JP2009234473A - Blower device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a blower device capable of blowing a uniform stream to a heat exchanger. <P>SOLUTION: This blower device is provided with a blower motor 15 having a rotary shaft 15a disposed in parallel with the heat exchanger 22 in a right and left direction of the heat exchanger 22, a blower 12 for blowing intake air, and first and second blower casings 13 and 14 having first and second air suction parts 13a and 14a and first and second air discharge ports 13b and 14b. The intake air sucked from the first air suction part 13a is blown by the blower 12 toward the first air discharge port 13b. The intake air sucked from the second air suction part 14a is blown by the blower 12 toward the second air discharge port 14b. The first air discharge port 13b blows intake air toward an upper side region in the vertical direction of the heat exchanger 22. The second air discharge port 14b blows intake air toward a lower side region in the vertical direction of the heat exchanger 22. As a result, the uniform stream can be blown to the heat exchanger. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a blower device that introduces intake air and blows air toward a heat exchanger disposed on the downstream side of the air flow, and in particular, uniformizes the flow of blown air that passes through the heat exchanger. About.

  Conventionally, as this type of blower device, for example, the one shown in Patent Document 1 is known. That is, in this blower device, the blower is disposed on the lower front side of the cooling heat exchanger disposed in the air conditioning case, and the discharge port of the scroll-like blower casing blows out on the front side of the cooling heat exchanger. Is arranged.

  In the blower device having such a configuration, when the blower is brought close to the cooling heat exchanger, there is a problem that the flow of the blown air passing through the cooling heat exchanger tends to be uneven. Therefore, in order to make the flow uniform, for example, as shown in FIG. 10, a trumpet-shaped duct portion 105 is formed at the discharge port 102 of the blower casing 101 and connected to the cooling heat exchanger 103.

  That is, the blower 104 is arranged so that the distance L1 between the discharge port 102 of the blower casing 101 and the front surface of the cooling heat exchanger 103 is increased. According to this, the physique of the front-back direction becomes large. Therefore, in the vehicle air conditioner, in order to reduce the physique in the front-rear direction, the blower 104 is arranged offset to the passenger seat side with respect to the cooling heat exchanger 103 as shown in FIG.

That is, the blower 104 is disposed on either side of the cooling heat exchanger 103 in the left-right direction, and the duct portion 105 is formed in the blower casing 101 and connected to the cooling heat exchanger 103. In such an arrangement, the air passage of the duct portion 105 must be formed in a complicated shape in order to make the flow of the blown air flowing through the cooling heat exchanger 103 uniform.
JP 2007-83774 A

  However, according to the arrangement shown in FIG. 10, there is a problem that the physique in the front-rear direction becomes large. Further, according to the arrangement as shown in FIG. 11, there is a problem that the physique in the left-right direction becomes large.

  Therefore, a first object of the present invention is to provide a blower device that can blow a uniform flow to a heat exchanger. Moreover, the 2nd objective is to provide the blower apparatus which can attain size reduction of an air blower.

In order to achieve the above object, the following technical means are adopted. That is, in the invention according to claim 1, in the blower device for introducing the intake air and blowing the intake air toward the heat exchanger (22) disposed on the downstream side of the air flow,
A blower motor (15) having a rotating shaft (15a) arranged in parallel with the heat exchanger (22) and a rotating shaft (15a) in the left-right direction of the heat exchanger (22), and blowing intake air And first and second blower casings (13, 14) having first and second air suction portions (13a, 14a) and first and second air discharge ports (13b, 14b). )
The intake air sucked from the first air suction part (13a) is blown by the blower (12) toward the first air discharge port (13b) and sucked from the second air suction part (14a). The air is blown by the blower (12) toward the second air discharge port (14b),
The first air discharge port (13b) blows intake air toward the upper region in the vertical direction of the heat exchanger (22), and the second air discharge port (14b) is the heat exchanger (22). Inhalation air is blown toward the lower region in the vertical direction.

  According to this invention, the blower (12) and the heat exchanger (22) are not excessively separated from each other, and a uniform flow of blown air is directed from the blower (12) to the heat exchanger (22). Can flow in. Furthermore, since the blower (12) can be brought close to the heat exchanger (22), the blower can be downsized.

