JP7422314B2 - air conditioner - Google Patents

Description

The present disclosure relates to an air conditioner.

Cited document 1 discloses a refrigerant detection air path whose both ends are connected to a main air path from an inlet to an outlet of an indoor unit of an air conditioner, and a refrigerant detection sensor that detects refrigerant inside the refrigerant detection air path. , the refrigerant detection air path is installed in the main air path and communicates between the air outlet side and the intake side of the blower that sends air from the inlet to the air outlet, and A refrigerant detection device is disclosed that can detect leaked refrigerant by guiding air outside a main air path within a housing.

WO2018/198165

Therefore, the present disclosure provides an air conditioner that can detect leaked refrigerant on the heat exchanger room side with high accuracy.

The present disclosure includes: a casing in which an inlet for air to flow in and an outlet for air to flow out; a partition wall for partitioning the inside of the casing into a heat exchanger chamber having a heat exchanger; An air conditioner including a refrigerant detection duct that communicates between a ventilation chamber and the heat exchanger chamber, and a refrigerant detection sensor that detects a refrigerant in the refrigerant detection duct, and a scroll casing in which a fan opening is formed; one end of the refrigerant detection duct, comprising: a sirocco fan housed in the scroll casing; and an air passage that discharges air sucked in from the fan opening by rotation of the sirocco fan toward the heat exchanger chamber; is an opening on the side of the ventilation chamber disposed in the ventilation chamber, and the other end of the refrigerant detection duct is an opening on the side of the heat exchanger chamber disposed in the heat exchanger chamber, and the other end of the refrigerant detection duct is an opening on the side of the heat exchanger chamber disposed in the heat exchanger chamber, and When viewed from above, the blowing chamber side opening is arranged within the area of the fan opening and in an area closer to the suction port than the rotating shaft.

According to the present disclosure, leaked refrigerant on the heat exchanger room side can be detected with high accuracy.

A side sectional view showing an air conditioner according to Embodiment 1 A plan view showing an air conditioner according to Embodiment 1

(Findings, etc. that formed the basis of this disclosure)
At the time when the inventors came up with the present disclosure, the refrigerant detection device included a refrigerant detection air path connected at both ends to a main air path from an inlet to an outlet of an indoor unit of an air conditioner; a refrigerant detection sensor that detects a refrigerant inside the detection air path, and the refrigerant detection air path is connected to the air outlet side of a blower that is installed in the main air path and sends air from the inlet to the outlet. There is a technology that detects refrigerant by communicating with the mouth side.

In the conventional technology, the inlet of the refrigerant detection air path is disposed at the outlet of the indoor unit, and the outlet is disposed at the inlet of the indoor unit. When the blower is driven, the pressure on the suction side tends to be lower than the pressure on the blower outlet side, so due to the pressure difference, the air on the blower outlet side flows through the refrigerant detection air path to the suction port side. It becomes easier.
However, not all areas in the space on the inlet side of the indoor unit have negative pressure, and there are cases where a differential pressure between the outlet side and the inlet side does not occur, which reduces the accuracy of refrigerant detection. The inventors discovered this, and in order to solve the problem, they have constituted the subject matter of the present disclosure.
Therefore, the present disclosure provides an air conditioner that can detect leaked refrigerant on the heat exchanger room side with high accuracy.

Hereinafter, embodiments will be described in detail with reference to the drawings. However, more detailed explanation than necessary may be omitted. For example, detailed explanations of well-known matters or redundant explanations of substantially the same configurations may be omitted. This is to avoid making the following description unnecessarily redundant and to facilitate understanding by those skilled in the art.
The accompanying drawings and the following description are provided to enable those skilled in the art to fully understand the present disclosure, and are not intended to limit the subject matter recited in the claims.

(Embodiment 1)
Embodiment 1 will be described below with reference to FIGS. 1 and 2.
FIG. 1 is a side cross-sectional view of an air conditioner in Embodiment 1. FIG. 2 is a plan view of the air conditioner according to the first embodiment.

