AU2018272238B2 - Indoor unit for air conditioner - Google Patents

Abstract

This indoor unit for an air conditioner is provided with: a casing main body (1); a turbo fan (30) which is disposed in the casing main body (1); a heat exchanger (40) which is disposed in the casing main body (1) so as to surround three sides of the turbo fan (30); a partition plate (50) which connects the two ends of the heat exchanger (40), and which, along with the heat exchanger (40), surrounds the turbo fan (30); and a blow-out port (10) which is provided on the side of the heat exchanger (40) opposite to the partition plate (50) such that blown out air is blown out downwards. The downstream side of an air passage (P) from the heat exchanger (40) to the blow-out port (10) in the casing main body (1) has a cross-sectional shape which has: a first air passage area (Aa) extending along one side of the casing main body (1); and second air passage areas (Ab) which extend from the two ends of the first air passage area (Aa) towards the side of a second wall part (12). Accordingly, an indoor unit for an air conditioner is provided which is capable of reducing pressure loss in the air passage, and improving performance.

Description

DESCRIPTION TITLE OF INVENTION: INDOOR UNIT FOR AIR CONDITIONER TECHNICAL FIELD

[0001]

The present invention relates to an indoor unit for an air conditioner.

BACKGROUND ART

[0002]

A conventional indoor unit for an air conditioner includes a heat exchanger having a U

shape and a turbo fan configured to suck in and blow out air in three directions via the heat

exchanger (see, for example, JP 2002-349890 A (Patent Literature 1)).

CITATION LIST PATENT LITERATURE

[0003]

Patent Literature 1: JP 2002-349890 A

SUMMARY OF INVENTION

[0004]

In the conventional indoor unit for an air conditioner, desirably, opposite heat exchange

parts of the heat exchanger having the U shape extend in parallel.

[0005]

However, if an indoor unit for an air conditioner is configured to blow out air in one

direction, the use of the heat exchanger having the U shape and including the opposite heat

exchange parts extending in parallel imposes limitations on a space for an air flow path and

hinders satisfactory increase in sectional area of the air flow path, which leads to degradation in

performance.

[0006]

It is an object of the present invention to substantially overcome, or at least ameliorate, at least

one disadvantage of present arrangements. Some embodiments of the present invention are

intended to provide an indoor unit for an air conditioner, the indoor unit being capable of

increasing a sectional area of an air flow path and reducing a pressure loss at the air flow path

with a simple configuration to thereby improve performance.

[0006a]

According to an aspect of the present invention, there is provided an indoor unit for an

air conditioner, comprising:

a casing;

a centrifugal fan disposed in the casing;

a heat exchanger disposed in the casing such that the centrifugal fan is surrounded by the

heat exchanger on three sides, the heat exchanger having a first heat exchange part opposite to a

blow-out port, a second heat exchange part elongated from a first end of the first heat exchange

part, and a third heat exchange part elongated from a second end of the first heat exchange part,

with sections connecting the first heat exchange part with each of the second and third heat

exchange parts being curved;

a partition connected to two ends of the heat exchanger to surround the centrifugal fan in

conjunction with the heat exchanger; and

the blow-out port through which air is blown out downward, the blow-out port being

formed in the casing at a position opposite to the partition with respect to the heat exchanger,

wherein

an air flow path from the heat exchanger to the blow-out port in the casing at least

partially has, at its downstream side, a sectional shape including a first air flow path region

extending along an edge of the casing and second air flow path regions respectively elongated

from two ends of the first air flow path region toward the partition, and

the blow-out port includes:

2a

a first blow-out port part extending along an edge of the casing, and

second blow-out port parts respectively elongated from two ends of the first blow-out

port part toward the partition,

a clearance between the second heat exchange part and an opposite edge, or side, of the casing

to the second heat exchange part and a clearance between the third heat exchange part and an

opposite edge, or side, of the casing to the third heat exchange part are tapered from the first

heat exchange part toward a distal end of the second heat exchange part and a distal end of the

third heat exchange part, respectively,

a region defined by a first plane including a line that is in contact with the first heat

exchange part and in parallel with a longitudinal direction of the first blow-out port part, a

second plane that is in contact with an outer face of the second heat exchange part excluding the

joint between the first heat exchange part and the second heat exchange part, and an outer face

of the heat exchanger overlaps a part of the blow-out port in plan view, and

a region defined by the first plane including the line that is in contact with the first heat

exchange part and in parallel with the longitudinal direction of the first blow-out port part, a

third plane that is in contact with an outer face of the third heat exchange part excluding the

joint between the first heat exchange part and the third heat exchange part, and the outer face of

the heat exchanger overlaps a part of the blow-out port in plan view.

[0006b]

According to an aspect of the present invention, there is provided an indoor unit for an air

conditioner, comprising:

a casing;

a centrifugal fan disposed in the casing;

a heat exchanger disposed in the casing such that the centrifugal fan is surrounded by the

heat exchanger on three sides, the heat exchanger having a first heat exchange part opposite to a

blow-out port, a second heat exchange part elongated from a first end of the first heat exchange

part, and a third heat exchange part elongated from a second end of the first heat exchange part,

2b

with sections connecting the first heat exchange part with each of the second and third heat

exchange parts being curved;

a partition connected to two ends of the heat exchanger to surround the centrifugal fan in

conjunction with the heat exchanger; and

the blow-out port through which air is blown out downward, the blow-out port being

formed in the casing at a position opposite to the partition with respect to the heat exchanger,

wherein

an air flow path from the heat exchanger to the blow-out port in the casing at least

partially has, at its downstream side, a sectional shape including a first air flow path region

extending along an edge of the casing and second air flow path regions respectively elongated

from two ends of the first air flow path region toward the partition, and

the blow-out port includes:

a first blow-out port part extending along an edge of the casing, and

second blow-out port parts respectively elongated from two ends of the first blow-out

port part toward the partition,

wherein the second heat exchange part and the third heat exchange part extend in parallel with

the opposite edges, or sides, of the casing to the second heat exchange part and the third heat

exchange part, respectively,

a region defined by a first plane including a line that is in contact with the first heat

exchange part and in parallel with a longitudinal direction of the first blow-out port part, a

second plane that is in contact with an outer face of the second heat exchange part excluding the

joint between the first heat exchange part and the second heat exchange part, and an outer face

of the heat exchanger overlaps a part of the blow-out port in plan view, and

a region defined by the first plane including the line that is in contact with the first heat

exchange part and in parallel with the longitudinal direction of the first blow-out port part, a

third plane that is in contact with an outer face of the third heat exchange part excluding the

2c

joint between the first heat exchange part and the third heat exchange part, and the outer face of

the heat exchanger overlaps a part of the blow-out port in plan view.

