TECHNICAL FIELD
[0001] The present disclosure relates to an evaporator of a refrigeration cycle apparatus
in which a non-azeotropic refrigerant mixture is enclosed.
BACKGROUND ART
[0002] As an evaporator of a refrigeration cycle apparatus, there is an evaporator in a
form in which a plurality of heat transfer tubes are unevenly distributed more on
either one of the windward side and the leeward side of the center of a heat transfer
fin. For example, the evaporator described in PTL 1 (
WO2017/183180) is a stack-type heat exchanger in which elongated holes each having a longitudinal
diameter extending in the width direction of a fin are provided at a predetermined
interval in a direction orthogonal to the width direction and the thickness direction
of the fin and in which a flat pipe is inserted into each of the elongated holes.
SUMMARY OF INVENTION
TECHNICAL PROBLEM
[0003] In an evaporator such as that described above, disposing the center of the entirety
of a flat pipe group in the width direction on the air windward side of the center
of a fin in the width direction increases a difference between an air temperature
and a heat-exchanger surface temperature, which improves heat exchange performance
but easily causes frost. Conversely, disposing the center of the entirety of the flat
pipe group in the width direction on the leeward side of the center of the fin in
the width direction tends to improve frost proof performance (capacity of suppressing
frost) but degrades heat exchange performance.
[0004] In particular, since the composition of a non-azeotropic refrigerant mixture is different
between a liquid phase and a gas phase, the refrigerant temperature at an inlet is
lower than that at an outlet in an evaporator. Thus, when flat pipes are unevenly
distributed more on the windward side, frost is easily generated.
[0005] In PTL 1, a distance between the flat pipes and a windward-side edge of the fin is
considered from the point of view of drainage of condensed water and melted water
but is not considered from the point of view of frost proof performance (capacity
of suppressing frost) and/or heat exchange performance in a case where a refrigerant
that flows in the evaporator is specified as a non-azeotropic refrigerant mixture.
[0006] Therefore, there is a task of providing, as an evaporator of a refrigeration cycle
apparatus in which a non-azeotropic refrigerant mixture is enclosed, an evaporator
that improves frost proof performance and/or heat exchange performance.
SOLUTION TO PROBLEM
[0007] An evaporator according to a first aspect is an evaporator of a refrigeration cycle
apparatus in which a non-azeotropic refrigerant mixture is enclosed, the evaporator
including a plurality of fins and a plurality of heat transfer tubes. The plurality
of fins are arranged at a predetermined interval in a plate thickness direction. The
plurality of heat transfer tubes extend through the plurality of fins in the plate
thickness direction. In the evaporator, a first heat exchange section is formed. In
the first heat exchange section, when the plurality of heat transfer tubes are viewed
as a heat-transfer-tube group in the plate thickness direction of the fins, a distribution
center of the heat-transfer-tube group in an airflow direction is positioned on the
leeward side of the center of the fins in the airflow direction.
[0008] In this evaporator, since an enclosed refrigerant is a non-azeotropic refrigerant
mixture, a refrigerant temperature at an evaporator inlet is low compared with at
an outlet, which easily causes frost. However, for example, when the first heat exchange
section is provided on the refrigerant inlet side, the distribution center of the
heat-transfer-tube group is positioned on the leeward side of the center of the fins
in the airflow direction. Thus, frost is not easily generated compared with when the
distribution center of the heat-transfer-tube group is positioned on the windward
side of the center of the fins.
[0009] An evaporator according to a second aspect is the evaporator according to the first
aspect in which a second heat exchange section is further formed. In the second heat
exchange section, the distribution center of the heat-transfer-tube group is positioned
on the windward side of the center of the fins in the airflow direction.
[0010] In this evaporator, the temperature of the non-azeotropic refrigerant mixture increases
from the inlet toward the outlet of the evaporator. It is thus preferable on the outlet
side to put high priority on heat exchange performance rather than frost proof performance
and to position the distribution center of the heat-transfer-tube group on the windward
side of the center of the fins in the airflow direction.
[0011] Therefore, by forming, in addition to the first heat exchange section according to
the first aspect, the second heat exchange section in which the distribution center
of the heat-transfer-tube group is positioned on the windward side of the center of
the fins in the airflow direction, it is possible to, for example, dispose the first
heat exchange section on the evaporator inlet side and the second heat exchange section
on the evaporator outlet side. Thus, it is possible to try a combination of the heat
exchange sections suitable for a refrigerant temperature in the evaporator.
[0012] An evaporator according to a third aspect is the evaporator according to the second
aspect in which a third heat exchange section is further formed. In the third heat
exchange section, the distribution center of the heat-transfer-tube group substantially
coincides with the center of the fins in the airflow direction.
[0013] In this evaporator, for example, it is possible to dispose the first heat exchange
section on the evaporator inlet side, the second heat exchange section on the evaporator
outlet side, and the third heat exchange section between the first heat exchange section
and the second heat exchange section. Thus, it is possible to try a combination of
the heat exchange sections suitable for a refrigerant temperature in the evaporator.
[0014] An evaporator according to a fourth aspect is the evaporator according to the second
aspect in which the first heat exchange section and the second heat exchange section
are integral with each other.
[0015] An evaporator according to a fifth aspect is the evaporator according to the third
aspect in which the first heat exchange section is integral with at least either one
of the second heat exchange section and the third heat exchange section.
[0016] An evaporator according to a sixth aspect is an evaporator of a refrigeration cycle
apparatus in which a non-azeotropic refrigerant mixture is enclosed, the evaporator
including a plurality of fins and a plurality of heat transfer tubes. The plurality
of fins are arranged at a predetermined interval in a plate thickness direction. The
plurality of heat transfer tubes extend through the plurality of fins in the plate
thickness direction. In the evaporator, a first heat exchange section and a second
heat exchange section are formed. In the first heat exchange section, a distance from
a windward-side end of the heat transfer tube positioned on the most windward side
in an airflow direction to a windward-side end of the fins is a first dimension. In
the second heat exchange section, a distance from a windward-side end of the heat
transfer tube positioned on the most windward side in the airflow direction to a windward-side
end of the fins is a second dimension smaller than the first dimension.
[0017] In this evaporator, the temperature of the non-azeotropic refrigerant mixture increases
from the inlet toward the outlet of the evaporator. It is thus preferable to put a
high priority on frost proof performance on the inlet side and put a high priority
on heat exchange performance on the outlet side.
[0018] For example, it is possible to dispose the first heat exchange section on the evaporator
inlet side and the second heat exchange section on the evaporator outlet side. Thus,
it is possible to try a combination suitable for a refrigerant temperature in the
evaporator.
[0019] An evaporator according to a seventh aspect is the evaporator according to the sixth
aspect in which a third heat exchange section is further formed. In the third heat
exchange section, a distance from a windward-side end of the heat transfer tube positioned
on the most windward side in the airflow direction to a windward-side end of the fins
and a distance from a leeward-side end of the heat transfer tube positioned on the
most leeward side in the airflow direction to a leeward-side end of the fins are equal
to each other.
