinafter, this wind flow is referred to as main flow 2.

  The main flow 1 and the main flow 2 flow into the discharge port 2e on the second direction CD2 side, and the main flow 1 and the main flow 2 are blown out of the fan case 2 from the discharge port 2e.

  The same applies to the outlet 2f on the fourth direction CD4 side. That is, the wind that flows from the fan 1 toward the side wall portion 2cc on the third direction CD3 side in the centrifugal direction CD of the fan 1 flows along the side wall portion 2cc on the third direction CD3 side toward the fourth direction CD4 side. To the side wall 2cd side. Hereinafter, this wind flow is referred to as main flow 3.

  Further, the wind that flows from the fan 1 toward the side wall 2cd on the fourth direction CD4 side in the centrifugal direction CD of the fan 1 flows along the side wall 2cd on the fourth direction CD4 side in the first direction CD1. It flows to the side wall portion 2ca side. Hereinafter, this wind flow is referred to as main flow 4.

  The main flow 3 and the main flow 4 flow into the discharge port 2f on the fourth direction CD4 side, and the main flow 3 and the main flow 4 are blown out of the fan case 2 from the discharge port 2f.

  Here, an operation and an effect due to the formation of the extended portions 20 and 21 will be described using FIG. 6 as compared with the case where the extended portions 20 and 21 are not formed. When the extended portions 20 and 21 are not formed, the width between the one wall portion 2a and the other wall portion 2b is uniform. FIG. 6 is a diagram showing the centrifugal blower 100 from the same viewpoint as that in FIG. 1, and the arrows represented by solid lines in the drawing schematically show the flow of wind.

  First, the case where the extended parts 20 and 21 are not formed will be described. Specifically, in the centrifugal blower 100 in this case, each of the surface facing the ventilation space S of the one wall portion 2a of the fan case 2 and the surface facing the ventilation space S of the other wall portion 2b is a flat surface. Has been. Further, the centrifugal blower 100 has a plane that is a part of the other wall portion 2b without the discharge ports 2e and 2f provided on the first direction CD1 side and the third direction CD3 side with respect to the fan 1. Has been placed. Further, in the centrifugal blower 100, the distance between the plane of the one wall portion 2a and the plane of the other wall portion 2b (that is, the width of the ventilation space S) is uniform overall.

  However, as a result of examination by the inventors of the present application, it has been found that it is difficult to provide a uniform wind speed or a uniform amount of wind as in the centrifugal blower of Patent Document 1 in this configuration. . That is, in the case of this configuration, the wind speed of the air blown in the centrifugal direction CD of the fan 1 and passing through the ventilation space S to the discharge ports 2 e and 2 f becomes nonuniform in the rotation direction of the fan 1.

  Specifically, the following knowledge was obtained. That is, the mainstream 1 flows in a narrow space between the fan 1 and the side wall portion 2ca on the first direction CD1 side, so that the wind speed is relatively fast, and the first direction among the discharge ports 2e on the second direction CD2 side is the first direction. It flows into the side close to the side wall 2ca on the CD1 side. On the other hand, the mainstream 2 flows in a wide space between the fan 1 and the side wall portion 2cb on the second direction CD2 side, so that the wind speed is relatively slow, and the mainstream 2 is out of the outlet 2e on the second direction CD2 side. It flows into the side close to the side wall 2cc on the side of the third direction CD3. That is, the main flow 1 and the main flow 2 having a large wind speed difference flow into different spaces into the discharge port 2e on the second direction CD2 side. For this reason, the wind speed of the wind flowing into the discharge port 2e on the second direction CD2 side becomes non-uniform, and the wind with the non-uniform wind speed is sent from the discharge port 2e to the air blow target. For the same reason, the wind speed of the wind flowing into the discharge port 2f on the fourth direction CD4 side also becomes non-uniform, and the wind with the non-uniform wind speed is sent from the discharge port 2f to the blow target.

  For both the first and third orientations CD1 and CD3, the distance between the fan 1 and the side wall portions 2ca and 2cc is set to be the same as the fan 1 and the side wall portions 2cb and 2cd on the second and fourth orientation CD2 and CD4 sides. The wind speed of the wind flowing into the discharge ports 2e and 2f also became non-uniform even when the distance was shorter than the distance between the two.

  As described above, in the centrifugal blower 100 when the expansion portions 20 and 21 are not formed, the main flow 1 and the main flow 2 having a large wind speed difference in different spaces are provided in the discharge port 2e on the second direction CD2 side. Flows in. The main flow 1 flows from the fan 1 toward the side wall portion 2ca on the first direction CD1 side in the centrifugal direction CD of the fan 1, and along the side wall portion 2ca on the first direction CD1 side, on the second direction CD2 side. It is the wind flow which flows to the side wall part 2cb side. The main flow 2 flows from the fan 1 toward the side wall portion 2cb on the second direction CD2 side in the centrifugal direction CD of the fan 1, and along the side wall portion 2cb on the second direction CD2 side on the third direction CD3 side. It is the wind flow which flows to the side wall part 2cc side.

  On the other hand, as shown in FIG. 6, in the centrifugal blower 100 according to the present embodiment, the expansion portions 20 and 21 are formed, so that the mainstream 1 is widened by the expansion portions 20 and 21. It flows through the ventilation space S and flows into the discharge port 2e on the second direction CD2 side. That is, in the centrifugal blower 100 according to the present embodiment, the main flow 1 passes through the wide ventilation space S, so that the flow velocity becomes slower than the case where the width of the ventilation space S is uniform as a whole, and the flow velocity is low. To flow into the discharge port 2e on the CD2 side in the second direction. Therefore, the difference in wind speed between the main flow 1 and the main flow 2 is smaller than when the width of the ventilation space S is uniform as a whole. For this reason, in the centrifugal blower 100 according to the present embodiment, the expansion portions 20 and 21 are formed, thereby suppressing variation in the wind speed and the amount of wind flowing into the discharge port 2e on the second direction CD2 side. it can. As described above, in the centrifugal blower 100 according to the present embodiment, even in the configuration in which the discharge port is not provided on the side in the predetermined direction that is the centrifugal direction CD of the fan (that is, the first direction CD1 side), The variation of can be suppressed. That is, in the centrifugal blower 100 according to the present embodiment, variations in wind speed and air volume can be suppressed even if the physique in the predetermined direction is reduced.