[0007]

An aspect of the present invention provides an indoor unit for an air conditioner,

the indoor unit including:

a casing;

a centrifugal fan disposed in the casing;

a heat exchanger disposed in the casing such that the centrifugal fan is surrounded by the

heat exchanger on three sides;

a partition connected to two ends of the heat exchanger to surround the centrifugal fan in

conjunction with the heat exchanger; and

a blow-out port through which air is blown out downward, the blow-out port being

formed in the casing at a position opposite to the partition with respect to the heat exchanger,

wherein

an air flow path from the heat exchanger to the blow-out port in the casing at least

partially has, at its downstream side, a sectional shape including a first air flow path region

extending along an edge of the casing and second air flow path regions respectively elongated

from two ends of the first air flow path region toward the partition.

[0008]

According to the configuration described above, the heat exchanger is disposed

in the casing such that the centrifugal fan is surrounded by the heat exchanger on three

sides. In addition, the air flow path from the heat exchanger to the blow-out port at

least partially has, at its downstream side, the sectional shape including the first air flow

path region extending along the edge of the casing and the second air flow path regions

respectively elongated from the two ends of the first air flow path region toward the

partition. The indoor unit thus enables increase in sectional area of the air flow path

and reduction in pressure loss at the air flow path with a simple configuration, which

leads to improvement in performance.

[0009]

The indoor unit for an air conditioner according to an embodiment further

includes a drain pan disposed below the heat exchanger in the casing, and the air flow

path at least partially has, at its side downstream of an upper end of the drain pan, the

sectional shape including the first air flow path region and the second air flow path

regions.

[0010]

According to the embodiment described above, the air flow path at least

partially has, at its side downstream of the upper end of the drain pan, the sectional

shape including the first air flow path region and the second air flow path regions.

This configuration therefore enables effective reduction in pressure loss by virtue of

widening of a portion, where the sectional area is otherwise small, of the air flow path.

[0011]

In the indoor unit for an air conditioner according to an embodiment, the blow-out port includes: a first blow-out port part extending along an edge of the casing, and second blow-out port parts respectively elongated from two ends of the first blow-out port part toward the partition.

[0012]

According to the embodiment described above, the blow-out port includes the

first blow-out port part extending along the edge of the casing, and the second blow-out

port parts respectively elongated from the two ends of the first blow-out port part

toward the partition. This configuration therefore enables increase in sectional area of

the air flow path and reduction in pressure loss at and around the blow-out port, which

leads to further improvement in performance.

[0013]

In the indoor unit for an air conditioner according to an embodiment,

the heat exchanger includes:

a first heat exchange part opposite to the blow-out port,

a second heat exchange part elongated from a first end of the first heat

exchange part, and

a third heat exchange part elongated from a second end of the first heat

exchange part, a clearance between the second heat exchange part and an opposite

edge, or side, of the casing to the second heat exchange part is tapered from the first

heat exchange part toward a distal end, or tip, of the second heat exchange part, and

a clearance between the third heat exchange part and an opposite edge, or side,

of the casing to the third heat exchange part is tapered from the first heat exchange part

toward a distal end, or tip, of the third heat exchange part.

[0014]

According to the embodiment described above, the clearance between the

second heat exchange part elongated from one of the ends of the first heat exchange part

opposite to the blow-out port and the opposite edge, or side, of the casing to the second

heat exchange part is tapered from the first heat exchange part toward the distal end, or

tip, of the second heat exchange part. In addition, the clearance between the third heat

exchange part elongated from the other end of the first heat exchange part opposite to

the blow-out port and the opposite edge, or side, of the casing to the third heat exchange

part is tapered from the first heat exchange part toward the distal end, or tip, of the third

heat exchange part. An opening defined between the two ends of the heat exchanger

having aU shape is thus increased. In addition, a joint between the first heat exchange

part and the second heat exchange part and a joint between the first heat exchange part

and the third heat exchange part are located inward away from an inner face of the

casing. Spaces thus defined are utilized for the second blow-out port parts. This

configuration therefore enables increase in area of the blow-out port.

[0015]

In the indoor unit for an air conditioner according to an embodiment,

the heat exchanger includes:

a first heat exchange part opposite to the blow-out port,

a second heat exchange part elongated from a first end of the first heat

exchange part, and

a third heat exchange part elongated from a second end of the first heat

exchange part,

the second heat exchange part extends in parallel with an opposite edge, or

side, of the casing to the second heat exchange part, and

the third heat exchange part extends in parallel with an opposite edge, or side, of the casing to the third heat exchange part.

[0016]

According to the embodiment described above, the second and third heat

exchange parts respectively elongated from the two ends of the first heat exchange part

opposite to the blow-out port extend in parallel with the opposite sides of the casing to

the second and third heat exchange parts, respectively. The joint between the first heat

exchange part and the second heat exchange part and the joint between the first heat

exchange part and the third heat exchange part may be curved or bent so as to be located

inward away from the inner face of the casing. Spaces thus defined are utilized for the

second blow-out port parts. This configuration therefore enables increase in area of

the blow-out port.

[0017]

The indoor unit for an air conditioner according to an embodiment further

includes a flap configured to control a direction of air to be blown out through the blow

out port, the flap including

a flap main body extending along an edge of the casing, and

auxiliary flaps respectively elongated from two ends of the flap main body in a

direction away from the edge of the casing.