[0020] In this evaporator, for example, it is possible to dispose the first heat exchange
section on the evaporator inlet side, the second heat exchange section on the evaporator
outlet side, and the third heat exchange section between the first heat exchange section
and the second heat exchange section. Thus, it is possible to try a combination of
the heat exchange sections suitable for a refrigerant temperature in the evaporator.
[0021] An evaporator according to an eighth aspect is the evaporator according to the sixth
aspect in which the first heat exchange section and the second heat exchange section
are integral with each other.
[0022] An evaporator according to a ninth aspect is the evaporator according to the seventh
aspect in which the first heat exchange section is integral with at least either one
of the second heat exchange section and the third heat exchange section.
[0023] An evaporator according to a tenth aspect is an evaporator of a refrigeration cycle
apparatus in which a non-azeotropic refrigerant mixture is enclosed, the evaporator
including a plurality of fins and a plurality of heat transfer tubes. The plurality
of fins are arranged at a predetermined interval in a plate thickness direction. The
plurality of heat transfer tubes extend through the plurality of fins in the plate
thickness direction. The fins have a plurality of cutouts. The plurality of cutouts
are arranged in a direction orthogonal to both an airflow direction and the plate
thickness direction. The heat transfer tubes are flat multi-hole pipes inserted into
the cutouts. In the evaporator, a first heat exchange section is formed. In the first
heat exchange section, the opening side of the cutouts is positioned on the leeward
side in the airflow direction.
[0024] In this evaporator, if the opening side of a cutout is present on the windward side
of an airflow, a difference between an air temperature and an evaporator surface temperature
is large, which improves heat exchange performance but easily causes frost. Conversely,
if the opening side of the cutout is present on the leeward side, frost proof performance
is improved but heat exchange performance is degraded. In particular, since a non-azeotropic
refrigerant mixture is used as a refrigerant, the refrigerant temperature tends to
decrease on the inlet side of the evaporator due to a temperature gradient, and frost
is easily generated.
[0025] However, since the first heat exchange section in which the opening side of the cutout
is positioned on the leeward side in the airflow direction is formed, it is possible
to improve frost proof performance by providing the first heat exchange section at
least on the inlet side of the evaporator.
[0026] An evaporator according to an eleventh aspect is the evaporator according to the
tenth aspect in which a second heat exchange section is further formed. In the second
heat exchange section, the opening side of the cutouts is positioned on the windward
side in the airflow direction.
[0027] In this evaporator, for example, it is possible to dispose the first heat exchange
section on the evaporator inlet side and the second heat exchange section on the evaporator
outlet side. Thus, it is possible to try a combination suitable for a refrigerant
temperature in the evaporator.
[0028] An evaporator according to a twelfth aspect is the evaporator according to the eleventh
aspect in which the first heat exchange section and the second heat exchange section
are integral with each other.
[0029] A refrigeration cycle apparatus according to a thirteenth aspect is a refrigeration
cycle apparatus including the evaporator according to any one of the first to twelfth
aspects. The non-azeotropic refrigerant mixture includes any of a HFC refrigerant,
a HFO refrigerant, CF3I, and a natural refrigerant.
[0030] A refrigeration cycle apparatus according to a fourteenth aspect is a refrigeration
cycle apparatus including the evaporator according to any one of the first to twelfth
aspects. The non-azeotropic refrigerant mixture includes any of R32, R1132(E), R1234yf,
R1234ze, CF3I, and CO2.
[0031] A refrigeration cycle apparatus according to a fifteenth aspect is a refrigeration
cycle apparatus including the evaporator according to any one of the first to twelfth
aspects. The non-azeotropic refrigerant mixture includes at least R1132(E), R32, and
R1234yf.
[0032] A refrigeration cycle apparatus according to a sixteenth aspect is a refrigeration
cycle apparatus including the evaporator according to any one of the first to twelfth
aspects. The non-azeotropic refrigerant mixture includes at least R1132(E), R1123,
and R1234yf.
[0033] A refrigeration cycle apparatus according to a seventeenth aspect is a refrigeration
cycle apparatus including the evaporator according to any one of the first to twelfth
aspects. The non-azeotropic refrigerant mixture includes at least R1132(E) and R1234yf.
[0034] A refrigeration cycle apparatus according to an eighteenth aspect is a refrigeration
cycle apparatus including the evaporator according to any one of the first to twelfth
aspects. The non-azeotropic refrigerant mixture includes at least R32, R1234yf, and
at least one of R1132a and R1114.
[0035] A refrigeration cycle apparatus according to a nineteenth aspect is a refrigeration
cycle apparatus including the evaporator according to any one of the first to twelfth
aspects. The non-azeotropic refrigerant mixture includes at least R32, CO2, R125,
R134a, and R1234yf.
[0036] A refrigeration cycle apparatus according to a twentieth aspect is a refrigeration
cycle apparatus including the evaporator according to any one of the first to twelfth
aspects. The non-azeotropic refrigerant mixture includes at least R1132(Z) and R1234yf.
BRIEF DESCRIPTION OF DRAWINGS
[0037]
Fig. 1 is a schematic diagram of an air conditioning apparatus as a refrigeration
apparatus according to one embodiment of the present disclosure.
Fig. 2 is a schematic front view of an indoor heat exchanger.
Fig. 3 is an external perspective view of an outdoor heat exchanger.
Fig. 4 is a P-H diagram of a non-azeotropic refrigerant mixture.
Fig. 5A is a perspective view of a first heat exchange section of an outdoor heat
exchanger according to a first embodiment.
Fig. 5B is a perspective view of a second heat exchange section of the outdoor heat
exchanger according to the first embodiment.
Fig. 6A is a schematic perspective view of an outdoor heat exchanger that uses both
the first heat exchange section and the second heat exchange section.
Fig. 6B is a schematic perspective view of a different outdoor heat exchanger that
uses both the first heat exchange section and the second heat exchange section.
Fig. 7A is a perspective view of a first heat exchange section of an outdoor heat
exchanger according to a second embodiment.
Fig. 7B is a perspective view of a second heat exchange section of the outdoor heat
exchanger according to the second embodiment.
Fig. 7C is a perspective view of a third heat exchange section of an outdoor heat
exchanger according to a modification of the second embodiment.
Fig. 8A is a perspective view of a first heat exchange section of an outdoor heat
exchanger according to a third embodiment.
Fig. 8B is a perspective view of a second heat exchange section of the outdoor heat
exchanger according to the third embodiment.
Fig. 8C is a perspective view of a third heat exchange section of an outdoor heat
exchanger according to a modification of the third embodiment.
DESCRIPTION OF EMBODIMENTS
<First Embodiment
(1) Configuration of Air Conditioning Apparatus 1
[0038] Fig. 1 is a schematic diagram of an air conditioning apparatus 1 according to one
embodiment of the present disclosure. In Fig. 1, the air conditioning apparatus 1
is a refrigeration apparatus that performs cooling operation and heating operation
by a vapor compression refrigeration cycle.