  In the invention described in claim 2, the blower (12) is composed of a right blower (12) and a left blower (12) fixed to both ends of the rotary shaft (15a), respectively, and the blower casing (13, 14) are the first and second blower casings (13, 14) on the right side for blowing the intake air by the right side blower (12), and the first and second sides on the left side for blowing the intake air by the left side blower (12). The first blower casing (13) on the right side blows intake air toward the upper or lower region in the vertical direction of the heat exchanger (22). The right second blower casing (14) blows intake air toward the lower or upper region in the vertical direction of the heat exchanger (22), and the left first blower casing (13) The intake air is blown toward the upper or lower region in the vertical direction of the exchanger (22), and the second blower casing (14) on the left side is the lower or upper region in the vertical direction of the heat exchanger (22). It is characterized by blowing inhaled air toward

  According to this invention, since the size of the blower (12) and the heat exchanger (22) in the front-rear direction can be reduced, a uniform flow of blown air can be introduced, and the blower can be downsized. I can plan.

In the invention according to claim 3, in the blower device for introducing the intake air and blowing the intake air toward the heat exchanger (22) disposed on the downstream side of the air flow,
A blower motor (15) having a rotating shaft (15a) disposed in parallel with the heat exchanger (22) in the vertical direction of the heat exchanger (22), and fixed to the rotating shaft (15a), blows intake air. And first and second blower casings (13, 14) having first and second air suction portions (13a, 14a) and first and second air discharge ports (13b, 14b). )
The intake air sucked from the first air suction part (13a) is blown by the blower (12) toward the first air discharge port (13b) and sucked from the second air suction part (14a). The air is blown by the blower (12) toward the second air discharge port (14b),
The first air discharge port (13b) blows intake air toward the right region in the left-right direction of the heat exchanger (22), and the second air discharge port (14b) is the heat exchanger (22). Inhalation air is blown toward the left region in the left-right direction.

  According to this invention, the blower (12) and the heat exchanger (22) are not excessively separated from each other, and a uniform flow of blown air is directed from the blower (12) to the heat exchanger (22). Can flow in. Furthermore, since the blower (12) can be brought close to the heat exchanger (22), the blower can be downsized.

In the invention according to claim 4, the blower (12) is composed of an upper blower (12) and a lower blower (12) fixed to both ends of the rotating shaft (15a), respectively.
The blower casings (13, 14) are a lower first blower casing (13, 14) for blowing intake air by the upper blower (12) and a lower blower (12) for blowing intake air. Side first and second blower casings (13, 14), and the upper first blower casing (13) is directed toward the right or left side region in the left-right direction of the heat exchanger (22). The upper second blower casing (14) blows the intake air toward the left or right region in the left-right direction of the heat exchanger (22), and the lower first blower casing. (13) blows intake air toward the right or left region in the left-right direction of the heat exchanger (22), and the lower second blower casing (14) is the left-right direction of the heat exchanger (22). In Kicking is characterized by blowing suction air toward the left or right area.

  According to this invention, since the physique of the left-right direction of a blower (12) and a heat exchanger (22) can be made small, while being able to flow in the blowing air of a uniform flow, size reduction of an air blower can be carried out. I can plan.

  In the invention according to claim 5, the first and second blower casings (13, 14) have the first and second air discharge ports (13b, 14b) in the axial direction of the rotating shaft (15a). It is characterized by being expanded in the opposite direction.

  According to this invention, the distance between the blower (12) and the heat exchanger (22) can be reduced. As a result, a uniform flow of blown air can be introduced, and the size of the blower can be reduced.

  The invention described in claim 6 is characterized in that the blower (12) is constituted by a centrifugal multi-blade fan of a double-side suction type. According to this invention, the distance between the blower (12) and the heat exchanger (22) can be reduced.

  In the invention according to claim 7, the first and second air suction portions (13a, 14a) of the first and second blower casings (13, 14) overlap in the axial direction of the rotating shaft (15a). The first air suction part (13a) is formed at one axial end of the blower (12), and the second air suction part (14a) 12) is formed at the other axial end, and the blower (12) rotates the intake air in the same direction while the first and second air in the first and second blower casings (13, 14). Intake air is blown toward the discharge ports (13b, 14b). According to the present invention, it is possible to easily form the first and second blower casings (13, 14) arranged adjacent to each other. Thereby, size reduction of an air blower can be achieved.

