TECHNICAL FIELD
[0001] The present invention relates to an air conditioner, and particularly to an air conditioner
that performs heating through a vapor compression refrigeration cycle.
BACKGROUND ART
[0002] In a case where an air conditioner that performs heating through the vapor compression
refrigeration cycle starts a heating operation, conditioned air blown out from an
indoor unit of the air conditioner is at substantially the same low temperature as
a room temperature at the time point of starting the heating operation, until an indoor
heat exchanger of the air conditioner warms up. If the conditioned air at such a low
temperature or the conditioned air mixed with indoor air is blown onto a user in the
room, the user may feel uncomfortable by cold air blow out from the indoor unit. In
order to protect the user from feeling cold by cold air blown out from the air conditioner
immediately after the start of the heating operation, for example, the air conditioner
described in Patent Literature 1 (
JP 9-303844 A) restricts the volume of air blown out from a fan until the temperature of the conditioned
air to be blown out rises. Another air conditioner is disclosed in patent document
JPH05141755A.
<Technical Problem>
[0003] However, if the volume of air to be blown out is restricted at the time of starting
the heating operation as described in Patent Literature 1, the rise in room temperature
is also reduced, and it takes time for the room to warm up.
SUMMARY OF THE INVENTION
[0004] Aim of the present invention is to provide an air conditioner which improves the
state of the art indicated above. This aim is achieved by the air conditioner according
to the corresponding appended independent claims 1 and 7. Preferred embodiments of
the invention are provided according to the dependent claims.
[0005] In particular, object of the present invention is to reduce uncomfortable feeling
due to cold air and promote a rise in room temperature in an air conditioner that
performs heating through a vapor compression refrigeration cycle.
<Solution to Problem>
[0006] In a first aspect, an air conditioner according to claim 1 of the present invention
includes: an indoor heat exchanger configured to exchange heat between refrigerant
and indoor air in a vapor compression refrigeration cycle; and an indoor fan configured
to be able to change an air volume at a time of blowing out, into a room, conditioned
air obtained through the heat exchange by the indoor heat exchanger, wherein the air
conditioner is configured to perform, when starting heating, first cold air reduction
control for performing an air volume restriction of the indoor fan until a temperature
of the indoor heat exchanger reaches a first temperature, and second cold air reduction
control for cancelling the air volume restriction at the indoor fan when the temperature
of the indoor heat exchanger reaches a second temperature lower than the first temperature.
[0007] The air conditioner according to the first aspect performs the first cold air reduction
control for restricting the air volume of the indoor fan until the temperature of
the indoor heat exchanger reaches the first temperature, and the second cold air reduction
control for cancelling the air volume restriction at the indoor fan when the temperature
of the indoor heat exchanger reaches the second temperature lower than the first temperature.
Therefore, the air conditioner can selectively perform the first cold air reduction
control in order to preferentially reduce uncomfortable feeling due to cold air, or
the second cold air reduction control in order to preferentially promote a rise in
room temperature, wherein wherein the first cold air reduction control or the second
cold air reduction control is selected in accordance with a preset selection condition.
[0008] The air conditioner according to the first aspect further includes a flap configured
to swing a direction of blowing out the conditioned air from the indoor fan, wherein
the selection condition includes, as a condition for selecting the second cold air
reduction control, a condition requiring that the flap not be swinging.
[0009] In the air conditioner according to the fourth aspect, the selection condition includes,
as a condition for selecting the second cold air reduction control, the condition
requiring that the flap not be swinging, and thus the second cold air reduction control
is not performed while the flap is swinging to blow out conditioned air to a wide
range. Therefore, it is possible to reduce the conditioned air being blown directly
onto a user, even if the second cold air reduction control is performed while the
user is in the room. If the swing is stopped in order to select the second cold air
reduction control, the user is very likely to mistake the stop for a malfunction.
The present invention can avoid such a mistake.
[0010] An air conditioner according to a second aspect of the present invention includes
alternatively to the first aspect of the present invention, a horizontal flap configured
to change an up-down direction of blowing out the conditioned air from the indoor
fan, wherein the selection condition includes, as a condition for selecting the second
cold air reduction control, a condition requiring that the horizontal flap be oriented
upward relative to a predetermined angle.
[0011] In the air conditioner according to the fifth aspect, the selection condition includes,
as a condition for selecting the second cold air reduction control, the condition
requiring that the horizontal flap be oriented upward relative to the predetermined
angle, and thus the second cold air reduction control is not performed when the horizontal
flap is oriented at, or downward relative to, the predetermined angle. Therefore,
if the predetermined angle is set such that the conditioned air is not blown onto
the user in the room, it is possible to reduce the conditioned air being blown directly
onto the user, even if the second cold air reduction control is performed while the
user is in the room.
[0012] Other preferred aspect of the invention are provided in the appended dependent claims.
<Advantageous Effects of Invention>
[0013] The air conditioner according of the present invention makes it possible to reduce
uncomfortable feeling due to cold air and to promote a rise in room temperature.
[0014] The air conditioner according of the present invention makes it easy to reduce uncomfortable
feeling due to cold air and to promote a rise in room temperature.
[0015] In the air conditioner according to another aspect of the present invention, the
second cold air reduction control is not performed when the room is already warm and
there is little need to raise the room temperature quickly. This makes it possible
to improve an effect of reducing uncomfortable feeling due to cold air.
[0016] In the air conditioner according to the present invention, during the second cold
air reduction control, it is possible to prevent a movement of the flap that may be
mistaken for a malfunction and a movement of the flap that increases the uncomfortable
feeling due to cold air.
[0017] The air conditioner according to aspects of the present invention makes it possible
to improve the function of reducing uncomfortable feeling due to cold air.
[0018] The air conditioner according to another aspect of the present invention improves
the function of promoting a rise in room temperature.
BRIEF DESCRIPTION OF THE DRAWINGS
[0019]
FIG. 1 is a perspective view illustrating an appearance of an air conditioner according
to an embodiment.
FIG. 2 is a circuit diagram illustrating a schematic configuration of the air conditioner
according to the embodiment.
FIG. 3 is a cross-sectional view of an indoor unit in which horizontal flaps are at
positions of a ceiling flow being selected as a wind direction.
FIG. 4 is a block diagram illustrating a schematic configuration of a control system
of the air conditioner.
FIG. 5 is a cross-sectional view of the indoor unit in which the horizontal flaps
are at positions of an upward flow being selected as the wind direction.
FIG. 6 is a cross-sectional view of the indoor unit in which the horizontal flaps
are at positions of a vertical flow being selected as the wind direction.
FIG. 7 is a conceptual view illustrating the interior of a room and the indoor unit
for describing a difference in the wind direction between an upward flow and a downward
flow.
FIG. 8 is a flowchart for describing first cold air reduction control and second cold
air reduction control.
FIG. 9 is a flowchart for describing second cold air reduction control and third cold
air reduction control in Modification 1A.
FIG. 10 is a circuit diagram illustrating a schematic configuration of an air conditioner
according to Modification IB.
FIG. 11 is a block diagram illustrating a schematic configuration of a control system
of the air conditioner according to Modification IB.
FIG. 12 is a flowchart for describing first cold air reduction control and second
cold air reduction control in Modification 1C.
DESCRIPTION OF EMBODIMENTS
(1) Overall configuration
[0020] A schematic configuration of an air conditioner according to an embodiment of the
present invention will be described with reference to FIGS. 1 and 2. An air conditioner
1 illustrated in FIG. 1 includes an indoor unit 3 attached to, for example, a wall
surface WL in a room, and an outdoor unit 2 installed outdoors. In FIG. 1, the outdoor
unit 2 is illustrated by a broken line since the outdoor unit 2 is located outdoors
on the opposite side of the indoor unit 3 with the wall surface WL interposed therebetween.