  Similarly, in the present embodiment, as shown in FIGS. 3 and 5, one of the third wall portions 2ac has an outer portion located outside the fan 1 in the centrifugal direction CD, and the rotation shaft 3a of the ventilation space S is located on the outer portion. An extension portion 22 that extends the width W3 in the direction is formed. That is, the expansion part 22 expands the width W3 of the ventilation space S surrounded by the outer portion to be larger than the width W4 of the ventilation space S surrounded by the inner portion located on the rotation axis P side than the outer portion. Is formed. The widths W3 and W4 here are widths in the rotation axis direction PD. More specifically, the extended portion 20 has a recessed portion 2k that is formed on the flat surface 2ja that is in contact with the ventilation space S of the first wall portion 2aa and that is recessed on the one side in the rotational axis direction PD. The width W3 of the ventilation space S is expanded to the one side by the internal space S3. The internal space S3 of the recess 2k is a part of the additional inflow space and the additional expansion space. The recess 2k has a quadrangular cross-sectional shape. Moreover, as shown in FIG. 1, the outermost edge OE in the centrifugal direction CD of the extended portion 22 is directly connected to the side wall portion 2cc on the third direction CD3 side. More specifically, the outermost edge OE in the centrifugal direction CD of the expansion part 22 is directly connected to the side wall part 2cc on the third direction CD3 side in the whole from the front side to the front side in the rotation direction RD. . Further, the extended portion 22 is formed such that the width W3 is substantially constant from the near side to the far side in the rotational direction RD.

  In the present embodiment, as shown in FIGS. 3 and 5, the outer portion of the other third wall portion 2bc located outside the fan 1 in the centrifugal direction CD is in the rotational axis direction PD of the ventilation space S. An extended portion 23 that extends the width W3 is formed. In other words, the expansion portion 23 expands the width W3 of the ventilation space S surrounded by the outer portion more than the width W4 of the ventilation space S surrounded by the inner portion located on the rotation axis P side than the outer portion. Is formed. The widths W3 and W4 here are widths in the rotation axis direction PD. More specifically, the extended portion 23 has a recessed portion 21 that is formed on the flat surface 2jb that is in contact with the ventilation space S in the first wall portion 2aa and that is recessed on the other side in the rotational axis direction PD. The width W3 of the ventilation space S is expanded to the other side by the internal space S4. The internal space S4 of the recess 21 is a part of the additional inflow space and the additional expansion space. The recess 21 has a quadrangular cross-sectional shape. Moreover, as shown in FIG. 1, the outermost edge OE in the centrifugal direction CD of the expansion part 23 is directly connected to the side wall part 2cc on the third direction CD3 side. More specifically, the outermost edge OE in the centrifugal direction CD of the extended portion 23 is directly connected to the side wall portion 2cc on the third direction CD3 side as a whole from the front side to the front side in the rotational direction RD. . In the present embodiment, as shown in FIGS. 3 and 5, the extension part 22 and the extension part 23 are arranged in substantially the same region in the centrifugal direction CD. The extension 23 is formed so that the width W3 is substantially constant from the front side to the front side in the rotation direction RD.

  In other words, in the present embodiment, since the extended portions 22 and 23 are formed, the width W3 of the ventilation space S surrounded by the outer portion is set to the inner portion positioned closer to the rotation axis P than the outer portion. It expands more than the width W4 of the ventilation space S surrounded by.

  The entire space expanded including the internal space S3 of the recess 2k and the internal space S4 of the recess 2l is an additional expansion space. A space sandwiched between the internal space S3 and the internal space S4 is also a part of the basic expansion space.

  That is, in this embodiment, the width W3 from the one wall 2a to the other wall 2b along the rotational axis direction PD in the additional expansion space is equal to the one wall along the rotational axis PD in the inner space in the additional inflow space. It is wider than the width W4 from the part 2a to the other wall part 2b. This inner space is a space located closer to the rotation axis P than the inner space S3 of the recess 2k in the additional inflow space. The width W3 corresponds to the third width, and the width W4 corresponds to the fourth width.

  For this reason, in the centrifugal blower 100 according to the present embodiment, since the expansion portions 22 and 23 are formed, as in the case of the expansion portions 20 and 21 described above, the exhaust on the side of the fourth direction CD4 is performed. Variations in the wind speed and the amount of wind flowing into the outlet 2f can be suppressed.

  As shown in FIG. 1, the extended portion 20 is continuously formed so as to extend from the point PT1 to the point PT2. That is, the basic expansion space is continuously formed so as to extend from the point PT1 to the point PT2. The extended portion 21 is continuously formed so as to extend from the point PT1 to the point PT3. That is, the basic expansion space is continuously formed so as to extend from the point PT1 to the point PT3. The point PT1 is a point on a predetermined straight line (that is, a straight line indicated by the arrow CD1) extending in the first direction CD1. Points PT2 and PT3 are points on a straight line SL1 that is parallel to the predetermined straight line and passes through the extreme end point PT4 of the fan 1 in the second direction CD2. In this way, each of the expansion portions 20 and 21 is continuous so as to extend at least from the point PT1 to a point on the straight line SL1 passing through the extreme end point PT4 of the fan 1 in the second direction CD2 parallel to the predetermined straight line. Is formed.