[0018]

According to the embodiment described above, the flap main body 20a

extending along the edge of the casing controls a direction of air to be blown out

through the first blow-out port part 10a. In addition, the auxiliary flaps 20b

respectively elongated from the two ends of the flap main body 20a in the direction

away from the edge of the casing respectively control directions of air to be blown out

through the second blow-out port parts 1Gb.

[0019]

In the indoor unit for an air conditioner according to an embodiment,

a distance between the second blow-out port parts of the blow-out port

gradually increases from the first blow-out port part toward distal ends of the second

blow-out port parts.

[0020]

According to the embodiment described above, the blow-out port has such a

shape that the distance between the second blow-out port parts gradually increases from

the first blow-out port part toward the distal ends of the second blow-out port parts. In

the casing, therefore, spaces defined by the curved portions or bent portions of the heat

exchanger having the U shape are effectively utilized for the second blow-out port parts.

[0021]

In the indoor unit for an air conditioner according to an embodiment,

a joint between the first heat exchange part and the second heat exchange part

is curved,

a joint between the first heat exchange part and the third heat exchange part is

curved,

a region defined by a first plane including a line that is in contact with the first

heat exchange part and in parallel with a longitudinal direction of the first blow-out port

part, a second plane that is in contact with an outer face of the second heat exchange

part excluding the joint between the first heat exchange part and the second heat

exchange part, and an outer face of the heat exchanger overlaps a part of the blow-out

port in plan view, and

a region defined by the first plane including the line that is in contact with the

first heat exchange part and in parallel with the longitudinal direction of the first blow- out port part, a third plane that is in contact with an outer face of the third heat exchange part excluding the joint between the first heat exchange part and the third heat exchange part, and the outer face of the heat exchanger overlaps a part of the blow-out port in plan view.

[0022]

According to the embodiment described above, the region defined by the first

plane including the line that is in contact with the first heat exchange part and in parallel

with the longitudinal direction of the first blow-out port part , the second plane that is in

contact with the outer face of the second heat exchange part excluding the joint between

the first heat exchange part and the second heat exchange part, and the outer face of the

heat exchanger overlaps a part of the blow-out port in plan view. In addition, the

region defined by the first plane including the line that is in contact with the first heat

exchange part and in parallel with the longitudinal direction of the first blow-out port

part, the third plane that is in contact with the outer face of the third heat exchange part

excluding the joint between the first heat exchange part and the third heat exchange

part, and the outer face of the heat exchanger overlaps a part of the blow-out port in plan

view. This configuration ensures open spaces to be utilized for the blow-out port at a

position outside the joint between the first heat exchange part and the second heat

exchange part and at a position outside the joint between the first heat exchange part

and the third heat exchange part.

[0023]

In the indoor unit for an air conditioner according to an embodiment,

the second and third heat exchange parts at least partially overlap the second

blow-out port parts of the blow-out port, respectively, as seen sideways from a direction

opposite to the blow-out port with respect to the centrifugal fan.

[0024]

According to the embodiment described above, the second and third heat

exchange parts at least partially overlap the second blow-out port parts of the blow-out

port, respectively, as seen sideways from the direction opposite to the blow-out port

with respect to the centrifugal fan. Spaces in the casing are thus effectively utilized.

[0025]

In the indoor unit for an air conditioner according to an embodiment,

the heat exchanger partially overlaps the second blow-out port parts of the

blow-out port as seen sideways from a direction in which the first blow-out port part of

the blow-out port extends.

[0026]

According to the embodiment described above, the heat exchanger partially

overlaps the second blow-out port parts of the blow-out port as seen sideways from the

direction in which the first blow-out port part of the blow-out port extends. Spaces in

the casing are thus effectively utilized.

[0027]

In the indoor unit for an air conditioner according to an embodiment,

a width of the blow-out port is wider than a width of the heat exchanger as seen

sideways from a direction opposite to the blow-out port with respect to the centrifugal

fan.

[0028]

According to the embodiment described above, the width of the blow-out port

is wider than the width of the heat exchanger as seen sideways from the direction

opposite to the blow-out port with respect to the centrifugal fan. The area of the blow

out port is thus further increased.

[0029]

As is clear from the foregoing description, according to the present invention, a blow

out port includes: a first blow-out port part extending along an edge of a casing, the first blow

out port part being located opposite a partition with respect to a heat exchanger disposed in the

casing such that a centrifugal fan is surrounded by the heat exchanger on three sides; and second

blow-out port parts elongated from two ends of the first blow-out port part toward the partition.

An area of the blow-out port is thus increased with a simple configuration, which leads to

improvement in performance.

BRIEF DESCRIPTION OF DRAWINGS

[0030]

FIG. 1 is a perspective view of an indoor unit for an air conditioner according to a first

embodiment of the present invention, the indoor unit being seen obliquely from below.

FIG. 2 is a perspective view of the indoor unit seen obliquely from above.

FIG. 3 is a bottom view of the indoor unit.

FIG. 4 is a sectional view taken along line IV-IV in FIG. 3.

FIG. 5 is a bottom view of the indoor unit from which a panel, a drain pan, and the like

are detached.

FIG. 6 illustrates a center of a turbo fan in the indoor unit.

FIG. 7 illustrates the center of the turbo fan in the indoor unit.

FIG. 8 is a bottom view of the indoor unit from which the panel is detached.

FIG. 9 is a bottom view of the indoor unit which is illustrated in FIG. 5 and to which a

flap is attached.

FIG. 10 is a bottom view of the indoor unit from which the flap is detached.

FIG. 11 illustrates a relationship between regions outside curved portions of a

heat exchanger and a blow-out port in the indoor unit.

FIG. 12 illustrates a relationship between the heat exchanger and the blow-out

port in the indoor unit seen sideways (X direction).

FIG. 13 illustrates a relationship between the heat exchanger and the blow-out

port in the indoor unit seen sideways (Y direction).

FIG. 14 illustrates a width of the heat exchanger and a width of the blow-out

port in the indoor unit seen sideways (X direction).

FIG. 15 is a bottom view of an indoor unit for an air conditioner according to a

second embodiment of the present invention in a state in which a panel, a drain pan, and

the like are detached from the indoor unit.