FIG. 2 illustrates a circuit configuration of the air conditioner 1. The air conditioner
1 includes a refrigerant circuit 10, and can execute a vapor compression refrigeration
cycle by circulating refrigerant in the refrigerant circuit 10. The indoor unit 3
and the outdoor unit 2 are connected by a connection pipe 4 in order to form the refrigerant
circuit 10 through which the refrigerant circulates. As illustrated in FIG. 4, the
air conditioner 1 also includes a control unit 50 in order to control internal devices.
A remote controller 5 is attached to the air conditioner 1. The remote controller
5 has a function of communicating with the control unit 50 using, for example, an
infrared ray. A user can use the remote controller 5 to make various settings for
the air conditioner 1.
(1-1) Refrigerant circuit 10
[0021] The refrigerant circuit 10 includes a compressor 11, an outdoor heat exchanger 13,
an expansion mechanism 14, an accumulator 15, and an indoor heat exchanger 16. The
compressor 11 sucks the refrigerant through a suction port, and discharges the refrigerant
compressed inside the compressor 11 to the indoor heat exchanger 16 through a discharge
port. The compressor 11 is a variable-capacity inverter compressor that controls the
number of rotations by an inverter. As an operating frequency of the compressor 11
increases, the amount of circulating refrigerant increases. As the operating frequency
of the compressor 11 decreases, on the other hand, the amount of circulating refrigerant
decreases.
[0022] The outdoor heat exchanger 13 includes a first port and a second port. The first
port allows the refrigerant to flow between the outdoor heat exchanger 13 and the
suction port of the compressor 11 via the accumulator 15. The second port allows the
refrigerant to flow between the outdoor heat exchanger 13 and the expansion mechanism
14. The outdoor heat exchanger 13 exchanges heat between outdoor air and the refrigerant
flowing through a heat transfer tube (not illustrated) connected between the second
port and the first port of the outdoor heat exchanger 13.
[0023] The expansion mechanism 14 is disposed between the outdoor heat exchanger 13 and
the indoor heat exchanger 16. The expansion mechanism 14 has a function of expanding
and thus decompressing the refrigerant flowing between the outdoor heat exchanger
13 and the indoor heat exchanger 16. The expansion mechanism 14 is configured to change
the opening degree thereof. A decrease in the opening degree increases a flow path
resistance of the refrigerant passing through the expansion mechanism 14. An increase
in the opening degree decreases the flow path resistance of the refrigerant passing
through the expansion mechanism 14. During a heating operation, such an expansion
mechanism 14 expands and thus decompresses the refrigerant flowing from the indoor
heat exchanger 16 toward the outdoor heat exchanger 13. A change in the opening degree
of the expansion mechanism 14 changes a flow rate of the refrigerant flowing through
the refrigerant circuit 10, even if the state of the other devices attached to the
refrigerant circuit 10 does not change.
[0024] The indoor heat exchanger 16 includes a first port and a second port. The first port
allows gas refrigerant to flow between the indoor heat exchanger 16 and the discharge
port of the compressor 11. The second port allows liquid refrigerant to flow between
the indoor heat exchanger 16 and the expansion mechanism 14. The indoor heat exchanger
16 exchanges heat between indoor air and the refrigerant flowing through heat transfer
tubes 16b (see FIG. 3) connected between the second port and the first port of the
indoor heat exchanger 16.
[0025] The accumulator 15 is disposed between the outdoor heat exchanger 13 and the suction
port of the compressor 11. In the accumulator 15, the refrigerant flowing from the
outdoor heat exchanger 13 toward the compressor 11 is separated into gas refrigerant
and liquid refrigerant. Then, the gas refrigerant is mainly supplied from the accumulator
15 to the suction port of the compressor 11.
[0026] In order to promote heat exchange between the outdoor air and the refrigerant flowing
through the heat transfer tube, the outdoor unit 2 includes an outdoor fan 21 that
generates a flow of the outdoor air passing through the outdoor heat exchanger 13.
The outdoor fan 21 is driven by an outdoor fan motor 21a, whose number of rotations
is changeable. In order to promote heat exchange between the indoor air and the refrigerant
flowing through the heat transfer tubes 16b, the indoor unit 3 includes an indoor
fan 31 that generates a flow of the indoor air passing through the indoor heat exchanger
16. The indoor fan 31 is driven by an indoor fan motor 31a, whose number of rotations
is changeable.
(1-2) Configuration of indoor unit 3
[0027] As illustrated in FIG. 3, the indoor unit 3 includes a casing 61, an air filter 62,
and a plurality of vertical flaps 63 and horizontal flaps 64 and 65, in addition to
the indoor heat exchanger 16 and the indoor fan 31 described above.
(1-2-1) Casing 61
[0028] The casing 61 has a box shape that is elongated in the longitudinal direction (hereinafter
also referred to as the right-left direction) and provided with a plurality of openings.
A suction port 71 is provided in a top surface portion of the casing 61. When the
indoor fan 31 is driven, indoor air near the suction port 71 is taken into the casing
61 through the suction port 71. The indoor air taken in through the suction port 71
passes through the air filter 62 provided on the top surface portion of the casing
61, then passes through the indoor heat exchanger 16, and is sent to the indoor fan
31. A blow-out port 72 is formed in a bottom surface portion of the casing 61. The
blow-out port 72 communicates with the interior of the casing 61 via a scroll flow
path 72b continuing from the indoor fan 31. The indoor air sucked through the suction
port 71 is subjected to heat exchange in the indoor heat exchanger 16, and then blown
out from the blow-out port 72 into a room RS through the scroll flow path 72b. A flow
path lower surface 72a is provided on the rear side of the scroll flow path 72b. A
cross-sectional shape of the flow path lower surface 72a draws a curve that goes away
from the rotation center of the indoor fan 31 as the flow path lower surface 72a goes
downward.
(1-2-2) Configuration for adjusting wind direction
[0029] The blow-out port 72 is provided with the two horizontal flaps 64 and 65 that extend
in the right-left direction. The horizontal flaps 64 and 65 are turnably attached
to the casing 61. The horizontal flaps 64 and 65 are configured to independently turn
around their respective centers of rotation that extend in the right-left direction,
by horizontal flap drive motors 37 provided for the respective horizontal flaps 64
and 65. The horizontal flap drive motors 37 are controlled by an indoor control device
35 (see FIG. 4) provided in the indoor unit 3. The horizontal flaps 64 and 65 adjust,
independently or in cooperation with each other, an up-down flow direction of air
that is blown out from the blow-out port 72.
[0030] The plurality of vertical flaps 63 having surfaces crossing the right-left direction
is provided at the back of the blow-out port 72. The vertical flaps 63 are configured
to turn right and left around centers of rotation extending in an up-down direction
(direction crossing the right-left direction), by a vertical flap drive motor 38 (see
FIG. 4). The indoor control device 35 also controls the vertical flap drive motor
38 that drives the vertical flaps 63. The plurality of vertical flaps 63 adjust the
right-left flow direction of air blown out from the blow-out port 72.
(1-2-3) Indoor heat exchanger 16
[0031] The indoor heat exchanger 16 includes a plurality of fins 16a and the plurality of
heat transfer tubes 16b penetrating the plurality of fins 16a. The indoor heat exchanger
16 functions as an evaporator or a radiator in accordance with an operating state
of the indoor unit 3, and exchanges heat between the refrigerant flowing through the
heat transfer tubes 16b and the air passing through the indoor heat exchanger 16.