  For this reason, in the centrifugal blower 100, the wind speed (that is, the main flow 1) flowing in the vicinity of the side wall portion 2ca on the first direction CD1 side is passed through the internal spaces S1 and S2 of the expansion portions 20 and 21, thereby increasing the wind speed. As a relatively slow wind, the second direction CD2 side can surely flow to the discharge port 2e.

  Similarly, as shown in FIG. 1, the extended portion 22 is continuously formed so as to extend from the point PT5 to the point PT6. That is, the additional expansion space is continuously formed so as to extend from the point PT5 to the point PT6. The extension 23 is continuously formed so as to extend from the point PT5 to the point PT7. That is, the additional expansion space is continuously formed so as to extend from the point PT5 to the point PT7. The point PT5 is a point on a predetermined straight line (that is, a straight line indicated by the arrow CD3) extending in the third direction CD3. Points PT6 and PT7 are points on a straight line SL2 that is parallel to the predetermined straight line and passes through the fan end point PT8 in the fourth direction CD4. In this manner, each of the expansion portions 22 and 23 is continuously extended so as to extend at least from the point PT5 to a point on the straight line SL2 that is parallel to the predetermined straight line and passes through the fan end point PT8 in the fourth direction CD4. Is formed.

  For this reason, in this centrifugal blower 100, the wind speed (ie, main flow 1) flowing in the vicinity of the side wall portion 2cc on the side of the third direction CD3 is passed through the internal spaces S3 and S4 of the expansion portions 22 and 23, so As a relatively slow wind, it is possible to surely flow to the discharge port 2f on the fourth direction CD4 side.

  In this embodiment, as shown in FIG. 3 and FIG. 4, the expansion portions 20 and 21 have a width W1 of the ventilation space S surrounded by the outer portion and 1.5 of a width W2 of the ventilation space S surrounded by the inner portion. It is formed so as to expand to more than twice and less than twice (for example, twice). That is, the extended portions 20 and 21 are formed so as to expand the width W1 of the ventilation space S surrounded by the outer portion to 1.5 times or more the width W2 of the ventilation space S surrounded by the inner portion.

  For this reason, in the centrifugal blower 100 according to the present embodiment, the wind can be sufficiently slowed by sufficiently widening the internal spaces S1 and S2 of the expansion portions 20 and 21, and the wind speed is uniform as described above. Can be sufficiently achieved.

  Similarly, as shown in FIGS. 3 and 5, the expansion portions 22 and 23 have a width W3 of the ventilation space S surrounded by the outer portion 1.5 times or more than a width W4 of the ventilation space S surrounded by the inner portion. And it is formed so as to expand to 2 times or less (for example, 2 times). That is, the extended portions 22 and 23 are formed so as to expand the width W3 of the ventilation space S surrounded by the outer portion to 1.5 times or more the width W4 of the ventilation space S surrounded by the inner portion.

  For this reason, in the centrifugal blower 100 according to the present embodiment, the wind can be sufficiently slowed by sufficiently widening the internal spaces S3 and S4 of the expansion portions 22 and 23, and the wind speed is uniform as described above. Can be sufficiently achieved.

  As shown in FIG. 1, in the centrifugal blower 100 according to the present embodiment, in the centrifugal direction CD of the fan 1, the distance DT1 between the fan 1 and the side wall portion 2ca on the first direction CD1 side is It is shorter than the distance DT2 with the side wall 2cb on the direction CD2. That is, in the present embodiment, the distance from the rotation axis P in the second direction CD2 to the side wall portion 2cb on the second direction CD2 side is from the rotation axis P in the first direction CD1 to the rotation axis P in the first direction CD1. It is shorter than the distance to the side wall 2ca on the side of the one-direction CD1.

  Thus, in the centrifugal blower 100 according to the present embodiment, the fan case 2 can be reduced in size by reducing the size of the fan case 2 in a predetermined direction (that is, the size of the first direction CD1), as described above. In addition, it is possible to make the wind speed uniform.

  Similarly, in the centrifugal blower 100 according to the present embodiment, in the centrifugal direction CD of the fan 1, the distance DT3 between the fan 1 and the side wall portion 2cc on the third direction CD3 side is the side of the fan 1 and the fourth direction CD4. It is shorter than the distance DT4 with the side wall portion 2cd. That is, in the present embodiment, the distance from the rotation axis P in the fourth direction CD4 to the side wall portion 2cd on the fourth direction CD4 side is from the rotation axis P in the third direction CD3 to the rotation axis P in the third direction CD3. The distance is shorter than the distance to the side wall 2cc on the side of the three-direction CD3.

As described above, in the centrifugal blower 100 according to the present embodiment, the fan case 2 can be reduced in size by reducing the size of the fan case 2 in a predetermined direction (that is, the size of the third orientation CD3), and as described above. In addition, as shown in FIG. 1, the centrifugal blower 100 includes a nose that is an arc-shaped portion in which the winding start side and the winding end side of the fan case 2 overlap each other. Portions 2m and 2n are formed. The nose portion 2m is formed on the side wall portion 2ca on the first direction CD1 side. The nose portion 2m is a winding start side (i.e., wind direction) in a portion of the fan case 2 that forms the ventilation space S through which the wind (i.e., mainstreams 1 and 2) flows on the first and second directions CD1 and CD2 side. The uppermost stream side of the flow) and the winding end side in the portion of the fan case 2 that forms the ventilation space S through which the winds flowing in the third and fourth directions CD3 and CD4 (that is, the mainstreams 3 and 4) pass. (That is, the most downstream side of the wind flow). The nose portion 2n is formed on the side wall portion 2cc on the third direction CD3 side. The nose portion 2n is a winding start side (i.e., wind direction) in a portion of the fan case 2 that forms the ventilation space S through which the wind (i.e., the mainstreams 3 and 4) flows through the third and fourth directions CD3 and CD4. The uppermost stream side of the flow) and the winding end side in the portion of the fan case 2 that forms the ventilation space S through which the winds flowing in the first and second directions CD1 and CD2 (that is, mainstreams 1 and 2) pass. (That is, the most downstream side of the wind flow).