DESCRIPTION OF EMBODIMENTS

[0031]

A specific description will be given of indoor units for an air conditioner

according to the present invention, based on embodiments illustrated in the drawings.

[0032]

[First Embodiment]

FIG. 1 is a perspective view of an indoor unit for an air conditioner according

to a first embodiment of the present invention, the indoor unit being seen obliquely from

below. This indoor unit is designed to be embedded in a ceiling.

[0033]

As illustrated in FIG. 1, the indoor unit for an air conditioner according to the

first embodiment includes a casing main body 1, a panel 2 having a rectangular shape,

the panel 2 being mounted to a lower side of the casing main body 1, and a grille 3

detachably mounted to the panel 2. The casing main body 1, the panel 2, and the grille

3 constitute a casing.

[0034]

The panel 2 has, in its longitudinal end and its lower face, a blow-out port 10

which extends along a shorter edge of the panel 2 and through which air is blown out

downward. The panel 2 also has a flap 20 pivotably mounted thereto. In FIG. 1, the

flap 20 closes the blow-out port 10.

[0035]

The indoor unit also includes a drain socket 7 protruding from a sidewall of the

casing main body 1. The drain socket 7 is connected to an external drain hose (not

illustrated). The indoor unit also includes pipe connection parts 5 and 6 each

protruding from a second wall 12 (see FIG. 5) of the casing main body 1. Each of the

pipe connection parts 5 and 6 is connected to an external refrigerant pipe (not

illustrated).

[0036]

As illustrated in FIG. 1, the indoor unit also includes an electrical component

unit 8 and hanger fittings 101 to 103 each protruding sideward from the casing main

body 1.

[0037]

FIG. 2 is a perspective view of the indoor unit seen obliquely from above. In

FIG. 2, the same constituent elements as those illustrated in FIG. 1 are denoted with the

same reference signs.

[0038]

FIG. 3 is a bottom view of the indoor unit. In FIG. 3, the same constituent

elements as those illustrated in FIG. 1 are denoted with the same reference signs.

[0039]

As illustrated in FIG. 3, the casing main body 1 has in its center a suction port

la. A filter 4 (see FIG. 4) is attached between the suction port la and the grille 3.

[0040]

FIG. 4 is a sectional view taken along line IV-IV in FIG. 3. In FIG. 4, the

same constituent elements as those illustrated in FIGS. 1 to 3 are denoted with the same

reference signs.

[0041]

As illustrated in FIG. 4, the casing main body 1 houses therein a turbo fan 30 to

be driven by a motor 31. The casing main body 1 also houses therein a bell mouth 32

at a position between the suction port la and the turbo fan 30. The casing main body 1

also houses therein a heat exchanger 40 and a partition plate 50 at a position around the

turbo fan 30. The casing main body 1 also houses therein a drain pan 60 at a position

below the heat exchanger 40 and the partition plate 50. The casing main body 1 also

houses therein a heat insulator 61 with which side faces and a bottom face of the drain

pan 60 are covered. The heat insulator 61 has a portion 61a fronting on an air flow

path P and protruding toward the air flow path P1 (see FIG. 8).

[0042]

The turbo fan 30 is an example of a centrifugal fan. The partition plate 50 is

an example of a partition. The partition may be integrated with the casing.

[0043]

The casing main body 1 has the air flow path P for guiding air from the turbo

fan 30 to the blow-out port 10 in the panel 2.

[0044]

FIG. 5 is a bottom view of the indoor unit from which the panel 2, the drain

pan 60, and the like are detached.

[0045]

As illustrated in FIG. 5, the casing main body 1 includes a first wall 11 located

near the blow-out port 10 (see FIG. 10), a second wall 12 opposite to the first wall 11, a

third wall 13 connecting the first wall 11 and the second wall 12, and a fourth wall 14

connecting the first wall 11 and the second wall 12 and opposite to the third wall 13.

In FIG. 5, reference numeral I0a denotes a first blow-out port part and 1Ob denotes

second blow-out port parts 1Ob.

[0046]

The heat exchanger 40 includes a first heat exchange part 41, a second heat

exchange part 42 located at an upstream side of the first heat exchange part 41 with

respect to a rotation direction (arrow R1) of the turbo fan 30 in plan view, and a third

heat exchange part 43 located at a downstream side of the first heat exchange part 41

with respect to the rotation direction (arrow RI) of the turbo fan 30 in plan view.

[0047]

The heat exchanger 40 has two ends connected to the partition plate 50 having

an arcuate shape, so that the turbo fan 30 is surrounded with the heat exchanger 40 and

the partition plate 50. The partition plate 50 is bowed outward.

[0048]

The pipe connection parts 5 and 6 are connected to an end of the third heat

exchange part 43 of the heat exchanger 40. The casing main body 1 also houses

therein a drain pump 70 at a position between the partition plate 50 and the second wall

12 and near the third wall 13.

[0049]

The third heat exchange part 43 elongated from the first heat exchange part 41

of the heat exchanger 40 at the downstream side in the rotation direction (arrow RI) of the turbo fan 30 is shorter in length than the second heat exchange part 42 elongated from the first heat exchange part 41 at the upstream side in the rotation direction (arrow

RI) of the turbo fan 30. Therefore, the pipe connection parts 5 and 6 are connected to

the end of the third heat exchange part 43. In other words, a space for connecting

pipes is ensured in the casing main body 1. As compared with a case where the third

heat exchange part 43 is equal in length to the second heat exchange part 42, a clearance

between an outer periphery of the turbo fan 30 and a downstream-side end of the

partition plate 50 is made larger than a clearance between the outer periphery of the

turbo fan 30 and an upstream-side end of the partition plate 50.

[0050]

In addition, the panel 2 has the blow-out port 10 at the position opposite to the

partition plate 50 with respect to the heat exchanger 40. Therefore, air from the turbo

fan 30 is smoothly blown out through the blow-out port 10 via the heat exchanger 40.

[0051]

FIG. 6 illustrates a center 01 of the turbo fan 30 in the indoor unit. The

center 01 of the turbo fan 30 is located upstream of a current of air (indicated by an

arrow R2) between the turbo fan 30 and the partition plate 50, with respect to a

perpendicular bisector L2 of a line LI connecting the two ends of the partition plate 50.