Although the indoor heat exchanger 16 including the fins 16a and the heat transfer
tubes 16b has been described herein, the indoor heat exchanger 16 used in the present
invention is not limited to a fin-and-tube heat exchanger. For example, a heat exchanger
including a flat multi-hole tube instead of the heat transfer tube 16b may be used.
(1-2-4) Indoor fan 31
[0032] As illustrated in FIG. 3, the indoor fan 31 is located substantially at the center
of the interior of the casing 61. The indoor fan 31 is a cross-flow fan having a substantially
cylindrical shape elongated in the longitudinal direction (right-left direction) of
the indoor unit 3. When the indoor fan 31 is driven to rotate, indoor air is sucked
through the suction port 71 and passes through the air filter 62, and then passes
through the indoor heat exchanger 16. Conditioned air generated in this manner is
blown out from the blow-out port 72 into the room RS. The indoor fan 31 rotates in
accordance with the number of rotations of the indoor fan motor 31a. The larger the
number of rotations, the larger the volume of conditioned air blown out from the blow-out
port 72.
(1-3) Schematic configuration of control system
[0033] As illustrated in FIG. 4, the control unit 50 includes an outdoor control device
26 incorporated in the outdoor unit 2, and the indoor control device 35 incorporated
in the indoor unit 3. The outdoor control device 26 and the indoor control device
35 are connected to each other by a signal line, and are configured to transmit and
receive signals therebetween.
[0034] The outdoor control device 26 of the outdoor unit 2 controls, for example, the compressor
11, the expansion mechanism 14, and the outdoor fan 21 and the like. For that purpose,
the outdoor unit 2 includes an outdoor temperature sensor 22, an outdoor heat exchanger
temperature sensor 23, a discharge pipe temperature sensor 24, and a suction pipe
temperature sensor 25. The outdoor temperature sensor 22 measures a temperature of
outdoor air. The outdoor heat exchanger temperature sensor 23 measures a temperature
of refrigerant flowing in a specific part of the outdoor heat exchanger 13. The discharge
pipe temperature sensor 24 detects a temperature of refrigerant discharged from the
compressor 11. The suction pipe temperature sensor 25 detects a temperature of gas
refrigerant sucked into the compressor 11. The outdoor control device 26 is connected
to the outdoor temperature sensor 22, the outdoor heat exchanger temperature sensor
23, the discharge pipe temperature sensor 24, and the suction pipe temperature sensor
25 in order to receive signals related to the temperatures measured by these sensors
22 to 25. The outdoor control device 26 includes, for example, a CPU (not illustrated)
and a memory 26a, and is configured to control the outdoor unit 2 in accordance with
a program or the like stored in the memory 26a.
[0035] The indoor control device 35 of the indoor unit 3 controls the indoor fan 31 and
the like. For that purpose, the indoor unit 3 includes a room temperature sensor 32
and an indoor heat exchanger temperature sensor 33. The room temperature sensor 32
measures a temperature of indoor air. The indoor heat exchanger temperature sensor
33 measures a temperature of refrigerant flowing in a specific part of the indoor
heat exchanger 16. The indoor control device 35 is connected to the room temperature
sensor 32 and the indoor heat exchanger temperature sensor 33 in order to receive
signals related to the temperatures measured by the room temperature sensor 32 and
the indoor heat exchanger temperature sensor 33. The indoor control device 35 includes,
for example, a CPU (not illustrated) and a memory 35a, and is configured to control
the indoor unit 3 in accordance with a program or the like stored in the memory 35a.
[0036] The remote controller 5 includes a liquid crystal display device 5a and buttons 5b
illustrated in FIG. 1. The buttons 5b correspond to, for example, an operation switch
51, a temperature setting switch 52, a wind direction setting switch 53, and an air
volume setting switch 54 illustrated in FIG. 4. A user can operate these switches
using the buttons 5b. The operation switch 51 is for switching between start and stop
of the operation of the air conditioner 1. The start and stop of the operation are
switched every time the operation switch 51 is operated. The temperature setting switch
52 is used to input a room temperature desired by the user. The wind direction setting
switch 53 is for setting a wind direction. The air volume setting switch 54 is used
to input an air volume.
[0037] The control unit 50 sets a target room temperature Tt based on a set temperature
Ts input through the temperature setting switch 52. During the heating operation,
for example, a temperature (Ts + α1) obtained by adding a constant value α1 to the
set temperature Ts is set as the target room temperature Tt. Alternatively, a temperature
(Ts + β1) obtained by adding a value β1 calculated in accordance with a predetermined
function f1(x) to the set temperature Ts may be set as the target room temperature
Tt. When a room temperature Tr becomes higher than the target room temperature Tt,
the control unit 50 sets the air conditioner 1 to a thermo-off state. When the room
temperature Tr becomes lower than a temperature (Ts - α2) obtained by subtracting
a constant value α2 from the set temperature Ts, the control unit 50 sets the air
conditioner 1 to a thermo-on state. Alternatively, the control unit 50 may set the
air conditioner 1 to the thermo-on state when the room temperature Tr becomes lower
than a temperature (Ts - β2) obtained by subtracting a value β2 calculated in accordance
with a predetermined function f2(x) from the set temperature Ts. In the thermo-on
state, the compressor 11 is driven and heat is transferred by the refrigerant. In
the thermo-off state, on the other hand, the compressor 11 is stopped, thus stopping
the heat transfer by the refrigerant.
[0038] The control unit 50 controls various devices constituting the air conditioner 1 based
on measurement values of the various sensors as described above and a command input
from the remote controller 5. The control unit 50 also notifies the user of the status
of the input command and the status of control using the liquid crystal display device
5a of the remote controller 5.
(2) Wind direction adjustment
(2-1) Manual setting
[0039] The user can manually adjust the positions of the vertical flaps 63 and the horizontal
flaps 64 and 65 using the wind direction setting switch 53 of the remote controller
5. With the indoor unit 3, for example, wind directions called "frontward flow", "rightward
flow", and "leftward flow" can be set in the right-left direction. For example, when
the "frontward flow" is selected as the wind direction, the vertical flaps 63 stop
while extending in the frontrear direction, and conditioned air is blown out forward.
When the "rightward flow" is selected as the wind direction, the vertical flaps 63
stop while being inclined to the right, and conditioned air is blown out rightward.
When the "leftward flow" is selected as the wind direction, the vertical flaps 63
stop while being inclined to the left, and conditioned air is blown out leftward.
The indoor unit 3 is also configured to select, for example, wind directions called
"ceiling flow", "upward flow", "downward flow", and "vertical flow" in the up-down
direction. When the "ceiling flow" is selected as the wind direction, the indoor unit
3 directs the tips of the horizontal flaps 64 and 65 to their respective highest positions,
and blows out conditioned air from the blow-out port 72 in a direction indicated by
an arrow Ar1 in FIG. 3, such that the conditioned air flows along a ceiling CE. When
the "upward flow" is selected as the wind direction, the indoor unit 3 slightly lowers
the tips of the horizontal flaps 64 and 65 as compared with the case of the "ceiling
flow", and blows out conditioned air in an upward direction relative to the horizontal
direction as indicated by an arrow Ar2 in FIG. 5. When the "downward flow" is selected
as the wind direction, the indoor unit 3 blows out conditioned air in a downward direction
relative to the horizontal direction. When the "vertical flow" is selected as the
wind direction, the indoor unit 3 directs the tips of the horizontal flaps 64 and
65 to their respective lowest positions as illustrated in FIG. 6, and blows out conditioned
air such that the conditioned air flows along the wall surface WL. The air flow indicated
by an arrow Ar1 in FIG. 7 is an example of the air flow generated when the "ceiling
flow" is selected as the wind direction. The air flow indicated by an arrow Ar2 in
FIG. 7 is an example of the air flow generated when the "upward flow" is selected
as the wind direction. The air flow indicated by an arrow Ar3 in FIG. 7 is an example
of the air flow generated when the "downward flow" is selected as the wind direction.