  The electric motor 3 is a motor that rotates the fan 1 by rotating the rotating shaft 3a at a rotation speed corresponding to the energization amount when an energization amount corresponding to the air volume set by an operation panel (not shown) is supplied. is there.

  As described above, in the centrifugal blower 100 according to the present embodiment, the width W1 of the ventilation space S surrounded by the outer portion is defined in the outer portion of the other first wall portion 2ba, and the ventilation space is surrounded by the inner portion. Expansion portions 20 and 21 that extend beyond the width W2 of S are formed. That is, in this embodiment, the width W1 from the one wall 2a to the other wall 2b along the rotation axis direction PD in the basic expansion space is equal to the one wall along the rotation axis direction PD in the inner space in the basic inflow space. It is wider than the width W2 from the portion 2a to the other wall portion 2b. This inner space is a space located closer to the rotation axis P than the inner space S1 of the recess 2h in the basic inflow space.

  For this reason, in the centrifugal blower 100 according to the present embodiment, the expansion portions 20 and 21 are formed, so that the mainstream 1 passes through the ventilation space S widened by the expansion portions 20 and 21 and is second. It flows into the discharge port 2e on the direction CD2 side. That is, the main flow 1 passes through the wide ventilation space S, so that the flow velocity becomes slower than the case where the width of the ventilation space S is entirely uniform, and the discharge port 2e on the second direction CD2 side in the state where the flow velocity is slow. Flow into. Therefore, the difference in wind speed between the main flow 1 and the main flow 2 is smaller than when the width of the ventilation space S is uniform as a whole. For this reason, in the centrifugal blower 100 according to the present embodiment, the expansion portions 20 and 21 are formed, so that the wind speed of the air flowing into the discharge port 2e on the second direction CD2 side can be made uniform. As described above, in the centrifugal blower 100 according to the present embodiment, even in a configuration in which the discharge port is not provided on the side in the predetermined direction that is the centrifugal direction CD of the fan (that is, the first direction CD1 side), the wind speed is uniform. It can be. That is, in the centrifugal blower 100 according to the present embodiment, the wind speed can be made uniform even if the physique in the predetermined direction is reduced.

  Similarly, in the centrifugal blower 100 according to this embodiment, the width W3 of the ventilation space S surrounded by the outer portion is set in the outer portion of the other third wall portion 2bc, and the width W3 of the ventilation space S surrounded by the inner portion is set. Expansion portions 22 and 23 that extend beyond the width W4 are formed. That is, in this embodiment, the width W3 from the one wall 2a to the other wall 2b along the rotational axis direction PD in the additional expansion space is equal to the one wall along the rotational axis PD in the inner space in the additional inflow space. It is wider than the width W4 from the part 2a to the other wall part 2b. This inner space is a space located closer to the rotation axis P than the inner space S3 of the recess 2k in the additional inflow space. Thereby, in the centrifugal blower 100 which concerns on this embodiment, the wind speed can be made uniform similarly to the effect by the expansion parts 20 and 21 being formed.

  Further, in the centrifugal blower 100 according to the present embodiment, the expansion portions 20 and 21 are at least the point PT2 on the straight line SL1 passing through the fan end point PT4 in the second direction CD2 parallel to the predetermined straight line from the point PT1. , And continuously formed so as to extend to PT3. That is, in the centrifugal blower 100 according to the present embodiment, the basic expansion space is continuously formed so as to extend from the point PT1 to the points PT2 and PT3.

  For this reason, in the centrifugal blower 100, the wind speed (ie, the main flow 1) flowing in the vicinity of the side wall portion 2ca on the first direction CD1 side is passed through the internal space S1 of the expansion portions 20 and 21, thereby comparing the wind speed. As a slow wind, the air can surely flow to the discharge port 2e on the CD2 side in the second direction.

  Similarly, in the centrifugal blower 100 according to the present embodiment, the expansion portions 22 and 23 are points on the straight line SL2 at least from the point PT5 and parallel to the predetermined straight line and passing through the fan end point PT8 in the fourth direction CD4. It is formed continuously so as to extend. That is, in the centrifugal blower 100 according to the present embodiment, the additional expansion space is continuously formed so as to extend from the point PT5 to the points PT6 and PT7. Thereby, like the effect in the case of the expansion parts 20 and 21, it can flow to the discharge port 2f by the side of 4th direction CD4 reliably as a wind with a comparatively slow wind speed.

  Further, the centrifugal blower 100 according to the present embodiment is configured so that the introduction port 2d has the one side in the rotational axis direction PD as the upstream side of the wind and the other side in the rotational axis direction PD as the downstream side of the wind. It is open. The two outlets 2e and 2f are opened such that the one side in the rotation axis direction PD is the upstream side of the wind and the other side in the rotation axis direction PD is the downstream side of the wind. That is, in the centrifugal blower 100 according to the present embodiment, the internal space S10 of the introduction port 2d is formed in the one wall portion 2a. The internal space S11 of the discharge port 2e is formed in the other wall 2b. The internal space S12 of the discharge port 2f is formed in the other wall 2b.

  For this reason, in this centrifugal blower 100, compared with the case where the discharge port is opened in the opposite direction (that is, the other side is the upstream side of the wind and the one side is the downstream side of the wind), The wind introduced from 2d can be provided from the discharge ports 2e and 2f with little pressure loss.

  Further, in the centrifugal blower 100 according to the present embodiment, the widths W1 of the ventilation space S in which the expansion portions 20 and 21 are surrounded by the outer portion are 1.5 times or more the width W2 of the ventilation space S surrounded by the inner portion. It is formed to expand.

  For this reason, in the centrifugal blower 100 according to the present embodiment, the wind can be sufficiently slowed by sufficiently widening the internal spaces S1 and S2 of the expansion portions 20 and 21, and the wind speed is uniform as described above. Can be sufficiently achieved.