[1-1. composition]
As shown in FIGS. 1 and 2, the air conditioner 1 in this embodiment includes a box-shaped housing 10. The housing 10 includes a top plate 11 and a bottom plate 12.
The left side of the housing 10 in FIG. 1 is a ventilation chamber 13, and the right side of the housing 10 in FIG. 1 is a heat exchanger chamber 14 that accommodates a heat exchanger 20. The ventilation chamber 13 and the heat exchanger chamber 14 are partitioned by a partition wall 15.

A suction port 16 for taking in indoor air is provided at the rear of the ventilation chamber 13, and a plurality of (three in this embodiment) scroll casings 31 each housing a sirocco fan 30 is provided inside the ventilation chamber 13. is provided. An air outlet 17 is provided in the heat exchanger chamber 14 on the front side of the heat exchanger 20 .
The scroll casing 31 is formed at both ends of the scroll casing 31, and has a fan opening 32 that sucks air flowing in from the suction port 16 due to the rotation of the sirocco fan 30, and a fan opening 32 that sucks the air sucked in from the fan opening 32 into the heat exchanger chamber. 14.
An electric motor 34 is provided between the scroll casings 31. The electric motor 34 is connected to a rotating shaft 35 of the sirocco fan 30 and drives the sirocco fan 30 to rotate.

The sirocco fan 30 is a centrifugal fan, and when the sirocco fan 30 is operated, air is sucked in from the suction port 16, is caused to flow into the inside of the scroll casing 31 from the direction of the rotating shaft 35 through the fan opening 32, and is drawn from the air passage 33. The conditioned air that is blown out to the heat exchanger 20 and heat exchanged with the heat exchanger 20 is discharged into the room from the outlet 17.
A drain pan 21 is disposed below the heat exchanger 20 housed in the heat exchanger chamber 14 in FIG.

Further, in the present embodiment, the heat exchanger chamber 14 includes a heat exchange region 22 of the heat exchanger 20 and a header region 23 which is at both ends of the heat exchanger 20 and to which the refrigerant pipes 24 are connected. A partition plate 25 is provided.
A refrigerant suction duct 41 is provided in the heat exchanger chamber 14 . The refrigerant suction duct 41 extends in the width direction of the heat exchanger chamber 14, and the heat exchanger chamber side openings 42 at both ends of the refrigerant suction duct 41 are configured to communicate from each partition plate 25 to the header region 23. has been done.

A branch duct 43 is connected to a midway portion of the refrigerant suction duct 41 located in the heat exchange area 22 . The branch duct 43 extends into the ventilation chamber 13 through the partition wall 15.
In this embodiment, the refrigerant detection duct 40 is composed of the refrigerant suction duct 41 and the branch duct 43.
Note that the refrigerant detection duct 40 may be configured to communicate between either the heat exchange area 22 or the header area 23 and the ventilation chamber 13.

In this embodiment, the branch duct 43 extends downward along the partition wall 15 in the vicinity of the partition wall 15, extends along the bottom surface of the ventilation chamber 13, and extends toward the ventilation chamber 13 side of the branch duct 43. The end portion extends upward from below the sirocco fan 30, and its ventilation chamber side opening 44 is open upward.
In this embodiment, branch duct 43 is arranged between two scroll casings 31 in an area where electric motor 34 is not installed. That is, the position between the fan openings 32 of the two scroll casings 31 has a more negative pressure than the space between the scroll casings 31 and the side wall of the housing 10, so that the refrigerant in the branch duct 43 flows through the fan openings 32. It is more likely to be discharged.
Note that the branch duct 43 may be arranged at a location other than between the scroll casings 31.

A refrigerant trap 45 having an internal volume larger than the inner diameter of the branch duct 43 is formed in the middle of the branch duct 43 .
A refrigerant detection sensor 46 is arranged in the refrigerant trap 45 to detect refrigerant.
Note that the installation position of the refrigerant detection sensor 46 can be set as appropriate, but since the refrigerant is heavier than air, it is preferable to install it at the lowest position of the branch duct 43.