The air flow indicated by an arrow Ar4 in FIG. 7 is an example of the air flow generated
when the "vertical flow" is selected as the wind direction. Although the case where
the up-down wind direction can be selected from among the four different wind directions
has been described here, the method of setting the wind directions that can be selected
in the up-down wind direction is not limited to this example.
(2-2) Swing setting
[0040] The wind direction setting switch 53 of the remote controller 5 can select how the
vertical flaps 63 swing. The wind direction setting switch 53 of the remote controller
5 can also select how the horizontal flaps 64 and 65 swing. Furthermore, the wind
direction setting switch 53 can select how the vertical flaps 63 and the horizontal
flaps 64 and 65 swing together.
(2-3) Automatic setting
[0041] The wind direction setting switch 53 of the remote controller 5 can be used to select
a wind direction automatic mode in which the control unit 50 sets the wind direction.
In the wind direction automatic mode, the control unit 50 automatically sets the wind
direction in accordance with the program stored in the memory 35a.
(3) Air volume adjustment
[0042] There are two modes of air volume adjustment, i.e., automatic setting and manual
setting. In the automatic setting mode, the control unit 50 automatically sets the
air volume in accordance with the program stored in the memory 35a. In the manual
setting mode, the user can use the air volume setting switch 54 of the remote controller
5 to set, for example, five different air volumes. Here, the five different air volumes
are called a first air volume, a second air volume, a third air volume, a fourth air
volume, and a fifth air volume in ascending order of air volume.
(4) Heating operation
[0043] During the heating operation of the air conditioner 1, high-temperature, high-pressure
refrigerant discharged from the compressor 11 flows into the indoor heat exchanger
16. At this time, the indoor heat exchanger 16 functions as a radiator. Therefore,
as the refrigerant flows through the indoor heat exchanger 16, the refrigerant warms
indoor air by exchanging heat with the indoor air, and the refrigerant is cooled by
radiation. The low-temperature, high-pressure refrigerant, the temperature of which
has been lowered by the indoor heat exchanger 16, is decompressed by the expansion
mechanism 14 to change into low-temperature, low-pressure refrigerant. The refrigerant
that has flowed into the outdoor heat exchanger 13 via the expansion mechanism 14
is warmed by exchanging heat with outdoor air. At this time, the outdoor heat exchanger
13 functions as an evaporator. Then, mainly low-temperature gas refrigerant flowing
from the outdoor heat exchanger 13 via the accumulator 15 is sucked into the compressor
11.
(4-1) First cold air reduction control and second cold air reduction control
(4-1-1) Start, cancellation of restriction, and end of first cold air reduction control
and second cold air reduction control
[0044] The first cold air reduction control and the second cold air reduction control will
be described with reference to the flowchart of FIG. 8. For example, when the button
5b for switching the operation switch 51 of the remote controller 5 is pressed to
start the operation (step S1), the control unit 50 determines whether a first start
condition has been satisfied (step S2). The first start condition is for determining
whether or not to start the first cold air reduction control or the second cold air
reduction control. If the first start condition has not been satisfied, neither the
first cold air reduction control nor the second cold air reduction control is performed.
Therefore, if the first start condition has not been satisfied, the processing proceeds
to step S9. If the first start condition has been satisfied, the processing proceeds
to next step S3, where it is determined whether a second start condition has been
satisfied. The second start condition is for determining whether the first cold air
reduction control or the second cold air reduction control is performed. The details
of the first start condition and the second start condition will be described later.
[0045] If it is determined in step S3 that the second start condition has been satisfied,
the second cold air reduction control is started (step S4) to restrict the air volume.
The first start condition and the second start condition are not usually changed after
the second cold air reduction control is started. Therefore, until the temperature
of the indoor heat exchanger 16 reaches a second temperature, steps S2, S3, S4 and
S5 are repeated in a loop and the second cold air reduction control continues. When
the temperature of the indoor heat exchanger 16 reaches the second temperature, the
processing proceeds from step S5 to step S6, where the air volume restriction of the
second cold air reduction control is cancelled. After the air volume restriction is
cancelled, the processing proceeds to step S9, where it is determined whether or not
to cancel the first cold air reduction control and the second cold air reduction control.
[0046] If it is determined in step S3 that the second start condition has not been satisfied,
the first cold air reduction control is started (step S7) to restrict the air volume.
The first start condition and the second start condition are not usually changed after
the first cold air reduction control is started. Therefore, until the temperature
of the indoor heat exchanger 16 reaches a first temperature, steps S2, S3, S7 and
S8 are repeated in a loop. When the temperature of the indoor heat exchanger 16 reaches
the first temperature, the processing proceeds from step S8 to step S6, where the
air volume restriction of the first cold air reduction control is cancelled. After
the air volume restriction is cancelled, the processing proceeds to step S9, where
it is determined whether or not to cancel the first cold air reduction control and
the second cold air reduction control.
[0047] In step S9, the control unit 50 determines whether the room temperature Tr measured
by the room temperature sensor 32 has exceeded a threshold temperature Th close to
the set temperature Ts. The setting of the threshold temperature Th is a design matter.
For example, the threshold temperature Th is set to a value lower than the set temperature
Ts by y degrees. In this case, if Tr > (Ts - y) is satisfied, the control unit 50
cancels the cold air reduction control (step S10), and ends the cold air reduction
control routine.
[0048] While the started heating operation is continued as it is, the temperature of the
indoor heat exchanger 16 usually rises gradually. However, the temperature of the
indoor heat exchanger 16 may lower after the heating operation is started but before
the temperature reaches the target room temperature Tt. The air conditioner 1 is configured
such that, when the temperature of the indoor heat exchanger 16 rises to the first
temperature or higher and then falls below the first temperature again during the
first cold air reduction control, the air volume is restricted again even after the
air volume restriction is once cancelled. Similarly, the air conditioner 1 is configured
such that, when the temperature of the indoor heat exchanger 16 rises to the second
temperature or higher and then falls below the second temperature again during the
second cold air reduction control, the air volume is restricted again even after the
air volume restriction is once cancelled.
[0049] Note that the second temperature is set lower than the first temperature in the above-described
control. Therefore, the temperature of the indoor heat exchanger 16 at the time when
the air volume restriction is cancelled in the second cold air reduction control is
lower than the temperature of the indoor heat exchanger 16 at the time when the air
volume restriction is cancelled in the first cold air reduction control. In other
words, as compared with the first cold air reduction control, the second cold air
reduction control prioritizes the function of raising the room temperature Tr over
the effect of reducing uncomfortable feeling due to cold air. Meanwhile, in order
to reliably reduce the uncomfortable feeling due to cold air, the second cold air
reduction control is performed only in a case where the second start condition is
satisfied, in which case it is easy to reduce the uncomfortable feeling due to cold
air.