  Similarly, in the centrifugal blower 100 according to the present embodiment, the expansion portions 22 and 23 have the width W3 of the ventilation space S surrounded by the outer portion, 1.5 times the width W4 of the ventilation space S surrounded by the inner portion. It is formed to expand as described above. Thereby, like the effect in the case of the expansion parts 20 and 21, the internal space S3 and S4 of the expansion parts 22 and 23 can be sufficiently widened to sufficiently slow the wind.

  Further, in the centrifugal blower 100 according to the present embodiment, in the centrifugal direction CD of the fan 1, the distance DT1 between the fan 1 and the side wall portion 2ca on the first direction CD1 side is equal to that on the fan 1 and the second direction CD2 side. The distance from the side wall 2cb is shorter. That is, in the present embodiment, the distance from the rotation axis P in the second direction CD2 to the side wall portion 2cb on the second direction CD2 side is from the rotation axis P in the first direction CD1 to the rotation axis P in the first direction CD1. It is shorter than the distance to the side wall 2ca on the side of the one-direction CD1.

  Thus, in the centrifugal blower 100 according to the present embodiment, the fan case 2 can be reduced in size by reducing the size of the fan case 2 in the predetermined direction (that is, the size of the first direction CD1). In this way, the wind speed can be made uniform.

  Similarly, in the centrifugal blower 100 according to the present embodiment, in the centrifugal direction CD of the fan 1, the distance DT3 between the fan 1 and the side wall portion 2cc on the third direction CD3 side is the side of the fan 1 and the fourth direction CD4. It is shorter than the distance DT4 with the side wall portion 2cd. That is, in the present embodiment, the distance from the rotation axis P in the fourth direction CD4 to the side wall portion 2cd on the fourth direction CD4 side is from the rotation axis P in the third direction CD3 to the rotation axis P in the third direction CD3. The distance is shorter than the distance to the side wall 2cc on the side of the three-direction CD3. As a result, the fan case 2 can be reduced in size by reducing the physique in the predetermined direction of the fan case 2 (that is, the physique of the third direction CD3), as well as the effects of the expansion portions 20 and 21. Thus, it is possible to make the wind speed uniform.

(Second Embodiment)
A second embodiment of the present disclosure will be described with reference to FIGS. This embodiment changes the arrangement | positioning of the expansion parts 20-23 in 1st Embodiment. Since the other parts are basically the same as those in the first embodiment, only the parts different from those in the first embodiment will be described except for the case where it is clearly indicated that they are the same as those in the first embodiment. FIG. 7 is a diagram corresponding to FIG. 1 in the first embodiment. 7 and 11, the broken line with the reference numeral 20 indicates the outer edge of the extended portion 20. 7 and 11, the broken line with the reference numeral 21 indicates the outer edge of the extended portion 21. 7 and 11, the broken line with the reference numeral 22 indicates the outer edge of the extended portion 22. 7 and 11, the broken line with the reference numeral 23 indicates the outer edge of the extended portion 23. In addition, in FIG. 11, an arrow indicated by a solid line without a sign indicates the direction of the flowing wind.

  In the first embodiment, the outermost edge OE in the centrifugal direction CD of the expansion portion 20 is directly connected to the side wall portion 2ca on the first direction CD1 side in the whole from the front side to the front side in the rotation direction RD. . On the other hand, in the present embodiment, the outermost edge OE in the centrifugal direction CD of the portion on the distal side in the rotational direction RD of the extended portion 20 is in the third direction CD3 rather than the side wall portion 2ca on the first direction CD1 side. Located apart to the side. The outermost edge OE in the centrifugal direction CD of the front portion in the rotational direction RD of the expanded portion 20 is directly connected to the side wall portion 2ca on the first direction CD1 side.

  In the first embodiment, the outermost edge OE in the centrifugal direction CD of the expansion portion 21 is directly connected to the side wall portion 2ca on the first direction CD1 side in the whole from the front side to the front side in the rotation direction RD. ing. On the other hand, in the present embodiment, the outermost edge OE in the centrifugal direction CD of the portion on the distal side in the rotational direction RD of the extended portion 21 is in the third direction CD3 rather than the side wall portion 2ca on the first direction CD1 side. Located apart to the side. In addition, the outermost edge OE in the centrifugal direction CD of the portion on the near side in the rotational direction RD in the extended portion 21 is directly connected to the side wall portion 2ca on the side in the first direction CD1.

  That is, in this embodiment, the predetermined upstream portion in the basic expansion space is in contact with the side wall portion 2ca on the first direction CD1, and the downstream portion in the basic expansion space is from the side wall portion 2ca on the first direction CD1 side, It is separated to the rotating shaft 3a side. This downstream portion is a portion on the downstream side of the wind flow from the upstream portion in the basic expansion space.

  In the first embodiment, the outermost edge OE in the centrifugal direction CD of the expansion portion 22 is directly connected to the side wall portion 2cc on the third direction CD3 side in the whole from the front side to the front side in the rotation direction RD. . On the other hand, in the present embodiment, the outermost edge OE in the centrifugal direction CD of the portion on the distal side in the rotational direction RD of the extended portion 22 is in the first direction CD1 rather than the side wall portion 2cc on the third direction CD3 side. Located apart to the side. Note that the outermost edge OE in the centrifugal direction CD of the portion on the near side in the rotational direction RD of the extended portion 22 is directly connected to the side wall portion 2cc on the third direction CD3 side.

  In the first embodiment, the outermost edge OE in the centrifugal direction CD of the extended portion 23 is directly connected to the side wall portion 2cc on the third direction CD3 side in the whole from the front side to the front side in the rotation direction RD. . On the other hand, in the present embodiment, the outermost edge OE in the centrifugal direction CD of the portion on the distal side in the rotational direction RD of the extended portion 23 is in the first direction CD1 rather than the side wall portion 2cc on the third direction CD3 side. Located apart to the side. Note that the outermost edge OE in the centrifugal direction CD of the portion on the near side in the rotational direction RD of the extended portion 23 is directly connected to the side wall portion 2cc on the third direction CD3 side.