[0039] A refrigerant circuit 10 of the air conditioning apparatus 1 is constituted by an
outdoor unit 2 and an indoor unit 4 that are connected to each other via a liquid-refrigerant
connection pipe 5 and a gas-refrigerant connection pipe 6.
[0040] A refrigerant enclosed in the refrigerant circuit 10 is a non-azeotropic refrigerant
mixture. The non-azeotropic refrigerant mixture includes any of a HFC refrigerant,
a HFO refrigerant, CF3I, and a natural refrigerant.
(1-1) Indoor Unit 4
[0041] The indoor unit 4 is installed indoors and constitutes part of the refrigerant circuit
10. The indoor unit 4 includes an indoor heat exchanger 41, an indoor fan 42, and
an indoor-side control unit 44.
(1-1-1) Indoor Heat Exchanger 41
[0042] The indoor heat exchanger 41 functions as an evaporator for the refrigerant during
cooling operation and cools indoor air. In addition, the indoor heat exchanger 41
functions as a radiator for the refrigerant during heating operation and heats indoor
air. The refrigerant inlet side of the indoor heat exchanger 41 during cooling operation
is connected to the liquid-refrigerant connection pipe 5, and the refrigerant outlet
side thereof is connected to the gas-refrigerant connection pipe 6.
[0043] Fig. 2 is a front view of the indoor heat exchanger 41. In Fig. 2, the indoor heat
exchanger 41 is a cross-fin-type heat exchanger. The indoor heat exchanger has a heat
transfer fin 412 and a heat transfer tube 411.
[0044] The heat transfer fin 412 is a thin aluminum flat plate. The heat transfer fin 412
has a plurality of through holes. The heat transfer tube 411 has a straight tube 411a
inserted into the through holes of the heat transfer fin 412, and U-shaped tubes 411b
and 411c that couple end portions of mutually adjacent straight tubes 411a to each
other.
[0045] The straight tube 411a is in close contact with the heat transfer fin 412 by being
subjected to tube expansion processing after inserted into the through holes of the
heat transfer fin 412. The straight tube 411a and the first U-shaped tube 411b are
formed integrally with each other. The second U-shaped tube 411c is coupled to an
end portion of the straight tube 411a by welding, brazing, or the like after the straight
tube 411a is inserted into the through holes of the heat transfer fin 412 and subjected
to tube expansion processing.
(1-1-2) Indoor Fan 42
[0046] The indoor fan 42 takes indoor air into the indoor unit 4, causes the indoor air
to exchange heat with the refrigerant in the indoor heat exchanger 41, and then supplies
the air to the inside of a room. As the indoor fan 42, a centrifugal fan, a multi-blade
fan, or the like is employed. The indoor fan 42 is driven by an indoor fan motor 43.
(1-1-3) Indoor-Side Control Unit 44
[0047] The indoor-side control unit 44 controls operation of each portion that constitutes
the indoor unit 4. The indoor-side control unit 44 has a microcomputer and a memory
that are for controlling the indoor unit 4.
[0048] The indoor-side control unit 44 transmits and receives a control signal and the like
to and from a remote controller (not illustrated). In addition, the indoor-side control
unit 44 transmits and receives a control signal and the like to and from an outdoor-side
control unit 38 of the outdoor unit 2 via a transmission line 8a.
(1-2) Outdoor Unit 2
[0049] The outdoor unit 2 is installed outdoors and constitutes part of the refrigerant
circuit 10. The outdoor unit 2 includes a compressor 21, a four-way switching valve
22, an outdoor heat exchanger 23, an expansion valve 26, a liquid-side shutoff valve
27, and a gas-side shutoff valve 28.
(1-2-1) Compressor 21
[0050] The compressor 21 is a device that compresses a low-pressure refrigerant of the refrigeration
cycle. The compressor 21 drives and rotates a positive-displacement compression element
(not illustrated) of a rotary type, a scroll type, or the like by a compressor motor
21a.
[0051] A suction pipe 31 is connected to the suction side of the compressor 21, and a discharge
pipe 32 is connected to the discharge side thereof. The suction pipe 31 is a refrigerant
pipe that connects the suction side of the compressor 21 and the four-way switching
valve 22 to each other. The discharge pipe 32 is a refrigerant pipe that connects
the discharge side of the compressor 21 and the four-way switching valve 22 to each
other.
[0052] An accumulator 29 is connected to the suction pipe 31. The accumulator 29 separates
a flowed-in refrigerant into a liquid refrigerant and a gas refrigerant and causes
only the gas refrigerant to flow to the suction side of the compressor 21.
(1-2-2) Four-Way Switching Valve 22
[0053] The four-way switching valve 22 switches the direction of the flow of the refrigerant
in the refrigerant circuit 10. During cooling operation, the four-way switching valve
22 causes the outdoor heat exchanger 23 to function as a radiator for the refrigerant
and causes the indoor heat exchanger 41 to function as an evaporator for the refrigerant.
[0054] During cooling operation, the four-way switching valve 22 connects the discharge
pipe 32 of the compressor 21 and a first gas refrigerant pipe 33 of the outdoor heat
exchanger 23 to each other and connects the suction pipe 31 of the compressor 21 and
a second gas refrigerant pipe 34 to each other (refer to the solid lines of the four-way
switching valve 22 in Fig. 1).
[0055] During heating operation, the four-way switching valve 22 is switched to a heating
cycle state in which the outdoor heat exchanger 23 functions as an evaporator for
the refrigerant and in which the indoor heat exchanger 41 functions as a radiator
for the refrigerant.
[0056] During heating operation, the four-way switching valve 22 connects the discharge
pipe 32 of the compressor 21 and the second gas refrigerant pipe 34 to each other
and connects the suction pipe 31 of the compressor 21 and the first gas refrigerant
pipe 33 of the outdoor heat exchanger 23 to each other (refer to the broken lines
of the four-way switching valve 22 in Fig. 1).
[0057] Here, the first gas refrigerant pipe 33 is a refrigerant pipe that connects the four-way
switching valve 22 and the refrigerant inlet of the outdoor heat exchanger 23 during
cooling operation to each other. The second gas refrigerant pipe 34 is a refrigerant
pipe that connects the four-way switching valve 22 and the gas-side shutoff valve
28 to each other.
(1-2-3) Outdoor Heat Exchanger 23
[0058] The outdoor heat exchanger 23 functions as a radiator for the refrigerant during
cooling operation. In addition, the outdoor heat exchanger 23 functions as an evaporator
for the refrigerant during heating operation. One end of a liquid refrigerant pipe
35 is connected to the refrigerant outlet of the outdoor heat exchanger 23 during
cooling operation. The other end of the liquid refrigerant pipe 35 is connected to
the expansion valve 26.
[0059] The outdoor heat exchanger 23 will be described in detail in the section "(3) Detailed
Structure of Outdoor Heat Exchanger 23".