In other words, the center 01 of the turbo fan 30 is located on the left side of the

perpendicular bisector L2 in FIG. 6.

[0052]

With this configuration, the clearance between the outer periphery of the turbo

fan 30 and the downstream-side end of the partition plate 50 with which an opening of

the heat exchanger 40 is covered is larger than the clearance between the outer

periphery of the turbo fan 30 and the upstream-side end of the partition plate 50. This configuration therefore enables reduction in pressure near the downstream-side end of the partition plate 50 that makes loud unusual noise. This configuration thus enables reduction in pressure at a high-pressure spot that may occur at the end of the partition plate 50 with which the opening of the heat exchanger 40 is covered, to thereby reduce unusual noise.

[0053]

The inventors of the present invention performed a simulation on the condition

that the center 01 of the turbo fan 30 is located upstream of the current of air (R2)

between the turbo fan 30 and the partition plate 50, with respect to the perpendicular

bisector L2 of the line LI connecting the two ends of the partition plate 50. It was

confirmed by this simulation that the indoor unit having the configuration described

above reduces a pressure near the downstream-side end of the partition plate 50, and

therefore reduces a pressure at a high-pressure spot that occurs at the end of the partition

plate 50 with which the opening of the heat exchanger 40 is covered, to thereby reduce

unusual noise.

[0054]

As illustrated in FIG. 6, the partition plate 50 is bowed outward beyond the line

Li connecting the two ends of the partition plate 50 (partition) in plan view. In

addition, the turbo fan 30 partially overlaps the region surrounded with the partition

plate 50 and the line LI connecting the two ends of the partition plate 50 (partition).

Therefore, the turbo fan 30 rotates along the partition plate 50 bowed outward, and the

partition plate 50 smoothly guides air from the turbo fan 30, which contributes to

reduction in space for housing the components in the casing main body 1.

[0055]

The position of the center 01 of the turbo fan 30 is set as illustrated in FIG. 7.

The heat exchanger 40 includes a heat exchange part 40a (a hatched region in FIG. 7)

having a line symmetrical shape in plan view. The turbo fan 30 is disposed such that

the center 01 of the turbo fan 30 is located upstream of the current of air (indicated by

the arrow R2) between the turbo fan 30 and the partition plate 50, with respect to a

symmetry axis L3 of the heat exchange part 40a having the line symmetrical shape. In

other words, the turbo fan 30 is disposed such that the center 01 of the turbo fan 30 is

located on the left side of the symmetry axis L3 in FIG. 7.

[0056]

As to a positional relationship between the heat exchanger 40 and the casing

main body 1, desirably, the heat exchanger 40 is disposed in the casing main body 1

such that the symmetry axis L3 of the heat exchange part 40a having the line

symmetrical shape in the heat exchanger 40 is aligned with a longitudinal center line of

the casing main body 1.

[0057]

FIG. 8 is a bottom view of the indoor unit from which the panel 2 is detached.

In FIG. 8, the same constituent elements as those illustrated in FIGS. 1 to 5 are denoted

with the same reference signs. The heat insulator 61 is disposed to cover the side face

and bottom face of the drain pan 60 (see FIG. 4). In addition, the portion 61a of the

heat insulator 61 protrudes toward the air flow path P1.

[0058]

As illustrated in FIG. 8, the air flow path P from the heat exchanger 40 to the

blow-out port 10 in the casing main body 1 has, at its side downstream of an upper end

of the drain pan 60, a sectional shape (indicated by a hatched region A in FIG. 8)

including a first air flow path region Aa extending along an edge of the casing main

body 1 and second air flow path regions Ab respectively elongated from two ends of the first air flow path region Aa toward the second wall 12. The sectional shape of the air flow path P including the first air flow path region Aa and second air flow path regions

Ab is a shape of a horizontal section taken along a plane perpendicular to an axis of

rotation of the turbo fan 30.

[0059]

FIG. 9 is a bottom view of the indoor unit which is illustrated in FIG. 5 and to

which the flap 20 (diagonally shaded) is attached. FIG. 10 is a bottom view of the

indoor unit from which the flap 20 is detached. InFIGS. 9 and 10,thesame

constituent elements as those illustrated in FIGS. 1 to 7 are denoted with the same

reference signs.

[0060]

As illustrated in FIGS. 9 and 10, the heat exchanger 40 having a U shape in

plan view includes the first heat exchange part 41 extending in parallel with the first

wall 11 of the casing main body 1, the second heat exchange part 42 elongated from a

first end of the first heat exchange part 41, and the third heat exchange part 43 elongated

from a second end of the first heat exchange part 41.

[0061]

A clearance between the second heat exchange part 42 and the third wall 13 is

tapered from the first heat exchange part 41 toward a distal end, or tip, of the second

heat exchange part 42. A clearance between the third heat exchange part 43 and the

fourth wall 14 is tapered from the first heat exchange part 41 toward a distal end, or tip,

of the third heat exchange part 43. In other words, a distance between the second heat

exchange part 42 and the third heat exchange part 43 gradually increases toward the two

ends of the heat exchanger 40.

[0062]

As illustrated in FIG. 9, the flap 20 configured to control a direction of air to be

blown out through the blow-out port 10 includes a flap main body 20a extending along

the first wall 11 of the casing main body 1, and auxiliary flaps 20b respectively

elongated from two ends of the flap main body 20a toward the second wall 12 of the

casing main body 1.

[0063]

As illustrated in FIG. 10, the blow-out port 10 includes a first blow-out port

part 1a having a rectangular shape and extending along the first wall 11 (shown in FIG.

9) of the casing main body 1, and second blow-out port parts1b respectively elongated

from two ends of the first blow-out port part 10a toward the second wall 12 (shown in

FIG. 9) of the casing main body 1. The blow-out port 10 is indicated by a hatched

region in FIG. 10, and is a region where the air flow path P is seen from a direction

perpendicular to the panel 2.