  That is, in this embodiment, the predetermined upstream portion in the additional expansion space is in contact with the side wall portion 2cc on the third direction CD3 side, and the downstream portion in the additional expansion space is from the side wall portion 2cc on the third direction CD3 side, It is separated to the rotating shaft 3a side. This downstream portion is a portion on the downstream side of the wind flow from the upstream portion in the additional expansion space.

  Here, according to the inventor's study, in the region A shown in FIG. 11, since the boundary between the mainstream 1 and the mainstream 2, a wind having a slower wind speed than the basic wind speed of the mainstream 1 or the mainstream 2 is generated. It became clear that it flowed. This region A is in the vicinity of the boundary between the side wall 2ca on the first direction CD1 side and the side wall 2cb on the second direction CD2 side in the ventilation space S, and on the side wall 2ca on the first direction CD1 side. Is a region away from the third direction CD3 side. That is, in this type of centrifugal blower, the wind speed of the wind passing through the region A is slow, so that the wind speed is uneven.

  Under such circumstances, in the present embodiment, as described above, the outermost edge OE in the centrifugal direction CD of the front portion in the rotational direction RD of the expansion portion 20 is the side wall portion on the first direction CD1 side. 2ca is directly connected. The outermost edge OE in the centrifugal direction CD of the portion of the extension portion 20 in the rotational direction RD is positioned farther to the third direction CD3 side than the side wall portion 2ca on the first direction CD1 side. ing.

  For this reason, in the centrifugal blower 100 according to the present embodiment, the fast wind flowing along the side wall portion 2ca on the side of the first direction CD1 flows through the internal space S1 of the expansion portion 20, and the wind with a relatively slow wind speed. The second direction CD2 side flows toward the discharge port 2e. Although the wind speed is slowed down by the expansion part 20, this wind is a wind with a fast wind speed (that is, a wind speed faster than that of the main stream 2) that originally flows along the side wall 2ca on the first direction CD1 side. In the centrifugal blower 100 according to the present embodiment, the wind having a high wind speed is passed through the region A that is located on the third direction CD3 side rather than the side wall part 2ca on the first direction CD1 side. Thus, the wind speed in the region A can be increased. Thereby, the wind speed of the wind which flows into the discharge port 2e by the side of 2nd direction CD2 can be made more uniform.

  In the present embodiment, as described above, the outermost edge OE in the centrifugal direction CD of the front portion in the rotational direction RD of the expansion portion 21 is directly connected to the side wall portion 2ca on the first direction CD1 side. Yes. And the outermost edge OE in the centrifugal direction CD of the portion on the distal side in the rotational direction RD of the extended portion 21 is positioned farther to the third direction CD3 side than the side wall portion 2ca on the first direction CD1 side. ing.

  For this reason, in the centrifugal blower 100 according to the present embodiment, the wind speed in the region A can be increased for the same reason as in the case of the expansion unit 20 described above, whereby the outlet on the second direction CD2 side. The wind speed of the wind flowing into 2e can be made more uniform.

  Further, in the present embodiment, as described above, the outermost edge OE in the centrifugal direction CD of the front portion in the rotational direction RD of the extended portion 22 is directly connected to the side wall portion 2cc on the third direction CD3 side. Yes. The outermost edge OE in the centrifugal direction CD of the portion on the distal side in the rotational direction RD of the extended portion 22 is located farther from the side of the first direction CD1 than the side wall 2cc on the third direction CD3 side. ing.

  For this reason, in the centrifugal blower 100 according to the present embodiment, the wind speed of the air flowing into the discharge port 2f on the fourth direction CD4 side can be made more uniform for the same reason as in the case of the expansion unit 20 described above. .

  In the present embodiment, as described above, the outermost edge OE in the centrifugal direction CD of the front portion in the rotational direction RD of the extended portion 23 is directly connected to the side wall portion 2cc on the third direction CD3 side. Yes. Then, the outermost edge OE in the centrifugal direction CD of the portion of the extended portion 23 in the rotational direction RD is positioned farther to the first direction CD1 side than the side wall portion 2cc on the third direction CD3 side. ing.

  For this reason, in the centrifugal blower 100 according to the present embodiment, the wind speed of the air flowing into the discharge port 2f on the fourth direction CD4 side can be made more uniform for the same reason as in the case of the expansion unit 20 described above. .

(Other embodiments)
The present disclosure is not limited to the above-described embodiment, and can be appropriately changed within the scope described in the claims.

  For example, in the first and second embodiments, the extension part 20 and the extension part 21 are arranged in substantially the same region in the centrifugal direction CD. Further, the extension part 22 and the extension part 23 are arranged in substantially the same region in the centrifugal direction CD. Therefore, in the first embodiment, as shown in FIG. 12, the extension part 20 and the extension part 21 may be arranged in different regions in the centrifugal direction CD. Similarly, in the first embodiment, the extension 22 and the extension 23 may be arranged in different regions in the centrifugal direction CD.

  Moreover, in the said embodiment, you may abbreviate | omit one of the expansion part 20 and the expansion part 21 (namely, delete a recessed part and make it a plane). FIG. 13 shows an example in which the extended portion 21 is omitted in the second embodiment (that is, the concave portion 2i is deleted to make a plane). Similarly, in the above-described embodiment, one of the extended portion 22 and the extended portion 23 may be omitted (that is, the concave portion may be deleted to make a plane).

  In the first and second embodiments, the extended portions 20 and 21 are formed so that the width W1 is substantially constant from the front side to the front side in the rotation direction RD. In the above embodiment, the extended portions 20 and 21 may be formed such that the width W1 is not substantially constant. Similarly, in the above embodiment, the extended portions 22 and 23 may be formed such that the width W3 is not substantially constant. In FIG. 14, in the second embodiment, an example is shown in which the extended portion 20 is formed so that the width W1 is narrowed from the near side to the far side in the rotation direction RD.