(1-2-4) Expansion Valve 26
[0060] The expansion valve 26 is an electric expansion valve. During cooling operation,
the expansion valve 26 decompresses a high-pressure refrigerant that is sent from
the outdoor heat exchanger 23 to a low pressure. During heating operation, the expansion
valve 26 decompresses a high-pressure refrigerant that is sent from the indoor heat
exchanger 41 to a low pressure.
(1-2-5) Liquid-Side Shutoff Valve 27 and Gas-Side Shutoff Valve 28
[0061] The liquid-side shutoff valve 27 is connected to the liquid-refrigerant connection
pipe 5. The gas-side shutoff valve 28 is connected the gas-refrigerant connection
pipe 6. The liquid-side shutoff valve 27 is positioned downstream the expansion valve
26 in a refrigerant circulation direction during cooling operation. The gas-side shutoff
valve 28 is positioned upstream the four-way switching valve 22 in a refrigerant circulation
direction during cooling operation.
(1-2-6) Outdoor Fan
[0062] The outdoor unit 2 includes an outdoor fan 36. The outdoor fan 36 takes outdoor air
into the outdoor unit 2, causes the outdoor air to exchange heat with the refrigerant
in the outdoor heat exchanger 23, and then discharges the air to the outside. As the
outdoor fan 36, a propeller fan or the like is employed. The outdoor fan 36 is driven
by an outdoor-fan motor 37.
(1-2-7) Outdoor-Side Control Unit 38
[0063] The outdoor-side control unit 38 controls operation of each portion that constitutes
the outdoor unit 2. The outdoor-side control unit 38 has a microcomputer and a memory
that are for controlling the outdoor unit 2.
[0064] The outdoor-side control unit 38 transmits and receives a control signal and the
like to and from the indoor-side control unit 44 of the indoor unit 4 via the transmission
line 8a.
(1-3) Refrigerant Connection Pipes 5 and 6
[0065] The connection pipes 5 and 6 are refrigerant pipes that are constructed at a local
site during installation of the air conditioning apparatus 1 in an installation location
at a building or the like. As each of the connection pipes 5 and 6, a pipe having
an appropriate length and an appropriate diameter is employed in accordance with installation
conditions such as an installation location, a combination of the outdoor unit 2 and
the indoor unit 4, and the like.
(2) Basic Operation of Air Conditioning Apparatus
[0066] Next, a basic operation of the air conditioning apparatus 1 will be described with
reference to Fig. 1. The air conditioning apparatus 1 is capable of performing cooling
operation and heating operation as basic operation.
(2-1) Cooling Operation
[0067] During cooling operation, the four-way switching valve 22 is switched to a cooling
cycle state (the state indicated by the solid lines in Fig. 1). In the refrigerant
circuit 10, a low-pressure gas refrigerant of the refrigeration cycle is sucked by
the compressor 21 and discharged after compressed.
[0068] The high-pressure gas refrigerant discharged from the compressor 21 is sent to the
outdoor heat exchanger 23 via the four-way switching valve 22.
[0069] In the outdoor heat exchanger 23 that functions as a radiator, the high-pressure
gas refrigerant sent to the outdoor heat exchanger 23 radiates heat by exchanging
heat with outdoor air supplied from the outdoor fan 36, and becomes a high-pressure
liquid refrigerant. The high-pressure liquid refrigerant is sent to the expansion
valve 26.
[0070] The high-pressure liquid refrigerant sent to the expansion valve 26 is decompressed
to a low pressure of the refrigeration cycle by the expansion valve 26 and becomes
a low-pressure gas-liquid two-phase refrigerant. The low-pressure gas-liquid two-phase
refrigerant decompressed in the expansion valve 26 is sent to the indoor heat exchanger
41 via the liquid-side shutoff valve 27 and the liquid-refrigerant connection pipe
5.
[0071] The low-pressure gas-liquid two-phase refrigerant sent to the indoor heat exchanger
41 evaporates in the indoor heat exchanger 41 by exchanging heat with indoor air supplied
from the indoor fan 42. Consequently, the indoor air is cooled. Then, the cooled air
is supplied to the inside of a room, thereby cooling the inside of the room.
[0072] The low-pressure gas refrigerant that has evaporated in the indoor heat exchanger
41 is sucked again by the compressor 21 via the gas-refrigerant connection pipe 6,
the gas-side shutoff valve 28, and the four-way switching valve 22.
(2-2) Heating Operation
[0073] During heating operation, the four-way switching valve 22 is switched to the heating
cycle state (the state indicated by the broken lines in Fig. 1). In the refrigerant
circuit 10, a low-pressure gas refrigerant of the refrigeration cycle is sucked by
the compressor 21 and discharged after compressed.
[0074] The high-pressure gas refrigerant discharged from the compressor 21 is sent to the
indoor heat exchanger 41 via the four-way switching valve 22, the gas-side shutoff
valve 28, and the gas-refrigerant connection pipe 6.
[0075] The high-pressure gas refrigerant sent to the indoor heat exchanger 41 radiates heat
in the indoor heat exchanger 41 by exchanging heat with indoor air supplied from the
indoor fan 42, and becomes a high-pressure liquid refrigerant. Consequently, the indoor
air is heated. Then, the heated air is supplied to the inside of a room, thereby heating
the inside of the room.
[0076] The high-pressure liquid refrigerant that has radiated heat in the indoor heat exchanger
41 is sent to the expansion valve 26 via the liquid-refrigerant connection pipe 5
and the liquid-side shutoff valve 27.
[0077] The high-pressure liquid refrigerant sent to the expansion valve 26 is decompressed
to a low pressure of the refrigeration cycle by the expansion valve 26 and becomes
a low-pressure gas-liquid two-phase refrigerant. The low-pressure gas-liquid two-phase
refrigerant decompressed in the expansion valve 26 is sent to the outdoor heat exchanger
23.
[0078] The low-pressure gas-liquid two-phase refrigerant sent to the outdoor heat exchanger
23 evaporates in the outdoor heat exchanger 23 by exchanging heat with outdoor air
supplied from the outdoor fan 36, and becomes a low-pressure gas refrigerant.
[0079] The low-pressure refrigerant that has evaporated in the outdoor heat exchanger 23
is sucked again by the compressor 21 through the four-way switching valve 22.
(3) Detailed Description of Outdoor Heat Exchanger 23
(3-1) Structure
[0080] Fig. 3 is an external perspective view of the outdoor heat exchanger 23. In Fig.
3, the outdoor heat exchanger 23 is a stack-type heat exchanger. The outdoor heat
exchanger 23 includes a plurality of flat pipes 231 and a plurality of heat transfer
fins 232.
(3-1-1) Flat Pipes 231
[0081] Each flat pipe 231 is a multi-hole pipe. The flat pipe 231 is formed of aluminum
or an aluminum alloy and has a flat portion 231a that serves as a heat transfer surface,
and a plurality of internal flow paths 231b in which the refrigerant flows.
[0082] The flat pipes 231 are arrayed in a plurality of stages to be stacked with a gap
(ventilation space) therebetween in a state in which respective flat portions 231a
are directed upward/downward.