[0064]

The flap main body 20a extending along the edge of the casing main body 1

controls a direction of air to be blown out through the first blow-out port part 10a. In

addition, the auxiliary flaps 20b respectively elongated from the two ends of the flap

main body 20a in a direction away from the edge of the casing main body 1 respectively

control directions of air to be blown out through the second blow-out port parts1Gb.

[0065]

FIG. 11 illustrates a relationship between regions Si and S2 outside the curved

portions of the heat exchanger 40 and the blow-out port 10 in the indoor unit.

[0066]

As illustrated in FIG. 11, the region Si is defined by a first plane including a

contacting line F1 that is in contact with the first heat exchange part 41 and in parallel with the longitudinal direction of the first blow-out port part I1a, a second plane including a contacting line F2 that is in contact with an outer face of the second heat exchange part 42 excluding a joint between the first heat exchange part 41 and the second heat exchange part 42, and an outer face of the heat exchanger 40. The region

Si overlaps a part of one of the second blow-out port parts 10b of the blow-out port 10

in plan view. In addition, the region S2 is defined by the first plane including the

contacting line F1 that is in contact with the first heat exchange part 41 and in parallel

with the longitudinal direction of the first blow-out port part I1a, a third plane including

a contacting line F3 that is in contact with an outer face of the third heat exchange part

43 excluding a joint between the first heat exchange part 41 and the third heat exchange

part 43, and the outer face of the heat exchanger 40. The region S2 overlaps a part of

the other second blow-out port part 1Ob of the blow-out port 10 in plan view.

[0067]

This configuration ensures an open space to be utilized for one of the second

blow-out port parts 1b at a position outside the joint between the first heat exchange

part 41 and the second heat exchange part 42, and also ensures an open space to be

utilized for the other second blow-out port part 1Gb at a position outside the joint

between the first heat exchange part 41 and the third heat exchange part 43.

[0068]

The blow-out port has such a shape that the distance between the second blow

out port parts 1Gb gradually increases from the first blow-out port part 1Ga toward the

distal ends of the second blow-out port parts 10b. In the casing main body 1,

therefore, the spaces defined by the curved portions of the heat exchanger 40 having the

U shape are effectively utilized for the second blow-out port parts 1Gb.

[0069]

The first embodiment employs the first plane including the contacting line F1

that is in parallel with the longitudinal direction of the first blow-out port part 1Ga and

in contact with the first heat exchange part 41 of the heat exchanger 40 having the U

shape. When the first blow-out port part is not formed in a rectangular shape, but is

curved, a direction of a line that is in contact with a center of the first blow-out port part

is defined as the longitudinal direction of the first blow-out port part.

[0070]

FIG. 12 illustrates a relationship between the heat exchanger 40 and the blow

out port 10 in the indoor unit seen sideways (X direction). In FIG. 12, the same

constituent elements as those illustrated in FIG. 5 are denoted with the same reference

signs. An X direction is a direction in which the indoor unit is seen sideways from the

second wall 12, and a Y direction is a direction in which the indoor unit is seen

sideways from the third wall 13.

[0071]

As illustrated in FIG. 12, the regions S3 and S4 of the second and third heat

exchange parts 42 and 43 respectively overlap the second blow-out port parts 1Gb of the

blow-out port 10 as seen sideways from the direction opposite to the blow-out port 10

with respect to the turbo fan 30 (i.e., the X direction). The spaces in the casing main

body 1 are thus effectively utilized. The second and third heat exchange parts 42 and

43 may entirely overlap the second blow-out port parts 1Gb of the blow-out port 10.

[0072]

FIG. 13 illustrates a relationship between the heat exchanger 40 and the blow

out port 10 in the indoor unit seen sideways (Y direction). In FIG. 13, the same

constituent elements as those illustrated in FIG. 5 are denoted with the same reference

signs. An X direction is a direction in which the indoor unit is seen sideways from the second wall 12, and a Y direction is a direction in which the indoor unit is seen sideways from the third wall 13.

[0073]

As illustrated in FIG. 13, the region S5 of the heat exchanger 40 overlaps the

second blow-out port parts 10b of the blow-out port 10 as seen sideways from the

direction in which the first blow-out port part Ia of the blow-out port 10 extends (i.e.,

the Y direction). The spaces in the casing main body 1 are thus effectively utilized.

[0074]

FIG. 14 illustrates a width W2 of the heat exchanger 40 and a width W1 of the

blow-out port 10 in the indoor unit seen sideways (X direction). In FIG. 14, the same

constituent elements as those illustrated in FIG. 5 are denoted with the same reference

signs. An X direction is a direction in which the indoor unit is seen sideways from the

second wall 12, and a Y direction is a direction in which the indoor unit is seen

sideways from the third wall 13.

[0075]

As illustrated in FIG. 14, the width W Iof the blow-out port 10 is wider than

the width W2 of the heat exchanger 40 as seen sideways from the direction opposite to

the blow-out port 10 with respect to the turbo fan 30 (i.e., the X direction). Theareaof

the blow-out port is thus further increased.

[0076]

According to the indoor unit having the configuration described above, the heat

exchanger 40 is disposed in the casing main body 1 such that the turbo fan 30

(centrifugal fan) is surrounded by the heat exchanger 40 on three sides. In addition,

the air flow path P from the heat exchanger 40 to the blow-out port 10 has, at its

downstream side, the sectional shape including the first air flow path region Aa extending along an edge of the casing main body 1 and the second air flow path regions

Ab respectively elongated from the two ends of the first air flow path region Aa toward

the partition 50. The indoor unit thus enables increase in sectional area of the air flow

path P and reduction in pressure loss at the air flow path P with a simple configuration,

which leads to improvement in performance.

[0077]

The air flow path P has, at its side downstream of the upper end of the drain

pan 60, the sectional shape including the first air flow path region Aa and the second air

flow path regions Ab. This configuration therefore enables effective reduction in

pressure loss by virtue of widening of a portion, where the sectional area is small, of the

air flow path P.

[0078]

In the first embodiment, the air flow path P has, at its side downstream of the

upper end of the drain pan 60, the U-shaped section including the first air flow path

region Aa and the second air flow path regions Ab. Alternatively, the section of at

least a part of the downstream side of the air flow path from the heat exchanger to the

blow-out port in the casing may have the U shape including the first air flow path region

extending along the edge of the casing and the second air flow path regions respectively

elongated from the two ends of the first air flow path region toward the partition.