  Moreover, in 1st, 2nd embodiment, although the cross-sectional shape of the recessed parts 2h-2k was a square, the cross-sectional shape of the recessed parts 2h-2k is not restricted to this. That is, for example, in the above-described embodiment, as shown in FIG. 15, the cross-sectional shape of the recesses 2 h to 2 k may be an arc shape. Moreover, in the said embodiment, as shown in FIG. 16, it is good also considering the cross-sectional shape of the recessed parts 2h-2k as a triangle.

  In the above embodiment, one of the two discharge ports 2e and 2f may be discarded.

In the said embodiment, the discharge port 2e was formed as a part of other 2nd wall part 2bb. However, in the above-described embodiment, the discharge port 2e may be formed as a part of one second wall part 2ab, and is formed as a part of one second wall part 2ab and the other second wall part 2bb. Also good. In the above embodiment, the discharge port 2f is formed as a part of the fourth wall portion 2bd. However, similarly, it may be formed as a part of one fourth wall part 2ad, or may be formed as a part of one fourth wall part 2ad and the other fourth wall part 2bd.
(Summary)
In the first aspect shown in part or all of the above embodiments, in the centrifugal blower, from one wall portion to the other wall portion along the direction of the rotation axis in a predetermined basic expansion space in the basic inflow space. Is wider than the second width from the one wall portion to the other wall portion along the direction of the rotation axis in the inner space located closer to the rotation axis than the basic expansion space in the basic inflow space.

  In the second aspect, in the centrifugal blower according to the first aspect, the first direction from the rotation axis toward the upstream end of the wind flow in the basic expansion space while being orthogonal to the rotation axis, and the rotation axis while being orthogonal to the rotation axis Is perpendicular to the second direction toward the basic discharge hole. The basic expansion space is continuously formed so as to extend from at least a point on a predetermined straight line extending in the first direction to a point on a straight line parallel to the predetermined straight line and passing through the endmost point of the fan in the second direction. ing.

  According to the second aspect, the wind flowing in the vicinity of the side wall portion on the first direction side can surely flow to the discharge port on the second direction side as a relatively slow wind speed.

  In the third aspect, in the centrifugal blower according to the first or second aspect, the predetermined upstream portion in the basic expansion space is in contact with the side wall portion, and is downstream of the upstream portion in the basic expansion space on the downstream side of the wind flow. The part is away from the side wall.

  According to this 3rd viewpoint, the wind speed of the wind which flows into a discharge port can be made more uniform. The details are described in the description of the second embodiment.

  In the fourth aspect, the introduction hole is formed in one wall portion, and the basic discharge port is formed in the other wall portion.

  According to the fourth aspect, the wind introduced from the inlet can be provided from the outlet with a small pressure loss.

According to a fifth aspect, in the centrifugal blower according to any one of the first to fourth aspects, the first width is 1.5 times or more of the second width. Can be sufficiently slowed down and the wind speed can be sufficiently uniformed.

  In a sixth aspect, in the centrifugal blower according to any one of the first to fifth aspects, further, from the rotation axis to the side wall portion in a basic predetermined direction from the rotation axis to the basic discharge hole while being orthogonal to the rotation axis. The distance is shorter than the distance from the rotation axis to the side wall portion in a direction shifted by 90 ° to the reverse rotation side of the fan with respect to the basic predetermined direction while being orthogonal to the rotation axis.

  According to the sixth aspect, the fan case can be reduced in size by reducing the size of the fan case in a predetermined direction, and variations in wind speed and air volume can be suppressed.

  In the seventh aspect, in the centrifugal blower, the third width from the one wall portion to the other wall portion along the direction of the rotation axis in the predetermined additional expansion space in the additional inflow space is additionally expanded in the additional inflow space. It is wider than the 4th width from the one wall part to the other wall part along the direction of the rotating shaft in the inner space located in the side of a rotating shaft rather than space.

  According to the seventh aspect, the wind speed can be made uniform even in the configuration in which the discharge port is not provided on the predetermined direction which is the centrifugal direction of the fan. That is, in this centrifugal blower, even if the size in the predetermined direction is reduced, the wind speed can be made uniform.

  According to an eighth aspect, in the centrifugal blower according to the seventh aspect, a third direction from the rotation axis toward the upstream end of the wind flow in the basic expansion space while orthogonal to the rotation axis, and a rotation axis orthogonal to the rotation axis Is orthogonal to the fourth direction toward the additional discharge hole. Further, the additional expansion space is continuously formed so as to extend from at least a point on a predetermined straight line extending in the third direction to a point on a straight line parallel to the predetermined straight line and passing through the extreme end point of the fan in the fourth direction. ing.

  According to the eighth aspect, the wind flowing in the vicinity of the side wall portion on the third direction side can surely flow to the discharge port on the fourth direction side as a relatively slow wind speed.

  In the ninth aspect, in the centrifugal blower of the seventh or eighth aspect, the predetermined upstream portion in the additional expansion space is in contact with the side wall portion, and is downstream of the upstream portion in the additional expansion space on the downstream side of the wind flow. The part is away from the side wall.

  According to the ninth aspect, the wind speed of the wind flowing into the discharge port can be made more uniform. The details are described in the description of the second embodiment.

  In the 10th viewpoint, the introduction hole is formed in one wall part, and the additional discharge port is formed in the other wall part. According to the tenth aspect, the wind introduced from the inlet can be provided from the outlet with a small pressure loss.

According to an eleventh aspect, in the centrifugal blower according to any one of the seventh to tenth aspects, the third width is 1.5 times or more the fourth width. Can be sufficiently slowed down and the wind speed can be sufficiently uniformed.