(4-1-2) First start condition
[0050] The first start condition includes a condition requiring that the air conditioner
be in operation. For example, the air conditioner being in operation is an AND condition;
unless the air conditioner is in operation, the first start condition is not satisfied
even if the other conditions are satisfied. Alternatively, the first start condition
may include a condition requiring that the compressor 11 be driven. For example, if
the compressor 11 being driven is an additional AND condition, the cold air reduction
control is started only in a case where the air conditioner is in operation and the
compressor 11 is driven. Alternatively, the first start condition may also include
a condition requiring that the ongoing heating operation not have been reserved. For
example, if the ongoing heating operation not having been reserved is an additional
AND condition, the cold air reduction control is started only in a case where the
air conditioner is in operation, the compressor 11 is driven, and the heating operation
has not been reserved. Alternatively, the first start condition may include a condition
requiring that the "ceiling flow" not be forcibly selected for removing a warm air
accumulation near the ceiling. This additional condition makes it possible to prevent
the air volume restriction when it is desired to generate a strong air flow along
the ceiling.
(4-1-3) Second start condition
[0051] The second start condition includes a condition requiring that the horizontal flaps
64 and 65 be oriented upward relative to a predetermined angle. For example, when
the wind direction is the "upward flow" as illustrated in FIG. 5, the horizontal flaps
64 and 65 are oriented upward relative to a predetermined angle An1 from the horizontal
plane. Therefore, if the second start condition requires that the horizontal flaps
64 and 65 be oriented upward relative to the predetermined angle An1, the horizontal
flaps 64 and 65 at the time of selecting the "ceiling flow" or "upward flow" as the
wind direction satisfy the second start condition.
[0052] Alternatively, the second start condition requiring that the horizontal flaps 64
and 65 be oriented upward relative to the predetermined angle may be instead a condition
requiring that the horizontal flaps 64 and 65 be at angles at which conditioned air
is blown out horizontally or upward relative to the horizontal direction. In this
case, the angles of the horizontal flaps 64 and 65 in the state of the "ceiling flow"
satisfy the second start condition. In the state of the "upward flow" in the present
embodiment, the conditioned air is blown out horizontally or upward relative to the
horizontal direction. Therefore, the angles of the horizontal flaps 64 and 65 in the
state of the "upward flow" also satisfy the second start condition.
[0053] Alternatively, the second start condition requiring that the horizontal flaps 64
and 65 be oriented upward relative to the predetermined angle may be instead a condition
requiring that the horizontal flaps 64 and 65 be at angles at which the conditioned
air is blown out along the ceiling, as well as being blown out horizontally or upward
relative to the horizontal direction. In this case, the angles of the horizontal flaps
64 and 65 in the state of the "ceiling flow" satisfy the second start condition.
[0054] Alternatively, the second start condition may include a condition requiring that
the flaps not be swinging. For example, if the horizontal flaps 64 and 65 and the
vertical flaps 63 not being swinging is an additional AND condition, the second cold
air reduction control is started only in a case where none of the horizontal flaps
64 and 65 and the vertical flaps 63 is swinging and the horizontal flaps 64 and 65
are oriented upward relative to the predetermined angle. In the case where there is
a plurality of flaps, it is possible to set a condition requiring that some specific
flaps not be swinging, for example, only the horizontal flaps 64 and 65 not be swinging.
Alternatively, in the case where there is a plurality of flaps, it is possible to
set a condition requiring that none of the flaps be swinging.
[0055] Alternatively, the second start condition may include a condition requiring that
the difference between the target room temperature Tt and the room temperature Tr
be larger than a threshold. For example, if the difference between the target room
temperature Tt and the room temperature Tr being larger than the threshold is an additional
AND condition, the second cold air reduction control is started only in a case where
none of the horizontal flaps 64 and 65 and the vertical flaps 63 is swinging, the
horizontal flaps 64 and 65 are oriented upward relative to the predetermined angle,
and the difference between the target room temperature Tt and the room temperature
Tr is larger than the threshold.
(4-1-4) Air volume restriction and cancellation thereof
[0056] Examples of the method of restricting the air volume restriction include a method
of restricting the air volume to the first air volume that is the smallest among those
that can be set by the user using the air volume setting switch 54 of the remote controller
5. Alternatively, for example, a dedicated air volume smaller than the first air volume
may be set for the first cold air reduction control and the second cold air reduction
control. In this case, when the air volume is restricted in the first cold air reduction
control and the second cold air reduction control, the air volume is restricted to
the dedicated air volume smaller than the first air volume.
[0057] The simplest method of cancelling the air volume is a method of cancelling all the
air volume restrictions such that any of the first to fifth air volumes is selectable,
when the first temperature is reached during the first cold air reduction control
or the second temperature is reached during the second cold air reduction control.
Other examples of the method of cancelling the air volume restriction include the
following. For example, a plurality of first temperatures is set, including temperatures
1a, 1b, 1c, and Id in ascending order of temperature. When the temperature of the
indoor heat exchanger 16 becomes higher than the temperature la, the air volume restriction
in the first cold air reduction control is partially cancelled such that the first
or second air volume can be selected. When the temperature of the indoor heat exchanger
16 becomes higher than the temperature 1b, the air volume restriction in the first
cold air reduction control is further partially cancelled such that any of the first
to third air volumes can be selected. When the temperature of the indoor heat exchanger
16 becomes higher than the temperature 1c, the air volume restriction in the first
cold air reduction control is further partially cancelled such that any of the first
to fourth air volumes can be selected. Finally, when the temperature of the indoor
heat exchanger 16 becomes higher than the temperature Id, all the air volume restrictions
are further cancelled. As described above, for example, the air volume restrictions
may be cancelled stepwise.
[0058] The second cold air reduction control may also be cancelled stepwise. For example,
a plurality of second temperatures is set, including temperatures 2a and 2b. In this
case, the following relationship is satisfied, in terms of the temperature value:
the temperature 2a < the temperature 2b < the temperature 1a < the temperature 1b
< the temperature 1c < the temperature 1d. When the temperature of the indoor heat
exchanger 16 becomes higher than the temperature 2a, the air volume restriction in
the second cold air reduction control is partially cancelled such that any of the
first to third air volumes can be selected. Furthermore, when the temperature of the
indoor heat exchanger 16 becomes higher than the temperature 2b, all the air volume
restrictions in the second cold air reduction control are further cancelled.
[0059] Examples of the cancellation of the air volume restriction include a full cancellation
with which all the air volumes selectable by the user, in this case the first to fifth
air volumes, become selectable at once, and another full cancellation with which the
selectable air volumes increase stepwise until all the air volumes become finally
selectable. Examples of the cancellation of the air volume restriction also include
a partial cancellation with which only a part of the air volumes becomes selectable.
Examples of the partial cancellation include one with which only a part of the air
volumes becomes selectable at once and the cancellation process ends, and one with
which the selectable air volumes increase stepwise but a part of the air volumes remains
unselectable till the end.
(5) Characteristics
(5-1)
[0060] The air conditioner 1 of the above embodiment is configured to perform the first
cold air reduction control for restricting the air volume of the indoor fan 31 until
the temperature of the indoor heat exchanger 16 reaches the first temperature, and
the second cold air reduction control for cancelling the air volume restriction at
the indoor fan 31 when the temperature of the indoor heat exchanger 16 reaches the
second temperature lower than the first temperature. The control unit 50 is configured
to selectively perform the first cold air reduction control in order to preferentially
reduce the uncomfortable feeling due to cold air, or the second cold air reduction
control in order to preferentially promote a rise in room temperature. Therefore,
it is possible to preferentially reduce the uncomfortable feeling due to cold air
through the first cold air reduction control, and to preferentially promote a rise
in room temperature through the second cold air reduction control. As a result, the
air conditioner 1 of the present embodiment has enhanced effects of reducing the uncomfortable
feeling due to cold air and promoting a rise in room temperature as compared with
the conventional case.