  In addition, the code | symbol in the bracket | parenthesis of each said means shows a corresponding relationship with the specific means of embodiment mentioned later.

(First embodiment)
Hereinafter, the blower device according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 5 as an example in which the blower device is applied to a vehicle air conditioner. FIG. 1 is a configuration diagram showing the overall configuration of the blower apparatus in the present embodiment. FIG. 2 is a view taken in the direction of arrow II shown in FIG. 3 is a cross-sectional view taken along the line III-III shown in FIG. 4 is a cross-sectional view taken along the line IV-IV shown in FIG. FIG. 5 is an arrow view showing the overall shape of the blower device.

  The up and down arrows shown in FIG. 1 indicate directions in the vehicle mounted state. Accordingly, the “front / rear direction” is the traveling direction of the vehicle when the air conditioning unit 10 is mounted on the vehicle, and the “left / right direction” is the left / right direction (vehicle width direction) when the air conditioning unit 10 is mounted on the vehicle. The “vertical direction” refers to a vertical direction when the air conditioning unit 10 is mounted on a vehicle.

  The air conditioning unit 10 of the present embodiment is mounted inside an instrument panel (instrument panel) in a vehicle interior. As shown in FIG. 1, the air conditioning unit 10 is roughly divided into two parts, a blower unit 11 and an air conditioning case 20.

  The air-conditioning case 20 forming the air passage is made of a resin molded product having elasticity to some extent and excellent in strength, such as polypropylene, and is composed of a plurality of divided cases. The divided case accommodates components such as a heat exchanger 22 (to be described later) and an air volume adjustment switching door (not shown) and an outlet switching door which are not shown in the figure, and is then integrally coupled by a fastening means such as a metal spring clip or a screw. 20 is configured.

  A heat exchanger 22 composed of a refrigeration cycle is disposed on the upstream end side of the air conditioning case 20. The refrigeration cycle includes a compressor, a condenser, a liquid receiver, an expansion valve, and a heat exchanger 22 (not shown). Then, by turning on an electromagnetic clutch (not shown), the compressor is driven and the refrigerant circulates in the refrigeration cycle. It is a heat exchanger for cooling which cools the air blown from the blower unit 11 by exchanging heat with the inflowing refrigerant.

  A heater core (not shown) is provided on the downstream side of the air flow of the heat exchanger 22. The heater core is a heating heat exchanger that heats the air that has passed through the heat exchanger 22 by exchanging heat with the cooling water of the engine.

  On the upstream side of the air flow of the blower unit 11, an inside air introduction port for introducing unshown vehicle interior air (inside air) and an outside air introduction port for introducing vehicle compartment outside air (outside air) are formed. Accordingly, an inside / outside air switching door (not shown) for selectively opening and closing the inside air introduction port and the outside air introduction port is provided.

  The blower unit 11 is a blower that is disposed on one end side of the air conditioning case 20 and sucks intake air of the inside air or the outside air and blows it toward the heat exchanger 22 disposed on the downstream side of the air flow. That is, it is a blower that generates an air flow from one end side of the air conditioning case 20 toward the vehicle interior. The blower unit 11 of the present embodiment is arranged on the front side of the heat exchanger 22 so that the axis of the blower 12, that is, the rotation shaft 12 a of the blower motor 15 is parallel to the left-right direction of the heat exchanger 22. .

  As shown in FIGS. 2 and 5, the blower unit 11 includes two blowers 12, a plurality (two in this example) of first and second blower casings 13 and 14, and a blower motor 15. The blower motor 15 is a double-shaft type, and the blower 12 is disposed on the rotary shafts 15a of both shafts. The blower motor 15 is controlled by a blower motor drive circuit (not shown). The blower motor 15 is disposed at a substantially central portion with respect to the left-right direction of the heat exchanger 22.

  The blower 12 is a double-suction type centrifugal multi-blade fan, and is disposed in the first and second blower casings 13 and 14 disposed adjacent to each other. The first and second blower casings 13 and 14 of the present embodiment are arranged adjacent to one blower 12 in the axial direction of the blower 12. Accordingly, the first and second blower casings 13 and 14 arranged adjacent to each other are provided on both shaft sides of the blower motor 15.