[0079]

The blow-out port 10 includes the first blow-out port part1Ga extending along

the edge of the casing main body 1, and the second blow-out port parts Ob respectively

elongated from the two ends of the first blow-out port part I1a toward the partition plate

50. This configuration therefore enables increase in area of the blow-out port 10 and

reduction in pressure loss at and around the blow-out port, which leads to further improvement in performance.

[0080]

The clearance between the second heat exchange part 42 elongated from one of

the ends of the first heat exchange part 41 opposite to the blow-out port 10 and the

opposite edge, or side, of the casing main body 1 to the second heat exchange part 42 is

tapered from the first heat exchange part 41 toward the distal end of the second heat

exchange part 42. In addition, the clearance between the third heat exchange part 43

elongated from the other end of the first heat exchange part 41 opposite to the blow-out

port 10 and the opposite edge, or side, of the casing main body I to the third heat

exchange part 43 is tapered from the first heat exchange part 41 toward the distal end of

the third heat exchange part 43. The opening defined between the two ends of the heat

exchanger 40 having the U shape is thus increased. In addition, the joint between the

first heat exchange part 41 and the second heat exchange part 42 and the joint between

the first heat exchange part 41 and the third heat exchange part 43 are located inward

away from an inner face of the casing main body 1. Spaces thus defined are utilized

for the second blow-out port parts lOb. This configuration therefore enables increase

in area of the blow-out port 10.

[0081]

In the first embodiment, the turbo fan 30 is a centrifugal fan. Alternatively,

the turbo fan 30 may by any centrifugal fan such as a sirocco fan.

[0082]

[Second Embodiment]

FIG. 15 is a bottom view of an indoor unit for an air conditioner according to a

second embodiment of the present invention in a state in which a panel, a drain pan, and

the like are detached from the indoor unit. The indoor unit for an air conditioner according to the second embodiment is identical in configuration to the indoor unit for an air conditioner according to the first embodiment except for a heat exchanger 140 having a U shape, and is therefore described with also reference to FIGS. 1 to 3.

[0083]

As illustrated in FIG. 15, the indoor unit for an air conditioner according to the

second embodiment includes a heat exchanger 140 having a U shape in plan view. The

heat exchanger 140 includes a first heat exchange part 141 extending in parallel with a

first wall 11 of a casing main body 1, a second heat exchange part 142 elongated from a

first end of the first heat exchange part 141, and a third heat exchange part 143

elongated from a second end of the first heat exchange part 141. Thesecondheat

exchange part 142 extends in parallel with a second wall 12. The third heat exchange

part 143 extends in parallel with a third wall 13.

[0084]

According to the indoor unit having the configuration described above, the

second and third heat exchange parts 142 and 143 respectively elongated from the two

ends of the first heat exchange part 141 opposite to a blow-out port 10 extend in parallel

with the opposite edges, or sides, of the casing main body 1 to the second and third heat

exchange parts 142 and 143, respectively. Ajoint between the first heat exchange part

141 and the second heat exchange part 142 and a joint between the first heat exchange

part 141 and the third heat exchange part 143 are curved so as to be located inward

away from an inner face of the casing main body 1. Spaces thus defined are utilized

for second blow-out port parts lOb. This configuration therefore enables increase in

area of the blow-out port 10. An area of the blow-out port 10 increases as a curvature

of each of the joint between the first heat exchange part 141 and the second heat

exchange part 142 and the joint between the first heat exchange part 141 and the third heat exchange part 143 increases.

[0085]

The indoor unit for an air conditioner according to the second embodiment

produces effects similar to those of the indoor unit for an air conditioner according to

the first embodiment.

[0086]

Preferably, the second heat exchange part 142 and the third heat exchange part

143, which are respectively elongated from the two ends of the first heat exchange part

141, extend in parallel with each other irrespective of the shape of the casing main body.

[0087]

[Third Embodiment]

An indoor unit for an air conditioner according to a third embodiment of the

present invention is identical in configuration to the indoor unit for an air conditioner

according to the first embodiment except for a heat exchanger, and is therefore

described with also reference to FIGS. 1 to 5.

[0088]

In the first embodiment, the heat exchanger 40 of the indoor unit includes the

first heat exchange part 41, the second heat exchange part 42 seamlessly elongated from

the first end of the first heat exchange part 41, and the third heat exchange part 43

seamlessly elongated from the second end of the first heat exchange part 41. The

indoor unit for an air conditioner according the third embodiment includes a heat

exchanger 40 divided into different pieces of a first heat exchange part, a second heat

exchange part, and a third heat exchange part.

[0089]

The indoor unit for an air conditioner according to the third embodiment produces effects similar to those of the indoor unit for an air conditioner according to the first embodiment.

[0090]

In the first to third embodiments, the casing of the indoor unit is constituted of

the casing main body 1, the panel 2, and the grille 3; however, the shape of the casing is

not limited thereto.

[0091]

Also in the first to third embodiments, the heat exchanger 40 of the indoor unit

has the U shape; however, the shape of the heat exchanger is not limited thereto.

Examples of the shape of the heat exchanger may include a circular arc shape, a V

shape, and the like.

[0092]

Also in the first to third embodiments, the indoor unit is designed to be

embedded in a ceiling; however, the indoor unit is not limited thereto. Alternatively,

the present invention is also applicable to, for example, an indoor unit designed to be

suspended from a ceiling.

[0093]

The foregoing description concerns specific embodiments of the present

invention; however, the present invention is not limited to the first to third

embodiments, and various modifications and variations may be made within the scope

of the present invention. For example, an appropriate combination of the

configurations described in the first to third embodiments may be regarded as an

embodiment of the present invention.