[0061] In the above embodiment, the case where the air volume restriction is cancelled at
the first temperature has been described as an example of the first cold air reduction
control for restricting the air volume of the indoor fan 31 until the temperature
of the indoor heat exchanger 16 reaches the first temperature. However, the first
cold air reduction control only needs to restrict the air volume of the indoor fan
31 until the temperature of the indoor heat exchanger 16 reaches the first temperature.
The first cold air reduction control does not necessarily have to cancel the air volume
restriction at the first temperature.
(5-2)
[0062] The first cold air reduction control or the second cold air reduction control is
selected in accordance with a selection condition, i.e., the second start condition.
Therefore, this selection condition is set in advance such that the first cold air
reduction control is selected in order to preferentially reduce the uncomfortable
feeling due to cold air, whereas the second cold air reduction control is selected
in order to preferentially promote a rise in room temperature. For example, when the
horizontal flaps 64 and 65 are not in the state of the "ceiling flow" being selected
as the wind direction, the first cold air reduction control is selected. Meanwhile,
when the horizontal flaps 64 and 65 are in the state of the "ceiling flow" being selected
as the wind direction and another second start condition is satisfied, the second
cold air reduction control is selected. That is, the following selection is achieved.
When the horizontal flaps 64 and 65 are in the state of the "ceiling flow" being selected
as the wind direction and the uncomfortable feeling due to cold air can be sufficiently
reduced, the air volume restriction is cancelled at a low temperature by the second
cold air reduction control with which relatively cold conditioned air is blown out.
Meanwhile, when the horizontal flaps 64 and 65 are not in the state of the "ceiling
flow" being selected as the wind direction and it is difficult to sufficiently reduce
the uncomfortable feeling due to cold air, the air volume restriction is cancelled
at a high temperature by the first cold air reduction control. As a result, it is
easy to reduce the uncomfortable feeling due to cold air and to promote a rise in
room temperature.
(5-3)
[0063] In the case where the second start condition as the selection condition includes,
as the condition for selecting the second cold air reduction control, the condition
requiring that the temperature difference (Tt - Tr) between the target room temperature
Tt and the room temperature Tr be larger than the threshold, the second cold air reduction
control is not performed when the temperature difference is small and a capacity requirement
is low. When the temperature difference (Tt - Tr) is small, the user has less desire
to quickly raise the room temperature Tr. As described above, the second cold air
reduction control is not performed when the room RS is already warm and there is little
need to raise the room temperature quickly. As a result, it is possible to focus on
improving the effect of reducing the uncomfortable feeling due to cold air, thus improving
the user's comfort.
(5-4)
[0064] For example, in the case where the second start condition as the selection condition
for selecting the second cold air reduction control includes the condition requiring
that the horizontal flaps 64 and 65 not be swinging, the second cold air reduction
control is not performed while the horizontal flaps 64 and 65 are swinging to blow
out air to a wide range. Such control makes it possible to reduce conditioned air
being blown directly onto the user, even if the second cold air reduction control
is performed while the user is in the room RS. If control is performed for stopping
the swing of the horizontal flaps 64 and 65 in order to select the second cold air
reduction control, the user is very likely to mistake the stop for a malfunction.
It is possible to prevent such a mistake by performing control for not stopping the
swing under the condition for selecting the second cold air reduction control requiring
that the flaps not be swinging. Alternatively, the second start condition may include
a condition requiring that the vertical flaps 63 not be swinging, in addition to the
horizontal flaps 64 and 65. The horizontal flaps are not limited to the two horizontal
flaps 64 and 65, but may be one horizontal flap, or three or more horizontal flaps.
(5-5)
[0065] In the case where the second start condition as the selection condition for selecting
the second cold air reduction control includes the condition requiring that the horizontal
flaps 64 and 65 be oriented upward relative to the predetermined angle An1, the second
cold air reduction control is not performed when the horizontal flaps 64 and 65 are
oriented at, or downward relative to, the predetermined angle An1. Therefore, the
predetermined angle An1 is set to an angle at which the conditioned air is not blown
onto the user in the room RS. As a result, it is possible to reduce relatively cold
conditioned air being blown directly onto the user and to improve the function of
reducing the uncomfortable feeling due to cold air, even if the second cold air reduction
control is performed while the user is in the room RS.
(5-6)
[0066] In the case where the second start condition as the selection condition includes
the condition requiring that the horizontal flaps 64 and 65 be at predetermined angles
at which the conditioned air is blown out horizontally or upward relative to the horizontal
direction, the conditioned air is blown out horizontally or upward relative to the
horizontal direction when the second cold air reduction control is performed. As a
result, for example, the indoor unit 3 at a high position can be set such that the
conditioned air is not blown directly onto the user in the room even if the second
cold air reduction control is performed while the user is standing up, making it possible
to improve the function of reducing the uncomfortable feeling due to cold air.
(5-7)
[0067] In the case where the second start condition as the selection condition includes
the condition requiring that the horizontal flaps 64 and 65 be at predetermined angles
at which the conditioned air is blown out along the ceiling, the conditioned air is
blown out along the ceiling when the second cold air reduction control is performed.
As a result, it is possible to reduce the conditioned air being blown directly onto
the user in the room even if the second cold air reduction control is performed while
the user is standing up, making it possible to improve the function of reducing the
uncomfortable feeling due to cold air.
(6) Modifications
(6-1) Modification 1A
[0068] In the above embodiment, the case where the two types of cold air reduction control,
i.e., the first cold air reduction control and the second cold air reduction control
are performed has been described. Alternatively, however, another cold air reduction
control may be further performed. For example, third cold air reduction control may
be further performed, with which the air volume restriction at the indoor fan 31 is
cancelled when the temperature of the indoor heat exchanger 16 reaches a third temperature
lower than the second temperature. The third cold air reduction control is further
performed with which the air volume restriction at the indoor fan 31 is cancelled
when the temperature of the indoor heat exchanger 16 reaches the third temperature
lower than the second temperature. Therefore, it is possible to rapidly raise the
room temperature through the third cold air reduction control in a case of more preferentially
promoting a rise in room temperature than in the second cold air reduction control.
[0069] For example, the third cold air reduction control may be added to the control of
the air conditioner 1 as illustrated in FIG. 9, with the flowchart illustrated in
FIG. 8 partially changed. It is determined whether a third start condition has been
satisfied (step S11) between step S3 and step S4 of the flowchart of FIG. 8. If the
third start conditions has been satisfied, the third cold air reduction control is
started (step S12). If the third start condition has not been satisfied, on the other
hand, the processing proceeds to step S4, where the second cold air reduction control
is started, and then steps S2 to S5 are repeated in a loop.
[0070] When the third cold air reduction control is started, it is then determined whether
the temperature of the indoor heat exchanger 16 has reached the third temperature
(step S13). When the temperature of the indoor heat exchanger 16 reaches the third
temperature, the processing proceeds to step S14, where the air volume restriction
is cancelled. After the operation of step S14 is finished, the processing proceeds
to step S9. If the temperature of the indoor heat exchanger 16 has not reached the
third temperature, the processing proceeds to step S2. The operation after the processing
proceeds to step S9 or step S2 is the same as the already described corresponding
operation of the flowchart illustrated in FIG. 8, and thus will not be described again.
[0071] It is assumed here that the control unit 50 is programmed to perform control such
that the second start condition includes, for example, a condition requiring that
the wind direction be the "ceiling flow" or "upward flow", and the third start condition
includes, for example, a condition requiring that the wind direction be the "ceiling
flow". That is, the third cold air reduction control focuses on promoting a rise in
room temperature as compared with the second cold air reduction control. Therefore,
when the temperature of the indoor heat exchanger 16 reaches the third temperature
lower than the second temperature, the air volume restriction is cancelled such that,
for example, any of the first to fifth air volumes is selectable (step S14).