  Each of the first and second blower casings 13 and 14 is formed in the same winding direction with respect to the axial direction of the blower 12 and the first and second air discharge ports 13b and 14b are provided at different positions. It has been. The first and second blower casings 13 and 14 disposed adjacent to each other have a height direction and a first blower casing 13 provided with a first air discharge port 13b on the upper side in the height direction (vertical direction). It is comprised from the 2nd blower casing 14 in which the 2nd air discharge port 14b was provided in the downward side (up-down direction).

  The first and second blower casings 13 and 14 rectify the radial flow discharged from the blower 12 and combine them in one direction, and efficiently generate the dynamic pressure obtained by the multi-blade fan. It is to convert to. Therefore, a plurality (two in this example) of the first and second blower casings 13 and 14 of the present embodiment have the first and second air discharge ports 13b and 14b in the heat exchanger 22, respectively. On the other hand, it is formed so as to blow out at different positions.

  More specifically, as shown in FIGS. 2 and 5, a first blower casing 13 is disposed on one side (right side) of the blower motor 15, and on the outer side (left-right direction) of the first blower casing 13. A second blower casing 14 is disposed. A first blower casing 13 is disposed on the other (left side) side of the blower motor 15, and a second blower casing 14 is disposed on the outer side (left-right direction) of the first blower casing 13.

  The first blower casing 13 is formed such that the first air discharge port 13b blows out the blown air from the central portion toward the upper portion, that is, the upper region with respect to the height direction (vertical direction) of the heat exchanger 22. Has been. The first blower casing 13 disposed on one side (right side) of the blower motor 15 has a first air discharge port 13b with respect to the horizontal direction of the heat exchanger 22 from the central portion to the right portion, that is, the right side. It arrange | positions so that blowing air may be blown out toward an area | region.

  The first blower casing 13 disposed on the other (left) side of the blower motor 15 has a discharge port 13b from the center portion to the left portion, that is, the left region with respect to the horizontal direction of the heat exchanger 22. It arrange | positions so that blowing air may be blown out.

  In the other second blower casing 14, the second air discharge port 14 b blows air from the central portion to the lower portion, that is, the lower region with respect to the height direction (vertical direction) of the heat exchanger 22. It is formed to blow out. The second blower casing 14 disposed on one side (right side) of the blower motor 15 has a second air discharge port 14b in the right and left direction of the heat exchanger 22 from the central portion to the right portion, that is, the right side. It arrange | positions so that blowing air may be blown out toward an area | region.

  The second blower casing 14 disposed on the other (left) side of the blower motor 15 has a second air discharge port 14b in the left-right direction of the heat exchanger 22 from the center portion to the left portion, that is, the left side. It arrange | positions so that blowing air may be blown out toward an area | region.

  Incidentally, the first and second blower casings 13 and 14 disposed adjacent to each other in the axial direction of the blower 12 are integrally formed. Reference numeral 13 a shown in FIGS. 1 and 2 is a first air suction part provided at a position corresponding to one suction part of the blower 12, and reference numeral 14 a corresponds to the other suction part of the blower 12. It is the 2nd air suction part provided in the position.

  That is, the first and second blower casings 13 and 14 are provided with first and second air suction portions 13a and 14b independently on the side surfaces facing each other. The first air suction portion 13 a is formed at one axial end of the blower 12, and the second air suction portion 14 a is formed at the other axial end of the blower 12.

  The first and second air suction portions 13 a and 14 a cover the blower 12 so as to overlap in the axial direction of the rotary shaft 15 a of the blower motor 15. According to such a configuration, the first and second blower casings 13 and 14 can be easily formed integrally.

  Moreover, the code | symbol 14d shown in FIG. 2 is a partition member. The partition member 14 d is a partition plate that partitions the blown air discharged by the blower 12. It is provided on the side plate adjacent to the first blower casing 13 and the second blower casing 14.

  Thereby, the intake air sucked from the first air suction portion 13a is blown out from the first air discharge port 13b, and the suction air sucked from the second air suction portion 14a is changed to the second air discharge port. 14b.