REFERENCE SIGNS LIST

[0094]

1 casing main body

1a suction port

2 panel

3 grille

4 filter

,6 pipe connection part

7 drain socket

8 electrical component unit

blow-out port

11 first wall

12 second wall

13 third wall

14 fourth wall

flap

a flap main body

b auxiliary flap

turbo fan (centrifugal fan)

31 motor

32 bell mouth

, 140 heat exchanger

41, 141 first heat exchange part

42, 142 second heat exchange part

43, 143 third heat exchange part

partition plate (partition)

drain pan

61 heat insulator

drain pump

P air flow path

Claims (8)

CLAIMS:

1. An indoor unit for an air conditioner, comprising:

a casing;

a centrifugal fan disposed in the casing;

a heat exchanger disposed in the casing such that the centrifugal fan is surrounded by the

heat exchanger on three sides, the heat exchanger having a first heat exchange part opposite to a

blow-out port, a second heat exchange part elongated from a first end of the first heat exchange

part, and a third heat exchange part elongated from a second end of the first heat exchange part,

with sections connecting the first heat exchange part with each of the second and third heat

exchange parts being curved;

a partition connected to two ends of the heat exchanger to surround the centrifugal fan in

conjunction with the heat exchanger; and

the blow-out port through which air is blown out downward, the blow-out port being

formed in the casing at a position opposite to the partition with respect to the heat exchanger,

wherein

an air flow path from the heat exchanger to the blow-out port in the casing at least

partially has, at its downstream side, a sectional shape including a first air flow path region

extending along an edge of the casing and second air flow path regions respectively elongated

from two ends of the first air flow path region toward the partition, and

the blow-out port includes:

a first blow-out port part extending along an edge of the casing, and

second blow-out port parts respectively elongated from two ends of the first blow-out

port part toward the partition,

a clearance between the second heat exchange part and an opposite edge, or side, of the casing

to the second heat exchange part and a clearance between the third heat exchange part and an

opposite edge, or side, of the casing to the third heat exchange part are tapered from the first heat exchange part toward a distal end of the second heat exchange part and a distal end of the third heat exchange part, respectively, a region defined by a first plane including a line that is in contact with the first heat exchange part and in parallel with a longitudinal direction of the first blow-out port part, a second plane that is in contact with an outer face of the second heat exchange part excluding the joint between the first heat exchange part and the second heat exchange part, and an outer face of the heat exchanger overlaps a part of the blow-out port in plan view, and a region defined by the first plane including the line that is in contact with the first heat exchange part and in parallel with the longitudinal direction of the first blow-out port part, a third plane that is in contact with an outer face of the third heat exchange part excluding the joint between the first heat exchange part and the third heat exchange part, and the outer face of the heat exchanger overlaps a part of the blow-out port in plan view.

2. An indoor unit for an air conditioner, comprising:

a casing;

a centrifugal fan disposed in the casing;

a heat exchanger disposed in the casing such that the centrifugal fan is surrounded by the

heat exchanger on three sides, the heat exchanger having a first heat exchange part opposite to a

blow-out port, a second heat exchange part elongated from a first end of the first heat exchange

part, and a third heat exchange part elongated from a second end of thefirst heat exchange part,

with sections connecting the first heat exchange part with each of the second and third heat

exchange parts being curved;

a partition connected to two ends of the heat exchanger to surround the centrifugal fan in

conjunction with the heat exchanger; and

the blow-out port through which air is blown out downward, the blow-out port being

formed in the casing at a position opposite to the partition with respect to the heat exchanger, wherein an air flow path from the heat exchanger to the blow-out port in the casing at least partially has, at its downstream side, a sectional shape including a first air flow path region extending along an edge of the casing and second air flow path regions respectively elongated from two ends of the first air flow path region toward the partition, and the blow-out port includes: a first blow-out port part extending along an edge of the casing, and second blow-out port parts respectively elongated from two ends of the first blow-out port part toward the partition, wherein the second heat exchange part and the third heat exchange part extend in parallel with the opposite edges, or sides, of the casing to the second heat exchange part and the third heat exchange part, respectively, a region defined by a first plane including a line that is in contact with the first heat exchange part and in parallel with a longitudinal direction of the first blow-out port part, a second plane that is in contact with an outer face of the second heat exchange part excluding the joint between the first heat exchange part and the second heat exchange part, and an outer face of the heat exchanger overlaps a part of the blow-out port in plan view, and a region defined by the first plane including the line that is in contact with the first heat exchange part and in parallel with the longitudinal direction of the first blow-out port part, a third plane that is in contact with an outer face of the third heat exchange part excluding the joint between the first heat exchange part and the third heat exchange part, and the outer face of the heat exchanger overlaps a part of the blow-out port in plan view.

3. The indoor unit for an air conditioner according to claim 1 or claim 2, further

comprising:

a drain pan disposed below the heat exchanger in the casing, wherein the air flow path at least partially has, at its side downstream of an upper end of the drain pan, the sectional shape including the first air flow path region and the second air flow path regions.

4. The indoor unit for an air conditioner according to any one of claims I to 3, further

comprising:

a flap configured to control a direction of air to be blown out through the blow-out port,

the flap including

a flap main body extending along an edge of the casing, and

auxiliary flaps respectively elongated from two ends of the flap main body in a direction

away from the edge of the casing.

5. The indoor unit for an air conditioner according to claim 1 or claim 2, wherein

a distance between the second blow-out port parts of the blow-out port gradually

increases from the first blow-out port part toward distal ends of the second blow-out port parts.

6. The indoor unit for an air conditioner according to claim 1 or claim 2, wherein

the second and third heat exchange parts at least partially overlap the second blow-out

port parts of the blow-out port, respectively, as seen sideways from a direction opposite to the

blow-out port with respect to the centrifugal fan.

7. The indoor unit for an air conditioner according to any one of claims 1 to 6, wherein

the heat exchanger partially overlaps the second blow-out port parts of the blow-out port

as seen sideways from a direction in which the first blow-out port part of the blow-out port

extends.

8. The indoor unit for an air conditioner according to any one of claims I to 7, wherein

a width of the blow-out port is wider than a width of the heat exchanger as seen

sideways from a direction opposite to the blow-out port with respect to the centrifugal fan.

Daikin Industries, Ltd.

Patent Attorneys for the Applicant

SPRUSON & FERGUSON