[0072] As described above, the air conditioner 1 can further perform the third cold air
reduction control with which the air volume restriction at the indoor fan 31 is cancelled
when the temperature of the indoor heat exchanger 16 reaches the third temperature
lower than the second temperature. This makes it possible to rapidly raise the room
temperature through the third cold air reduction control in a case of more preferentially
promoting a rise in room temperature than in the second cold air reduction control.
The third cold air reduction control is performed to improve the function of promoting
a rise in room temperature. Meanwhile, the third cold air reduction control is started
only in a case where it is easier to reduce the uncomfortable feeling due to cold
air than when starting the second cold air reduction control. It is thus possible
to achieve both reduction of the uncomfortable feeling due to cold air and promotion
of a rise in room temperature.
(6-2) Modification 1B
[0073] In the above embodiment, the air conditioner 1 is configured exclusively for heating.
Alternatively, as illustrated in FIGS. 10 and 11, the air conditioner 1 may further
include, for example, a four-way switching valve 12 such that heating and cooling
can be switched. In the air conditioner 1 configured as illustrated in FIG. 10, the
compressor 11 discharges refrigerant compressed inside the compressor 11 to a first
port of the four-way switching valve 12 from the discharge port of the compressor
11. The four-way switching valve 12 includes, in addition to the first port, a second
port connected to the outdoor heat exchanger 13, a third port connected to the accumulator
15, and a fourth port connected to the indoor heat exchanger 16. During the heating
operation of the air conditioner 1, the four-way switching valve 12 causes the refrigerant
to flow between the first port and the fourth port and simultaneously causes the refrigerant
to flow between the second port and the third port (as illustrated by the broken lines).
During the cooling operation and a reverse cycle defrost operation of the air conditioner
1, the four-way switching valve 12 causes the refrigerant to flow between the first
port and the second port and simultaneously causes the refrigerant to flow between
the third port and the fourth port (as illustrated by the solid lines).
[0074] In the case where the heating operation or the cooling operation can be selected
as described above, the first start condition of the flowchart illustrated in FIG.
8 only needs to include, for example as an AND condition, a condition requiring that
the heating operation be selected. Since the outdoor control device 26 controls the
four-way switching valve 12, the control unit 50 can obtain, from the outdoor control
device 26, information indicating which of the heating operation and the cooling operation
is currently being performed.
(6-3) Modification 1C
[0075] In the above embodiment, if the situation changes and the determination as to whether
the first start condition or the second start condition is satisfied changes during
the first cold air reduction control or the second cold air reduction control, the
cold air reduction control is allowed to change. However, the method of selecting
the first cold air reduction control or the second cold air reduction control is not
limited to the method of the above embodiment. For example, the flowchart may be partially
changed as illustrated in FIG. 12. In the flowchart illustrated in FIG. 12, when the
determination in steps S5 and S8 is "No", the processing returns to steps S4 and S7,
respectively. Once the first cold air reduction control or the second cold air reduction
control is started, each control is continued until the temperature of the indoor
heat exchanger 16 reaches the first temperature or the second temperature, respectively.
REFERENCE SIGNS LIST
[0076]
- 1
- Air conditioner
- 2
- Outdoor unit
- 3
- Indoor unit
- 10
- Refrigerant circuit
- 11
- Compressor
- 12
- Four-way switching valve
- 13
- Outdoor heat exchanger
- 14
- Expansion mechanism
- 16
- Indoor heat exchanger
- 21
- Outdoor fan
- 31
- Indoor fan
- 32
- Room temperature sensor
- 33
- Indoor heat exchanger temperature sensor
- 63
- Vertical flap
- 64, 65
- Horizontal flap
CITATION LIST
PATENT LITERATURE
1. Klimaanlage (1), umfassend:
einen Innenwärmetauscher (16), der konfiguriert ist, um Wärme zwischen Kältemittel
und Innenluft in einem Dampfkompressionskühlkreislauf auszutauschen;
einen Innenventilator (31), der konfiguriert ist, um ein Luftvolumen zu einem Zeitpunkt
zum Ausblasen, in einen Raum, klimatisierter Luft, die durch den Wärmeaustausch durch
den Innenwärmetauscher erhalten wird, zu ändern, wobei die Klimaanlage (1) so konfiguriert
ist, dass sie beim Starten der Erwärmung, eine erste Kaltluftreduzierungssteuerung
zum Durchführen einer Luftvolumenbegrenzung des Innenventilators (31), bis eine Temperatur
des Innenwärmetauschers (16) eine erste Temperatur erreicht, und eine zweite Kaltluftreduzierungssteuerung
zum Aufheben der Luftvolumenbegrenzung am Innenventilator (31), wenn die Temperatur
des Innenwärmetauschers (16) eine zweite Temperatur erreicht, die niedriger als die
erste Temperatur ist, durchführt, wobei die erste Kaltluftreduzierungssteuerung oder
die zweite Kaltluftreduzierungssteuerung gemäß einer voreingestellten Auswahlbedingung
ausgewählt wird; und
eine Klappe (63, 64, 65), die konfiguriert ist, um eine Richtung zum Ausblasen der
klimatisierten Luft aus dem Innenventilator (31) zu schwenken,
wobei die Klimaanlage dadurch gekennzeichnet ist, dass die Auswahlbedingung, als Bedingung für die Auswahl der zweiten Kaltluftreduzierungssteuerung,
eine Bedingung beinhaltet, die erfordert, dass die Klappe (63, 64, 65) nicht schwenkt.
2. Klimaanlage (1) nach Anspruch 1,
wobei die Auswahlbedingung, als Bedingung für die Auswahl der zweiten Kaltluftreduzierungssteuerung,
eine Bedingung beinhaltet, die erfordert, dass ein Unterschied zwischen einer Zielraumtemperatur
und einer Raumtemperatur größer als ein Schwellenwert ist.
3. Klimaanlage (1) nach einem der vorhergehenden Ansprüche, umfassend eine horizontale
Klappe (64, 65), die konfiguriert ist, um eine Auf-Ab-Richtung zum Ausblasen der klimatisierten
Luft aus dem Innenventilator (31) zu ändern,
wobei die Auswahlbedingung, als Bedingung für die Auswahl der zweiten Kaltluftreduzierungssteuerung,
eine Bedingung beinhaltet, die erfordert, dass die horizontale Klappe (64, 65) relativ
zu einem vorbestimmten Winkel nach oben ausgerichtet ist.
4. Klimaanlage (1) nach Anspruch 3,
wobei die Auswahlbedingung erfordert, dass der vorbestimmte Winkel der horizontalen
Klappe (64, 65) ein Winkel ist, in dem die klimatisierte Luft relativ zu einer horizontalen
Richtung horizontal oder nach oben ausgeblasen wird.
5. Klimaanlage (1) nach Anspruch 3,
wobei die Auswahlbedingung erfordert, dass der vorbestimmte Winkel der horizontalen
Klappe (64, 65) ein Winkel ist, in dem die klimatisierte Luft entlang einer Decke
ausgeblasen wird.
6. Klimaanlage (1) nach einem der Ansprüche 1 bis 7, die konfiguriert ist, um eine dritte
Kaltluftreduzierungssteuerung zum Aufheben der Luftvolumenbegrenzung am Innenventilator
(31) weiter durchzuführen, wenn die Temperatur des Innenwärmetauschers (16) eine dritte
Temperatur erreicht, die niedriger als die zweite Temperatur ist.