  Next, the shapes of the first and second air discharge ports 13b and 14b provided in the first and second blower casings 13 will be described with reference to FIGS. FIG. 3 shows the flow of air in the first blower casing 13, and FIG. 4 shows the flow of air in the second blower casing 14.

  As shown in FIG. 3, the first blower casing 13 has a downstream end of the first air discharge port 13b divided into two parts (H) as described above with respect to the height direction (vertical direction) of the heat exchanger 22. = H) is formed so as to connect the upper portions. In other words, the first air outlet 13b is formed so that the air passage gradually expands as it approaches the front surface of the heat exchanger 22 from the uppermost end of the blower 12.

  That is, it is formed in a substantially trumpet shape. As a result, the intake air introduced from the first air intake portion 13a can be blown out into the upper portion divided into two (H = H), that is, the upper region.

  As shown in FIG. 4, in the second blower casing 14, the downstream end of the second air discharge port 14 b is divided into two (H = H) with respect to the height direction (vertical direction) of the heat exchanger 22. It is formed so as to connect the lower part from the central part. In other words, the second air discharge port 14b is formed so that the air passage gradually expands as it approaches the front surface of the heat exchanger 22 from the uppermost end of the blower 12.

  That is, it is formed in a substantially trumpet shape. Thereby, the suction air introduced from the second air suction part 14a can be blown out to the lower part divided into two (H = H), that is, the lower region.

  Further, as shown in FIGS. 2 and 5, the first air outlet 13b of the first blower casing 13 is connected to the first air suction portion 13a toward the downstream end of the first air outlet 13b. The side surface on the opposite side is formed so as to expand in the axial direction of the blower 12. In other words, the air passage is formed so that the air passage gradually expands as it approaches the front surface of the heat exchanger 22 also in the left-right opening of the first air discharge port 13b.

  Similarly, the second air outlet 14b of the second blower casing 14 is formed such that the air passage gradually expands as the opening in the left-right direction approaches the front surface of the heat exchanger 22. . For example, in the first blower casing 13 on the right side in FIG. 2, the downstream end of the first air discharge port 13 b extends in the right direction in the figure, while in the second blower casing 14, The downstream end of the second air discharge port 14b extends in the left direction in the figure.

  In other words, the first and second air discharge ports 13b and 14b of the first and second blower casings 13 and 14 disposed adjacent to each other are expanded along opposite directions in the axial direction of the blower 12. Is formed. Thereby, the distance of the blower 12 and the heat exchanger 22 can be made small.

  Next, the operation of the blower unit 11 configured as above will be described. When the blower motor 15 is driven to rotate the blower 12, blown air is blown out from the first and second air discharge ports 13 b and 14 b of the first and second blower casings 13 and 14 toward the heat exchanger 22. Is done.

  Here, each of the first and second air discharge ports 13b and 14b is one of positions substantially divided into four with respect to the front surface area of the heat exchanger 22, that is, upward (leftward) or downward from the central portion. Since it arrange | positions so that it may blow out toward (right side), the distance of the blower 12 and the heat exchanger 22 can be made small. Thereby, the blast air of a uniform flow can be made to flow into the heat exchanger 22.

  In other words, the blower 12 and the heat exchanger 22 are not excessively separated from each other, and a uniform flow of blown air can be introduced from the blower 12 toward the heat exchanger 22. Moreover, since the blower 12 can be brought close to the heat exchanger 22, the size in the front-rear direction can be reduced, and the blower can be downsized.

(Second Embodiment)
In the first embodiment described above, the first air discharge port 13b of the first blower casing 13 is directed from the center portion to the upper portion, that is, the upper region with respect to the height direction (vertical direction) of the heat exchanger 22. The blower air is blown out, but the blower air may be blown out from the central portion toward the lower portion, that is, the lower region with respect to the height direction (vertical direction) of the heat exchanger 22. .

  In this case, the second air outlet 14b of the second blower casing 14 is blown air from the central portion toward the upper portion, that is, the upper region with respect to the height direction (vertical direction) of the heat exchanger 22. It will be formed to blow out.

  FIG. 6 is a configuration diagram showing the overall configuration of the blower device in the present embodiment. 7 is a view taken along arrow VII shown in FIG.