(3-1-2) Heat Transfer Fins 232
[0083] Each heat transfer fin 232 is a fin made of aluminum or an aluminum alloy. The heat
transfer fin 232 is disposed in a ventilation space between the flat pipes 231 that
are vertically adjacent to each other and is in contact with the flat portions 231a
of the flat pipes 231.
[0084] The heat transfer fin 232 has cutouts 232c (refer to Fig. 5A and Fig. 5B) into which
the flat pipes 231 are inserted. After the flat pipes 231 are inserted into the cutouts
232c of the heat transfer fins 232, the heat transfer fins 232 and the flat portions
231a of the flat pipes 231 are joined to each other by brazing or the like.
(3-1-3) Headers 233a and 233b
[0085] The headers 233a and 233b are coupled to both ends of the flat pipes 231 arrayed
in the plurality of stages in the up-down direction. The headers 233a and 233b have
a function of supporting the flat pipes 231, a function of guiding the refrigerant
to the internal flow paths of the flat pipes 231, and a function of gathering the
refrigerant that has flowed out from the internal flow paths.
[0086] When the outdoor heat exchanger 23 functions as an evaporator for the refrigerant,
the refrigerant flows into the first header 233a. The refrigerant that has flowed
into the first header 233a is distributed to the internal flow paths of the flat pipes
231 of the stages substantially evenly and flows toward the second header 233b. The
refrigerant that flows in the internal flow paths of the flat pipes 231 of the stages
absorbs heat via the heat transfer fins 232 from an air flow that flows in the ventilation
spaces. The refrigerant that has flowed in the internal flow paths of the flat pipes
231 of the stages gathers at the second header 233b and flows out from the second
header 233b.
[0087] When the outdoor heat exchanger 23 functions as a radiator for the refrigerant, the
refrigerant flows into the second header 233b. The refrigerant that has flowed into
the second header 233b is distributed to the internal flow paths of the flat pipes
231 of the stages substantially evenly and flows toward the first header 233a. The
refrigerant that flows in the internal flow paths of the flat pipes 231 of the stages
radiates heat via the heat transfer fins 232 into an air flow that flows in the ventilation
spaces. The refrigerant that has flowed in the internal flow paths of the flat pipes
231 of the stages gathers at the first header 233a and flows out from the first header
233a.
(3-2) Suppression of Frost
[0088] Fig. 4 is a P-H diagram of a non-azeotropic refrigerant mixture. In Fig. 4, the refrigerant
temperature increases toward the evaporator outlet. Since the composition of the non-azeotropic
refrigerant mixture is different between a liquid phase and a gas phase, a "temperature
gradient" in which an evaporation start temperature and an evaporation end temperature
in the evaporator are different is present. Due to the temperature gradient, the temperature
at the inlet easily decreases in the evaporator, which easily causes frost during
heating operation.
[0089] Fig. 5A is a perspective view of a first heat exchange section 23a of the outdoor
heat exchanger 23 according to the first embodiment. In Fig. 5A, the opening side
of the cutouts 232c is positioned on the leeward side in the airflow direction in
the first heat exchange section 23a.
[0090] Fig. 5B is a perspective view of a second heat exchange section 23b of the outdoor
heat exchanger 23 according to the first embodiment. In Fig. 5B, the opening side
of the cutouts 232c is positioned on the windward side in the airflow direction.
[0091] Since the openings of the cutouts 232c are positioned on the windward side in the
airflow direction in the second heat exchange section 23b illustrated in Fig. 5B,
a difference between an air temperature and a heat-exchanger surface temperature is
large, and thus has a feature of improving heat exchange performance but easily causing
frost.
[0092] Meanwhile, since the openings of the cutouts 232c are positioned on the leeward side
in the airflow direction in the first heat exchange section 23a illustrated in Fig.
5A, a difference between an air temperature and a heat-exchanger surface temperature
is small compared with the second heat exchange section 23b. Frost is thus suppressed.
[0093] Therefore, in the present embodiment, the first heat exchange section 23a is formed
on the inlet side of the outdoor heat exchanger 23 that functions as an evaporator.
(3-3) Improvement of Heat Exchange Performance
[0094] As described above, compared with the second heat exchange section 23b, a difference
between an air temperature and a heat-exchanger surface temperature is small in the
first heat exchange section 23a. The heat exchange performance is thus degraded. Therefore,
constituting the entirety of the outdoor heat exchanger 23 by the first heat exchange
section 23a is not preferable for performance.
[0095] Thus, in the present embodiment, both the first heat exchange section 23a and the
second heat exchange section 23b are used to improve heat exchange performance while
suppressing frost.
[0096] Fig. 6A is a schematic perspective view of the outdoor heat exchanger 23 that uses
both the first heat exchange section 23a and the second heat exchange section 23b.
Fig. 6B is a schematic perspective view of a different outdoor heat exchanger 23'
that uses both a first heat exchange section 23a' and a second heat exchange section
23b'.
[0097] In Fig. 6A, when the outdoor heat exchanger 23 functions as an evaporator for the
refrigerant, the refrigerant that has flowed into the first header 233a is distributed
to the internal flow paths 231b of the flat pipes 231 of the stages substantially
evenly and flows toward the second header 233b. The temperature of the non-azeotropic
refrigerant mixture at the evaporator inlet easily decreases, which easily causes
frost. Therefore, a certain section from the first header 233a toward the second header
233b is constituted by the first heat exchange section 23a to suppress frost.
[0098] Meanwhile, the temperature of the non-azeotropic refrigerant mixture increases toward
the evaporator outlet. Thus, to improve heat exchange performance, a part between
the first heat exchange section 23a and the second header 233b is constituted by the
second heat exchange section 23b.
[0099] It is possible by thus disposing the first heat exchange section 23a on the evaporator
inlet side and the second heat exchange section 23b on the evaporator outlet side
to improve heat exchange performance while suppressing frost.
[0100] In Fig. 6B, when the outdoor heat exchanger 23' functions as an evaporator for the
refrigerant, the refrigerant that has flowed into the lower stage of the first header
233a' is distributed to internal flow paths 231b' of the flat pipes 231 of the stages
of the lower stage substantially evenly and flows toward the second header 233b'.
[0101] The refrigerant that has reached the lower stage of the second header 233b' gathers
temporarily and flows into the upper stage of the second header 233b' via a curved
pipe 234. Thereafter, the refrigerant is distributed to the internal flow paths 231b
of the flat pipes 231 of the stages of the upper stage substantially evenly and flows
toward the second header 233b'.
[0102] The temperature of the non-azeotropic refrigerant mixture at the evaporator inlet
easily decreases, which easily causes frost. Therefore, a section from the lower stage
of the first header 233a' toward the lower stage of the second header 233b' is constituted
by the first heat exchange section 23a' to suppress frost.
[0103] Meanwhile, the temperature of the non-azeotropic refrigerant mixture increases toward
the evaporator outlet. Thus, to improve heat exchange performance, a section from
the upper stage of the first header 233b' toward the upper stage of the first header
233a' is constituted by the second heat exchange section 23b'.