7. Klimaanlage (1), umfassend:
einen Innenwärmetauscher (16), der konfiguriert ist, um Wärme zwischen Kältemittel
und Innenluft in einem Dampfkompressionskühlkreislauf auszutauschen;
einen Innenventilator (31), der konfiguriert ist, um ein Luftvolumen zu einem Zeitpunkt
zum Ausblasen, in einen Raum, klimatisierter Luft, die durch den Wärmeaustausch durch
den Innenwärmetauscher erhalten wird, zu ändern, wobei die Klimaanlage (1) so konfiguriert
ist, dass sie beim Starten der Erwärmung, eine erste Kaltluftreduzierungssteuerung
zum Durchführen einer Luftvolumenbegrenzung des Innenventilators (31), bis eine Temperatur
des Innenwärmetauschers (16) eine erste Temperatur erreicht, und eine zweite Kaltluftreduzierungssteuerung
zum Aufheben der Luftvolumenbegrenzung am Innenventilator (31), wenn die Temperatur
des Innenwärmetauschers (16) eine zweite Temperatur erreicht, die niedriger als die
erste Temperatur ist, durchführt, wobei die erste Kaltluftreduzierungssteuerung oder
die zweite Kaltluftreduzierungssteuerung gemäß einer voreingestellten Auswahlbedingung
ausgewählt wird; und
eine horizontale Klappe (64, 65), die konfiguriert ist, um eine Auf-Ab-Richtung zum
Ausblasen der klimatisierten Luft aus dem Innenventilator (31) zu ändern, wobei die
Klimaanlage dadurch gekennzeichnet ist, dass die Auswahlbedingung, als Bedingung für die Auswahl der zweiten Kaltluftreduzierungssteuerung,
eine Bedingung beinhaltet, die erfordert, dass die horizontale Klappe (64, 65) relativ
zu einem vorbestimmten Winkel nach oben ausgerichtet ist.
8. Klimaanlage (1) nach Anspruch 7,
wobei die Auswahlbedingung erfordert, dass der vorbestimmte Winkel der horizontalen
Klappe (64, 65) ein Winkel ist, in dem die klimatisierte Luft relativ zu einer horizontalen
Richtung horizontal oder nach oben ausgeblasen wird.
9. Klimaanlage (1) nach Anspruch 7,
wobei die Auswahlbedingung erfordert, dass der vorbestimmte Winkel der horizontalen
Klappe (64, 65) ein Winkel ist, in dem die klimatisierte Luft entlang einer Decke
ausgeblasen wird.
1. Climatiseur (1), comprenant :
un échangeur de chaleur intérieur (16) configuré pour échanger de la chaleur entre
le réfrigérant et l'air intérieur dans un cycle de réfrigération à compression de
vapeur ;
un ventilateur intérieur (31) configuré pour changer un volume d'air à un moment de
soufflage, dans une pièce, d'air conditionné obtenu par l'échange de chaleur par l'échangeur
de chaleur intérieur,
dans lequel le climatiseur (1) est configuré pour effectuer, lors du démarrage du
chauffage, une première commande de réduction d'air froid pour effectuer une restriction
du volume d'air du ventilateur intérieur (31) jusqu'à ce qu'une température de l'échangeur
de chaleur intérieur (16) atteigne une première température, et une deuxième commande
de réduction d'air froid pour annuler la restriction du volume d'air en correspondance
du ventilateur intérieur (31) lorsque la température de l'échangeur de chaleur intérieur
(16) atteint une deuxième température inférieure à la première température, dans lequel
la première commande de réduction d'air froid ou la deuxième commande de réduction
d'air froid est sélectionnée selon une condition de sélection prédéfinie ; et
un volet (63, 64, 65) configuré pour basculer une direction de soufflage de l'air
conditionné du ventilateur intérieur (31),
le climatiseur étant caractérisé en ce que la condition de sélection comprend, comme condition de sélection de la deuxième commande
de réduction d'air froid, une condition exigeant que le volet (63, 64, 65) ne bascule
pas.
2. Climatiseur (1) selon la revendication 1,
dans lequel la condition de sélection comprend, comme condition de sélection de la
deuxième commande de réduction d'air froid, une condition exigeant qu'une différence
entre une température ambiante cible et une température ambiante soit supérieure à
un seuil.
3. Climatiseur (1) selon l'une quelconque des revendications précédentes, comprenant
un volet horizontal (64, 65) configuré pour changer une direction de haut en bas de
soufflage de l'air conditionné du ventilateur intérieur (31),
dans lequel la condition de sélection comprend, comme condition de sélection de la
seconde commande de réduction d'air froid, une condition exigeant que le volet horizontal
(64, 65) soit orienté vers le haut par rapport à un angle prédéterminé.
4. Climatiseur (1) selon la revendication 3,
dans lequel la condition de sélection exige que l'angle prédéterminé du volet horizontal
(64, 65) soit un angle auquel l'air conditionné est soufflé horizontalement ou vers
le haut par rapport à une direction horizontale.
5. Climatiseur (1) selon la revendication 3,
dans lequel la condition de sélection exige que l'angle prédéterminé du volet horizontal
(64, 65) soit un angle auquel l'air conditionné est soufflé le long d'un plafond.
6. Climatiseur (1) selon l'une quelconque des revendications 1 à 7, étant configuré pour
effectuer de plus une troisième commande de réduction d'air froid pour annuler la
restriction du volume d'air en correspondance du ventilateur intérieur (31) lorsque
la température de l'échangeur de chaleur intérieur (16) atteint une troisième température
inférieure à la deuxième température.
7. Climatiseur (1), comprenant :
un échangeur de chaleur intérieur (16) configuré pour échanger de la chaleur entre
le réfrigérant et l'air intérieur dans un cycle de réfrigération à compression de
vapeur ;
un ventilateur intérieur (31) configuré pour changer un volume d'air à un moment de
soufflage, dans une pièce, de l'air conditionné obtenu par l'échange de chaleur par
l'échangeur de chaleur intérieur,
dans lequel le climatiseur (1) est configuré pour effectuer, lors du démarrage du
chauffage, une première commande de réduction d'air froid pour effectuer une restriction
du volume d'air du ventilateur intérieur (31) jusqu'à ce qu'une température de l'échangeur
de chaleur intérieur (16) atteigne une première température, et une deuxième commande
de réduction d'air froid pour annuler la restriction du volume d'air en correspondance
du ventilateur intérieur (31) lorsque la température de l'échangeur de chaleur intérieur
(16) atteint une deuxième température inférieure à la première température, dans lequel
la première commande de réduction d'air froid ou la deuxième commande de réduction
d'air froid est sélectionnée selon une condition de sélection prédéfinie ; et
un volet horizontal (64, 65) configuré pour changer une direction de haut en bas de
soufflage de l'air conditionné du ventilateur intérieur (31),
le climatiseur étant caractérisé en ce que la condition de sélection comprend, comme condition de sélection de la deuxième commande
de réduction d'air froid, une condition exigeant que le volet horizontal (64, 65)
soit orienté vers le haut par rapport à un angle prédéterminé.
8. Climatiseur (1) selon la revendication 7,
dans lequel la condition de sélection exige que l'angle prédéterminé du volet horizontal
(64, 65) soit un angle auquel l'air conditionné est soufflé horizontalement ou vers
le haut par rapport à une direction horizontale.
9. Climatiseur (1) selon la revendication 7,
dans lequel la condition de sélection exige que l'angle prédéterminé du volet horizontal
(64, 65) soit un angle auquel l'air conditionné est soufflé le long d'un plafond.