  More specifically, as shown in FIGS. 6 and 7, the first blower casing 13 has a first air discharge port 13 b from the center portion with respect to the height direction (vertical direction) of the heat exchanger 22. The blower air is blown out toward the lower portion, that is, the lower region. The first blower casing 13 disposed on one side (right side) of the blower motor 15 has a first air discharge port 13b with respect to the horizontal direction of the heat exchanger 22 from the central portion to the right portion, that is, the right side. It arrange | positions so that blowing air may be blown out toward an area | region.

  The first blower casing 13 disposed on the other (left) side of the blower motor 15 has a discharge port 13b from the center portion to the left portion, that is, the left region with respect to the horizontal direction of the heat exchanger 22. It arrange | positions so that blowing air may be blown out.

  In the other second blower casing 14, the second air discharge port 14 b blows out the blown air from the central portion toward the upper portion, that is, the upper region with respect to the height direction (vertical direction) of the heat exchanger 22. It is formed as follows. The second blower casing 14 disposed on one side (right side) of the blower motor 15 has a second air discharge port 14b in the right and left direction of the heat exchanger 22 from the central portion to the right portion, that is, the right side. It arrange | positions so that blowing air may be blown out toward an area | region.

  The second blower casing 14 disposed on the other (left) side of the blower motor 15 has a second air discharge port 14b in the left-right direction of the heat exchanger 22 from the center portion to the left portion, that is, the left side. It arrange | positions so that blowing air may be blown out toward an area | region.

  According to the configuration as described above, each of the first and second air discharge ports 13b and 14b is positioned substantially divided into four with respect to the front area of the heat exchanger 22 as in the first embodiment. Since it is arranged to blow out upward (leftward) or downward (rightward) from the central portion, the distance between the blower 12 and the heat exchanger 22 can be reduced. Thereby, the blast air of a uniform flow can be made to flow into the heat exchanger 22.

(Third embodiment)
In the first and second embodiments described above, on the front side of the heat exchanger 22, the axis of the blower 12, that is, the rotating shaft 12 a of the blower motor 15 is arranged in parallel along the left-right direction of the heat exchanger 22. However, the blower unit 11 may be offset from the heat exchanger 22 in the left-right direction. FIG. 8 is a schematic diagram showing an arrangement relationship between the blower and the heat exchanger in the present embodiment.

  In the present embodiment, as shown in FIG. 8, the blower 12 is arranged on the lateral side of the heat exchanger 22 in the left-right direction, and the axis of the blower 12 is set in the height direction (vertical direction) of the heat exchanger 22. It is arrange | positioned so that it may become parallel along. That is, the rotating shaft 12 a of the blower motor 15 is arranged in the vertical direction of the heat exchanger 22.

  And the 1st and 2nd blower casings 13 and 14 arrange | positioned adjacently are toward the right part (right area | region) or the left part (left area | region) from the center part with respect to the left-right direction of the heat exchanger 22. The blower air is blown out.

  The first blower casing 13 blows air from the central portion where the first air discharge port 13b is divided into two (L = L) in the left-right direction of the heat exchanger 22 toward the right portion, that is, the right region. It is formed to blow out air. In the second blower casing 14, the second air discharge port 14 b is directed from the center portion divided into two (L = L) with respect to the horizontal direction of the heat exchanger 22 to the right portion, that is, the right region. The blower air is blown out.

  In this embodiment, the 1st and 2nd blower casings 13 and 14 are arrange | positioned at the both ends of the blower motor 15, ie, the one side and the other side of an up-down direction, respectively. More specifically, the first blower casing 13 arranged on one side (lower side) of the blower motor 15 has a first air discharge port 13b in the center with respect to the height direction (vertical direction) of the heat exchanger 22. It arrange | positions so that blowing air may be blown out toward a lower part from the part, ie, a lower right area | region.

  And the 1st blower casing 13 arrange | positioned at the other (upper) side of the blower motor 15 has the 1st air discharge port 13b with respect to the height direction (up-down direction) of the heat exchanger 22, and an upper part from a center part. That is, the air is blown out toward the upper right region.