[0104] It is possible by thus disposing the first heat exchange section 23a' on the evaporator
inlet side and the second heat exchange section 23b' on the evaporator outlet side
to improve heat exchange performance while suppressing frost.
(4) Features
(4-1)
[0105] In the first heat exchange section 23a of the outdoor heat exchanger 23, the opening
side of the cutouts 232c of the heat transfer fins 232 is positioned on the leeward
side in the airflow direction. By disposing the first heat exchange section 23a on
the side of the inlet for the non-azeotropic refrigerant mixture, it is possible to
improve frost proof performance (capacity of suppressing frost) when the outdoor heat
exchanger 23 functions as an evaporator.
(4-2)
[0106] In addition, by disposing the first heat exchange section 23a on the side of the
inlet for the non-azeotropic refrigerant mixture and disposing the second heat exchange
section 23b, in which the openings of the cutouts 232c are positioned on the windward
side in the airflow direction, on the side of the outlet, it is possible to improve
heat exchange performance while suppressing frost.
(4-3)
[0107] The first heat exchange section 23a and the second heat exchange section 23b are
integral with each other.
(5) Modification
[0108] With the first heat exchange section 23a being disposed on the inlet side of the
outdoor heat exchanger 23 that functions as an evaporator and the second heat exchange
section 23b being disposed on the outlet side, a third heat exchange section 23c may
be disposed between the first heat exchange section 23a and the second heat exchange
section 23b.
[0109] In the third heat exchange section 23c, the distribution center of the flat pipes
231 in the width direction coincides with the center of the heat transfer fins 232
in the airflow direction.
[0110] The technical significance of this modification is that it is possible to try a combination
of the heat exchange sections suitable for a refrigerant temperature in the outdoor
heat exchanger 23 that functions as an evaporator. As a result, it is possible to
improve heat exchange performance while suppressing frost.
[0111] The first heat exchange section 23a may be integral with at least either one of the
second heat exchange section 23b and the third heat exchange section 23c.
<Second Embodiment
[0112] In the first embodiment, a stack-type heat exchanger in which the flat pipes 231
are inserted into the cutouts 232c provided in the heat transfer fins 232 is employed
as the outdoor heat exchanger 23.
[0113] In the second embodiment, a stack-type heat exchanger in which flat pipes extend
through elongated holes provided in heat transfer fins is employed as the outdoor
heat exchanger 23.
(1) Suppression of Frost
[0114] Fig. 7A is a perspective view of a first heat exchange section 123a of the outdoor
heat exchanger 23 according to the second embodiment. In the first heat exchange section
123a in Fig. 7A, a distance from the windward-side end of a flat pipe 231M positioned
on the most windward side in the airflow direction to the windward-side end of a heat
transfer fin 232M is a first dimension D1.
[0115] Fig. 7B is a perspective view of a second heat exchange section 123b of the outdoor
heat exchanger 23 according to the second embodiment. In the second heat exchange
section 123b in Fig. 7B, a distance from the windward-side end of the flat pipe 231M
positioned on the most windward side in the airflow direction to the windward-side
end of the heat transfer fin 232M is a second dimension D2 smaller than the first
dimension D1.
[0116] Since the distance (second dimension D2) from the windward-side end of the flat pipe
231M positioned on the most windward side in the airflow direction to the windward-side
end of the heat transfer fin 232M in the second heat exchange section 123b illustrated
in Fig. 7B is smaller than the distance (first dimension D1) in the first heat exchange
section 123a, a difference between an air temperature and a heat-exchanger surface
temperature is large. The second heat exchange section 123b thus has a feature of
improving heat exchange performance but easily causing frost.
[0117] Meanwhile, since the distance from the windward-side end of the flat pipe 231M positioned
on the most windward side in the airflow direction to the windward-side end of the
heat transfer fin 232M in the first heat exchange section 123a illustrated in Fig.
7A is larger than the distance (second dimension D2) in the second heat exchange section
123b, a difference between an air temperature and a heat-exchanger surface temperature
is small, compared with the second heat exchange section 123b, which suppresses frost.
[0118] Therefore, in the second embodiment, the first heat exchange section 123a is formed
on the inlet side of the outdoor heat exchanger 23 that functions as an evaporator.
(2) Improvement of Heat Exchange Performance
[0119] As described above, compared with the second heat exchange section 123b, a difference
between an air temperature and a heat-exchanger surface temperature is small in the
first heat exchange section 123a. The heat exchange performance is thus degraded.
Therefore, constituting the entirety of the outdoor heat exchanger 23 by the first
heat exchange section 123a is not preferable for performance.
[0120] Thus, in the second embodiment, both the first heat exchange section 123a and the
second heat exchange section 123b are used, as in the first embodiment, to improve
heat exchange performance while suppressing frost. Fig. 6A and Fig. 6B are also applied
to the second embodiment by replacing the first heat exchange section 23a of the first
embodiment with the "first heat exchange section 123a" and replacing the second heat
exchange section 23b of the first embodiment with the "second heat exchange section
123b".
[0121] In Fig. 6A, when the outdoor heat exchanger 23 functions as an evaporator for the
refrigerant, the refrigerant that has flowed into the first header 233a is distributed
to the internal flow paths of the flat pipes of the stages substantially evenly and
flows toward the second header 233b. The temperature of the non-azeotropic refrigerant
mixture at the evaporator inlet easily decreases, which easily causes frost. Therefore,
a certain section from the first header 233a toward the second header 233b is constituted
by the first heat exchange section 123a to suppress frost.
[0122] Meanwhile, the temperature of the non-azeotropic refrigerant mixture increases toward
the evaporator outlet. Thus, to improve heat exchange performance, a part between
the first heat exchange section 123a and the second header 233b is constituted by
the second heat exchange section 123b.
[0123] It is possible by thus disposing the first heat exchange section 123a on the evaporator
inlet side and the second heat exchange section 123b on the evaporator outlet side
to improve heat exchange performance while suppressing frost.
(3) Features of Second Embodiment
(3-1)
[0124] The temperature of the non-azeotropic refrigerant mixture increases from the inlet
toward the outlet of the evaporator. It is thus preferable to put a high priority
on frost proof performance (capacity of suppressing frost) on the inlet side and put
a high priority on heat exchange performance on the outlet side.
[0125] Therefore, it is possible to try a combination suitable for a refrigerant temperature
in the evaporator, the combination being such that the first heat exchange section
123a is disposed on the inlet side of the outdoor heat exchanger 23 that functions
as an evaporator and the second heat exchange section 123b is disposed on the outlet
side.
(3-2)
[0126] The first heat exchange section 123a and the second heat exchange section 123b are
integral with each other.
(4) Modification
[0127] With the first heat exchange section 123a being disposed on the inlet side of the
outdoor heat exchanger 23 that functions as an evaporator and the second heat exchange
section 123b being disposed on the outlet side, a third heat exchange section may
be disposed between the first heat exchange section 123a and the second heat exchange
section 123b.