  In a twelfth aspect, in the centrifugal blower according to any one of the seventh to eleventh aspects, further, from the rotation axis to the side wall portion in an additional predetermined direction from the rotation axis toward the additional discharge hole while being orthogonal to the rotation axis. The distance is shorter than the distance from the rotation axis to the side wall portion in a direction shifted by 90 ° about the rotation axis toward the reverse rotation side of the fan with respect to the additional predetermined direction while being orthogonal to the rotation axis.

  According to the twelfth aspect, the fan case can be reduced in size by reducing the size of the fan case in a predetermined direction, and the wind speed can be made uniform.

DESCRIPTION OF SYMBOLS 1 Fan 2 Fan case 2a One wall part 2b Other wall part 2c Side wall part 100 Centrifugal blower S10 Introduction hole S11 Basic discharge hole S12 Additional discharge hole

Claims (12)

A fan (1) that generates a wind flowing in a centrifugal direction (CD) about the rotation axis (P) by rotating;
A fan case (2) that encloses and houses the fan,
The fan case has one wall portion (2a) positioned on one side in the direction of the rotation axis with respect to the fan and the other wall portion (2b) positioned on the other side in the direction of the rotation shaft with respect to the fan. ) And a side wall (2c) located in a region outside the fan in the centrifugal direction,
The one wall portion, the other wall portion, and the side wall portion accommodate the fan so as to surround the fan,
The space surrounded by the one wall portion, the other wall portion, and the side wall portion forms a ventilation space (S) that is a space for allowing the wind to pass therethrough,
The fan case is formed with an introduction hole (S10) for introducing external air into the ventilation space, and a basic discharge hole (S11) for discharging the air passing through the ventilation space to the outside.
Of the ventilation space, in the basic inflow space which is shifted to the reverse rotation side of the fan with respect to the basic discharge hole with respect to the basic discharge hole, after exiting the fan and before flowing into the basic discharge hole The wind passes,
A first width (W1) from the one wall portion to the other wall portion along the direction of the rotation axis in a predetermined basic expansion space in the basic inflow space is greater than the basic expansion space in the basic inflow space. A centrifugal blower that is wider than a second width (W2) from the one wall portion to the other wall portion along the direction of the rotation shaft in the inner space located on the rotation shaft side. A first direction (CD1) from the rotation axis toward the upstream end of the wind flow of the basic expansion space while orthogonal to the rotation axis, and a second direction from the rotation axis to the basic discharge hole while orthogonal to the rotation axis (CD2) is orthogonal,
The basic expansion space is at least on a straight line (SL1) passing through the end point (PT4) of the fan in the second direction parallel to the predetermined straight line from a point (PT1) on the predetermined straight line extending in the first direction. The centrifugal blower according to claim 1, wherein the centrifugal blower is continuously formed so as to extend to the point (PT2, PT3).   The predetermined upstream portion in the basic expansion space is in contact with the side wall portion, and the downstream portion on the downstream side of the wind flow from the upstream portion in the basic expansion space is separated from the side wall portion. Centrifugal blower.   The centrifugal blower according to any one of claims 1 to 3, wherein the introduction hole is formed in the one wall portion, and the basic discharge hole is formed in the other wall portion.   The centrifugal blower according to any one of claims 1 to 4, wherein the first width is 1.5 times or more of the second width.   The distance from the rotation axis to the side wall portion in the basic predetermined direction (CD2) from the rotation axis toward the basic discharge hole while being orthogonal to the rotation axis is relative to the basic predetermined direction while being orthogonal to the rotation axis. The centrifuge according to any one of claims 1 to 5, wherein the centrifugal axis is shorter than a distance from the rotation axis to the side wall portion in a direction (CD1) shifted by 90 ° toward the reverse rotation side of the fan around the rotation axis. Type blower. The fan case is formed with an additional discharge hole (S12) for discharging the wind passing through the ventilation space to the outside.
In the additional inflow space that is shifted to the reverse rotation side of the fan around the rotation axis with respect to the additional discharge hole in the ventilation space, after exiting from the fan and before flowing into the additional discharge hole The wind passes,
A third width (W3) from the one wall portion to the other wall portion along the direction of the rotation axis in a predetermined additional expansion space in the additional inflow space is greater than the additional expansion space in the additional inflow space. A centrifugal blower that is wider than the fourth width (W2) from the one wall portion to the other wall portion along the direction of the rotation shaft in the inner space located on the rotation shaft side. A third direction (CD3) from the rotational axis toward the upstream end of the wind flow of the additional expansion space while orthogonal to the rotational axis, and a fourth direction from the rotational axis to the additional discharge hole while orthogonal to the rotational axis (CD4) is orthogonal,
The basic expansion space is at least on a straight line (SL2) passing through the end point (PT8) of the fan in the fourth direction parallel to the predetermined straight line from a point (PT5) on the predetermined straight line extending in the third direction. The centrifugal blower according to claim 7, which is continuously formed so as to extend to the point (PT6, PT7).   The predetermined upstream portion in the additional expansion space is in contact with the side wall portion, and the downstream portion on the downstream side of the wind flow from the upstream portion in the additional expansion space is separated from the side wall portion. Centrifugal blower.   The centrifugal blower according to any one of claims 7 to 9, wherein the introduction hole is formed in the one wall portion, and the additional discharge hole is formed in the other wall portion.   The centrifugal blower according to any one of claims 7 to 10, wherein the third width is 1.5 times or more of the fourth width.   The distance from the rotation axis to the side wall portion in the additional predetermined direction (CD4) from the rotation axis toward the additional discharge hole while orthogonal to the rotation axis is relative to the additional predetermined direction while orthogonal to the rotation axis. The centrifugal separation according to any one of claims 7 to 11, which is shorter than a distance from the rotation shaft to the side wall portion in a direction (CD3) shifted by 90 ° toward the reverse rotation side of the fan around the rotation shaft. Type blower.

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