  Similarly, in the second blower casing 14 arranged on one side (lower side) of the blower motor 15, the second discharge port 14 b is downward from the center portion with respect to the height direction (vertical direction) of the heat exchanger 22. It arrange | positions so that blowing air may be blown out toward a part, ie, the lower left side area | region.

  The second blower casing 14 disposed on the other (upper) side of the blower motor 15 has a second air discharge port 14b from the center portion to the upper portion with respect to the height direction (vertical direction) of the heat exchanger 22. That is, it arrange | positions so that blowing air may be blown out toward the upper left area | region.

  Further, the opening in the height direction (vertical direction) of the first and second air discharge ports 13b and 14b of the first and second blower casings 13 and 14 is the same as that of the first embodiment. In the axial direction, it is formed so as to be expanded along directions opposite to each other.

  According to the configuration as described above, as in the first and second embodiments, the distance between the blower 12 and the heat exchanger 22 is not excessively increased, and from the blower 12 toward the heat exchanger 22, A uniform flow of blown air can be introduced. Moreover, since the blower 12 can be brought close to the heat exchanger 22, the physique in the left-right direction can be reduced, and the size of the blower can be reduced.

(Fourth embodiment)
In the above embodiment, the first and second blower casings 13 and 14 arranged adjacent to each other are formed in the same winding direction, but may be formed in opposite directions. FIG. 9 is a schematic diagram showing an arrangement relationship between the blower and the heat exchanger in the present embodiment.

  As shown in FIG. 9, the first and second blower casings 13, 14 of the present embodiment are formed such that the scroll winding direction is opposite to the rotation direction of the blower 12, and the first and second The air discharge ports 13b and 14b are provided at different positions. The first and second blower casings 13 and 14 disposed adjacent to each other have a height direction and a first blower casing 13 provided with a first air discharge port 13b on the upper side in the height direction (vertical direction). It is comprised from the 2nd blower casing 14 in which the 2nd air discharge port 14b was provided in the downward side (up-down direction).

  In the first blower casing 13 and the second blower casing 14, the winding direction of the scroll is opposite. However, in this case, since the rotation directions of the blowers 12 disposed in the first and second blower casings 13 and 14 are different from each other, they are applied to the first and second blower casings 13 and 14, respectively. The blower 12 and the blower motor 15 for rotating the blower 12 need to be arranged separately. That is, it is necessary to dispose the one-side suction type blowers 12 having different rotation directions in the first and second blower casings 13 and 14 disposed adjacent to each other.

(Other embodiments)
In the first and second embodiments described above, two blowers 12 are disposed in the blower motor 15 for both shafts. However, one or a plurality of blowers 12 may be provided. Moreover, although the heat exchanger 22 arrange | positioned in the downstream of the air flow of the blower 12 was demonstrated with the cooling heat exchanger for refrigeration cycles, it is not restricted to a cooling heat exchanger.

It is a block diagram which shows the whole structure of the blower apparatus in 1st Embodiment. It is II arrow line view shown in FIG. It is III-III sectional drawing shown in FIG. It is IV-IV sectional drawing shown in FIG. It is an arrow line view which shows the whole blower apparatus shape in 1st Embodiment. It is a block diagram which shows the whole structure of the blower apparatus in 2nd Embodiment. It is a VII arrow line view shown in FIG. It is a schematic diagram which shows the arrangement | positioning relationship between the blower and heat exchanger in 3rd Embodiment. It is a schematic diagram which shows the arrangement | positioning relationship between the blower and heat exchanger in 4th Embodiment. It is a schematic diagram which shows the arrangement | positioning relationship between the blower and heat exchanger in a prior art. It is a schematic diagram which shows the arrangement | positioning relationship between the blower and heat exchanger in a prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 12 ... Blower, left side blower, right side blower, upper side blower, lower side blower 13 ... 1st blower casing, blower casing 13a ... 1st air suction part 13b ... 1st air discharge port 14 ... 1st Blower casing, blower casing 14a ... second air suction portion 14b ... second discharge port 15 ... blower motor 15a ... rotary shaft 22 ... heat exchanger

Claims (7)