[0128] Fig. 7C is a perspective view of a third heat exchange section 123c of the outdoor
heat exchanger 23 according to a modification of the second embodiment. In the third
heat exchange section 123c in Fig. 7C, a distance D3 from the windward-side end of
the flat pipe 231M positioned on the most windward side in the airflow direction to
the windward-side end of the heat transfer fin 232M and a distance from the leeward-side
end of the flat pipe 231M positioned on the most leeward side in the airflow direction
to the leeward-side end of the heat transfer fin 232M are equal to each other.
[0129] The technical significance of this modification is that it is possible to try a combination
of the heat exchange sections suitable for a refrigerant temperature in the outdoor
heat exchanger 23 that functions as an evaporator. As a result, it is possible to
improve heat exchange performance while suppressing frost.
[0130] The first heat exchange section 123a may be integral with at least either one of
the second heat exchange section 123b and the third heat exchange section 123c.
<Third Embodiment
[0131] In the first embodiment and the second embodiment, a stack-type heat exchanger is
employed as the outdoor heat exchanger 23. In a third embodiment, a cross-fin-type
heat exchanger is employed as the outdoor heat exchanger 23.
(1) Suppression of Frost
[0132] Fig. 8A is a perspective view of a first heat exchange section 223a of the outdoor
heat exchanger 23 according to the third embodiment. In the first heat exchange section
223a in Fig. 8A, when a plurality of heat transfer tubes 231N are viewed as a heat-transfer-tube
group in the plate thickness direction of a heat transfer fin 232N, the distribution
center of the heat-transfer-tube group in the airflow direction is positioned on the
leeward side of the center of the heat transfer fin 232N in the airflow direction.
[0133] Fig. 8B is a perspective view of a second heat exchange section 223b of the outdoor
heat exchanger 23 according to the third embodiment. In the second heat exchange section
223b in Fig. 8B, the distribution center of the heat-transfer-tube group in the airflow
direction is positioned on the windward side of the center of the heat transfer fin
232N in the airflow direction.
[0134] Since the distribution center of the heat-transfer-tube group is positioned on the
windward side of the center of the heat transfer fin 232N in the airflow direction,
a distance from the windward-side end of the heat transfer tube 231N positioned on
the most windward side in the airflow direction to the windward-side end of the heat
transfer fin 232N is smaller in the second heat exchange section 223b illustrated
in Fig. 8B than the distance in the first heat exchange section 223a. As a result,
a difference between an air temperature and a heat-exchanger surface temperature is
large. The second heat exchange section 223b thus has a feature of improving heat
exchange performance but easily causing frost.
[0135] Meanwhile, since the distribution center of the heat-transfer-tube group in the airflow
direction is positioned on the leeward side of the center of the heat transfer fin
232N in the airflow direction, a distance from the windward-side end of the heat transfer
tube 231N positioned on the most windward side in the airflow direction to the windward-side
end of the heat transfer fin 232N is larger in the first heat exchange section 223a
illustrated in Fig. 8A than the distance in the second heat exchange section 223b.
As a result, compared with the second heat exchange section 223b, a difference between
an air temperature and a heat-exchanger surface temperature is small, which suppresses
frost.
[0136] Therefore, in the third embodiment, the first heat exchange section 223a is formed
on the inlet side of the outdoor heat exchanger 23 that functions as an evaporator.
(2) Improvement of Heat Exchange Performance
[0137] As described above, compared with the second heat exchange section 223b, a difference
between an air temperature and a heat-exchanger surface temperature is small in the
first heat exchange section 223a. The heat exchange performance is thus degraded.
Therefore, constituting the entirety of the outdoor heat exchanger 23 by the first
heat exchange section 223a is not preferable for performance.
[0138] Thus, in the third embodiment, both the first heat exchange section 223a and the
second heat exchange section 223b are used, as in the first embodiment and the second
embodiment, to improve heat exchange performance while suppressing frost. Fig. 6A
and Fig. 6B are also applied to the third embodiment by replacing the first heat exchange
section 23a of the first embodiment with the "first heat exchange section 223a" and
replacing the second heat exchange section 23b of the first embodiment with the "second
heat exchange section 223b".
[0139] In Fig. 6A, when the outdoor heat exchanger 23 functions as an evaporator for the
refrigerant, the refrigerant that has flowed into the first header 233a is distributed
to the heat transfer tubes of the stages substantially evenly and flows toward the
second header 233b. The temperature of the non-azeotropic refrigerant mixture at the
evaporator inlet easily decreases, which easily causes frost. Therefore, a certain
section from the first header 233a toward the second header 233b is constituted by
the first heat exchange section 223a to suppress frost.
[0140] Meanwhile, the temperature of the non-azeotropic refrigerant mixture increases toward
the evaporator outlet. Thus, to improve heat exchange performance, a part between
the first heat exchange section 223a and the second header 233b is constituted by
the second heat exchange section 223b.
[0141] It is possible by thus disposing the first heat exchange section 223a on the evaporator
inlet side and the second heat exchange section 223b on the evaporator outlet side
to improve heat exchange performance while suppressing frost.
(3) Features of Third Embodiment
(3-1)
[0142] The temperature of the non-azeotropic refrigerant mixture increases from the inlet
toward the outlet of the evaporator. It is thus preferable to put a high priority
on frost proof performance (capacity of suppressing frost) on the inlet side and put
a high priority on heat exchange performance on the outlet side.
[0143] Therefore, it is possible to try a combination suitable for a refrigerant temperature
in the evaporator, the combination being such that the first heat exchange section
223a is disposed on the inlet side of the outdoor heat exchanger 23 that functions
as an evaporator and the second heat exchange section 223b is disposed on the outlet
side.
(3-2)
[0144] The first heat exchange section 223a and the second heat exchange section 223b are
integral with each other.
(4) Modification
[0145] With the first heat exchange section 23a being disposed on the inlet side of the
outdoor heat exchanger 23 that functions as an evaporator and the second heat exchange
section 23b being disposed on the outlet side, a third heat exchange section may be
disposed between the first heat exchange section 223a and the second heat exchange
section 223b.
[0146] Fig. 8C is a perspective view of a third heat exchange section 223c of the outdoor
heat exchanger 23 according to a modification of the third embodiment. In the third
heat exchange section 223c in Fig. 8C, the distribution center of the heat-transfer-tube
group in the airflow direction coincides with the center of the fin in the airflow
direction.
[0147] The technical significance of this modification is that it is possible to try a combination
of the heat exchange sections suitable for a refrigerant temperature in the outdoor
heat exchanger 23 that functions as an evaporator. As a result, it is possible to
improve heat exchange performance while suppressing frost.
[0148] The first heat exchange section 223a may be integral with at least either one of
the second heat exchange section 223b and the third heat exchange section 223c.
<Others>
[0149] In each of the embodiments described above, the non-azeotropic refrigerant mixture
is described to include any of a HFC refrigerant, a HFO refrigerant, CF3I, and a natural
refrigerant. More specifically, a non-azeotropic refrigerant mixture corresponding
to any of (A) to (G) below is desirable.