In the blower device that introduces intake air and blows the intake air toward the heat exchanger (22) disposed on the downstream side of the air flow,
A blower motor (15) having a rotating shaft (15a) disposed in parallel with the heat exchanger (22) in the left-right direction of the heat exchanger (22);
A blower (12) which is fixed to the rotating shaft (15a) and blows intake air;
First and second air suction portions (13a, 14a) and first and second blower casings (13, 14) having first and second air discharge ports (13b, 14b), and
The intake air sucked from the first air suction part (13a) is blown by the blower (12) toward the first air discharge port (13b),
The intake air sucked from the second air suction portion (14a) is blown by the blower (12) toward the second air discharge port (14b),
The first air discharge port (13b) blows the intake air toward an upper region in the vertical direction of the heat exchanger (22),
The blower device, wherein the second air discharge port (14b) blows the intake air toward a lower region in the vertical direction of the heat exchanger (22). The blower (12) is composed of a right blower (12) and a left blower (12) fixed to both ends of the rotating shaft (15a), respectively.
The blower casings (13, 14) include right first and second blower casings (13, 14) for blowing the intake air by the right blower (12), and the intake air by the left blower (12). And the left and first blower casings (13, 14) on the left side.
The first blower casing (13) on the right side blows the intake air toward the upper or lower region in the vertical direction of the heat exchanger (22),
The second blower casing (14) on the right side blows the intake air toward the lower or upper region in the vertical direction of the heat exchanger (22),
The first blower casing (13) on the left side blows the intake air toward the upper or lower region in the vertical direction of the heat exchanger (22),
The blower according to claim 1, wherein the second blower casing (14) on the left side blows the intake air toward a lower or upper region in the vertical direction of the heat exchanger (22). apparatus. In the blower device that introduces intake air and blows the intake air toward the heat exchanger (22) disposed on the downstream side of the air flow,
A blower motor (15) having a rotating shaft (15a) disposed in parallel with the heat exchanger (22) in the vertical direction of the heat exchanger (22);
A blower (12) which is fixed to the rotating shaft (15a) and blows intake air;
First and second air suction portions (13a, 14a) and first and second blower casings (13, 14) having first and second air discharge ports (13b, 14b), and
The intake air sucked from the first air suction part (13a) is blown by the blower (12) toward the first air discharge port (13b),
The intake air sucked from the second air suction portion (14a) is blown by the blower (12) toward the second air discharge port (14b),
The first air discharge port (13b) blows the intake air toward a right region in the left-right direction of the heat exchanger (22),
The blower device, wherein the second air discharge port (14b) blows the intake air toward a left region in the left-right direction of the heat exchanger (22). The blower (12) is composed of an upper blower (12) and a lower blower (12) fixed to both ends of the rotating shaft (15a), respectively.
The blower casings (13, 14) are formed by upper and lower blower casings (13, 14) for blowing the intake air by the upper blower (12) and the suction by the lower blower (12). It consists of lower first and second blower casings (13, 14) that blow air,
The upper first blower casing (13) blows the intake air toward the right or left region in the left-right direction of the heat exchanger (22),
The upper second blower casing (14) blows the intake air toward the left or right region in the left-right direction of the heat exchanger (22),
The lower first blower casing (13) blows the intake air toward the right or left region in the left-right direction of the heat exchanger (22),
4. The blower according to claim 3, wherein the lower second blower casing (14) blows the intake air toward a left or right region in a left-right direction of the heat exchanger (22). apparatus.   In the first and second blower casings (13, 14), the first and second air discharge ports (13b, 14b) are enlarged in opposite directions in the axial direction of the rotating shaft (15a). The blower device according to any one of claims 1 to 4, wherein the blower device is provided.   The blower device according to any one of claims 1 to 5, wherein the blower (12) comprises a double-sided suction type centrifugal multi-blade fan. The first and second air suction portions (13a, 14a) of the first and second blower casings (13, 14) overlap with each other in the axial direction of the rotary shaft (15a). Covering
The first air suction portion (13a) is formed at one axial end of the blower (12), and the second air suction portion (14a) is the other axial direction of the blower (12). Formed at the end,
The blower (12) is directed toward the first and second air discharge ports (13b, 14b) of the first and second blower casings (13, 14) while rotating the intake air in the same direction. The blower device according to any one of claims 1 to 6, wherein the intake air is blown.

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