- (A) A non-azeotropic refrigerant mixture that includes any of R32, R1132(E), R1234yf,
R1234ze, CF3I, and CO2
- (B) A non-azeotropic refrigerant mixture that includes at least R1132(E), R32, and
R1234yf
- (C) A non-azeotropic refrigerant mixture that includes at least R1132(E), R1123, and
R1234yf
- (D) A non-azeotropic refrigerant mixture that includes at least R1132(E) and R1234yf
- (E) A non-azeotropic refrigerant mixture that includes at least R32, R1234yf, and
at least one of R1132a and R1114
- (F) A non-azeotropic refrigerant mixture that includes at least R32, CO2, R125, R134a,
and R1234yf
- (G) A non-azeotropic refrigerant mixture that includes at least R1132(Z) and R1234yf
[0150] Embodiments of the present disclosure have been described above; however, it should
be understood that various changes in the forms and details are possible without departing
from the gist and the scope of the present disclosure described in the claims.
INDUSTRIAL APPLICABILITY
[0151] The present disclosure is widely applicable to a refrigeration apparatus capable
of performing cooling operation and heating operation.
REFERENCE SIGNS LIST
[0152]
1 air conditioning apparatus (refrigeration apparatus)
23 outdoor heat exchanger (evaporator)
23a first heat exchange section
23b second heat exchange section
23c third heat exchange section
123a first heat exchange section
123b second heat exchange section
123c third heat exchange section
223a first heat exchange section
223b second heat exchange section
223c third heat exchange section
231 flat pipe (heat transfer tube)
231M flat pipe (heat transfer tube)
231N heat transfer tube
232 heat transfer fin
232c cutout
232M heat transfer fin
232N heat transfer fin
CITATION LIST
PATENT LITERATURE
1. An evaporator of a refrigeration cycle apparatus in which a non-azeotropic refrigerant
mixture is enclosed, the evaporator comprising:
a plurality of fins (232) that are arranged at a predetermined interval in a plate
thickness direction; and
a plurality of heat transfer tubes (231) that extend through the plurality of fins
in the plate thickness direction,
wherein a first heat exchange section (23a) in which, when the plurality of heat transfer
tubes are viewed as a heat-transfer-tube group in the plate thickness direction of
the fins, a distribution center of the heat-transfer-tube group in an airflow direction
is positioned on a leeward side of a center of the fins in the airflow direction is
formed.
2. The evaporator according to claim 1,
wherein a second heat exchange section (23b) in which the distribution center of the
heat-transfer-tube group is positioned on a windward side of the center of the fins
in the airflow direction is further formed.
3. The evaporator according to claim 2,
wherein a third heat exchange section in which the distribution center of the heat-transfer-tube
group coincides with the center of the fins in the airflow direction is further formed.
4. The evaporator according to claim 2,
wherein the first heat exchange section and the second heat exchange section are integral
with each other.
5. The evaporator according to claim 3,
wherein the first heat exchange section is integral with at least either one of the
second heat exchange section and the third heat exchange section.
6. An evaporator of a refrigeration cycle apparatus in which a non-azeotropic refrigerant
mixture is enclosed, the evaporator comprising:
a plurality of fins (232) that are arranged at a predetermined interval in a plate
thickness direction; and
a plurality of heat transfer tubes (231) that extend through the plurality of fins
in the plate thickness direction,
wherein a first heat exchange section (23a) in which a distance from a windward-side
end of the heat transfer tube positioned on a most windward side in an airflow direction
to a windward-side end of the fins is a first dimension, and
a second heat exchange section (23b) in which a distance from a windward-side end
of the heat transfer tube positioned on a most windward side in an airflow direction
to a windward-side end of the fins is a second dimension smaller than the first dimension
are formed.
7. The evaporator according to claim 6,
wherein a third heat exchange section in which
a distance from a windward-side end of the heat transfer tube positioned on a most
windward side in an airflow direction to a windward-side end of the fins, and
a distance from a leeward-side end of the heat transfer tube positioned on a most
leeward side in an airflow direction to a leeward-side end of the fins
are equal to each other is further formed.
8. The evaporator according to claim 6,
wherein the first heat exchange section and the second heat exchange section are integral
with each other.
9. The evaporator according to claim 7,
wherein the first heat exchange section is integral with at least either one of the
second heat exchange section and the third heat exchange section.
10. An evaporator of a refrigeration cycle apparatus in which a non-azeotropic refrigerant
mixture is enclosed, the evaporator comprising:
a plurality of fins (232) that are arranged at a predetermined interval in a plate
thickness direction; and
a plurality of heat transfer tubes (231) that extend through the plurality of fins
in the plate thickness direction,
wherein the fins have a plurality of cutouts (232c) that are arranged in a direction
orthogonal to both an airflow direction and the plate thickness direction,
the heat transfer tubes are flat multi-hole pipes inserted into the cutouts, and
a first heat exchange section (23a) in which an opening side of the cutouts is positioned
on a leeward side in the airflow direction is formed.
11. The evaporator according to claim 10,
wherein a second heat exchange section (23b) in which the opening side of the cutouts
is positioned on a windward side in the airflow direction is further formed.
12. The evaporator according to claim 11,
wherein the first heat exchange section and the second heat exchange section are integral
with each other.
13. A refrigeration cycle apparatus comprising:
the evaporator according to any one of claims 1 to 12,
wherein the non-azeotropic refrigerant mixture includes any of a HFC refrigerant,
a HFO refrigerant, CF3I, and a natural refrigerant.
14. A refrigeration cycle apparatus comprising:
the evaporator according to any one of claims 1 to 12,
wherein the non-azeotropic refrigerant mixture includes any of R32, R1132(E), R1234yf,
R1234ze, CF3I, and CO2.
15. A refrigeration cycle apparatus comprising:
the evaporator according to any one of claims 1 to 12,
wherein the non-azeotropic refrigerant mixture includes at least R1132(E), R32, and
R1234yf.
16. A refrigeration cycle apparatus comprising:
the evaporator according to any one of claims 1 to 12,
wherein the non-azeotropic refrigerant mixture includes at least R1132(E), R1123,
and R1234yf.
17. A refrigeration cycle apparatus comprising:
the evaporator according to any one of claims 1 to 12,
wherein the non-azeotropic refrigerant mixture includes at least R1132(E) and R1234yf.
18. A refrigeration cycle apparatus comprising:
the evaporator according to any one of claims 1 to 12,
wherein the non-azeotropic refrigerant mixture includes at least R32, R1234yf, and
at least one of R1132a and R1114.
19. A refrigeration cycle apparatus comprising:
the evaporator according to any one of claims 1 to 12,
wherein the non-azeotropic refrigerant mixture includes at least R32, CO2, R125, R134a,
and R1234yf.
20. The refrigeration cycle apparatus comprising:
the evaporator according to any one of claims 1 to 12,
wherein the non-azeotropic refrigerant mixture includes at least R1132(Z) and R1234yf.