In the present embodiment, when viewed from the direction of the rotation axis 35 of the sirocco fan 30, the ventilation chamber side opening 44 of the branch duct 43 is defined by a virtual vertical line ( It is arranged in an area that overlaps with the area of the semicircular part on the side of the suction port 16 (shown by a dashed line in FIG. 1).

Preferably, the ventilation chamber side opening 44 is arranged at the peripheral edge of the fan opening 32 when viewed from the direction of the rotation axis 35 of the sirocco fan 30.
When the sirocco fan 30 is driven to rotate, the peripheral edge of the fan opening 32 has a more negative pressure than the center where the rotating shaft 35 is located, so the refrigerant flows out from the ventilation chamber side opening 44. It becomes easier.
In this case, when viewed from the direction of the rotation axis 35 of the sirocco fan 30, the blowing chamber side opening 44 may be arranged near the end of the fan opening 32 on the suction port 16 side.
Thereby, the refrigerant in the branch duct 43 is easily discharged to the ventilation chamber side opening 44.

Furthermore, preferably, the opening 44 on the side of the ventilation chamber of the branch duct 43 is located at a position on the bottom plate of the housing 10 that is closer to the virtual horizontal line passing through the rotating shaft 35 of the sirocco fan 30 in the fan opening 32 (shown by a two-dot chain line in FIG. 1). It is placed in an area that overlaps with the area on the 12th side.
Generally, in the region below the imaginary horizontal line passing through the rotation axis 35, the direction of rotation of the sirocco fan 30 and the main direction of the air sucked in from the suction port 16 are opposite to each other. The flow collides with the mainstream air flow, preventing air from entering the fan opening 32.
Therefore, by arranging the opening 44 on the side of the ventilation chamber of the branch duct 43 in an area that overlaps with the area on the bottom plate 12 side of the housing 10 rather than the virtual horizontal line passing through the rotation axis 35, the branch duct 43 is able to direct the air in the sirocco fan 30. It can also act as a bulkhead to prevent collisions. As a result, the negative pressure space in the area below the fan opening 32 can be expanded, the inflow of refrigerant from the refrigerant detection duct 40 can be promoted, and the suction of mainstream air from the fan opening 32 can also be promoted. .

Note that the ventilation chamber side opening 44 may be arranged in an area that overlaps with the area on the top plate 11 side of the housing 10 rather than the virtual horizontal line passing through the rotation axis 35 of the sirocco fan 30.
In the region closer to the top plate 11 than the imaginary horizontal line, the flow of the main flow and the rotation direction of the sirocco fan 30 are in the same direction, so the speed of suction of the main flow into the fan opening 32 increases, and negative pressure is likely to occur. By arranging the ventilation chamber side opening 44 at this location, air flows smoothly into the refrigerant detection duct 40, so that in the event of a refrigerant leak, the refrigerant detection sensor 46 can quickly detect the leaked refrigerant.
That is, it is most preferable that the ventilation chamber side opening 44 be arranged at the peripheral edge of the fan opening 32 and at a position slightly closer to the top surface than the end of the fan opening 32 on the suction port 16 side.

Further, since the sirocco fan 30 rotates clockwise in the figure, the blowing chamber side opening 44 is arranged at the peripheral edge of the fan opening 32 and is provided facing upward, so that the refrigerant flow direction of the blowing chamber side opening 44 is The direction of rotation of the sirocco fan 30 can be made to substantially match the direction of rotation of the sirocco fan 30, and thereby the refrigerant leaking from the branch duct 43 can be smoothly sucked into the fan opening 32.

Further, the heat exchanger room side opening 42 of the refrigerant detection duct 40 is arranged such that its height is located at the top of the bank portion 26 of the drain pan 21. Thereby, it is possible to suppress the drain water accumulated in the drain pan 21 from flowing into the refrigerant detection duct 40 from the heat exchanger room side opening 42.
Furthermore, the heat exchanger room side opening 42 is arranged at a position lower than the lower edge of the air outlet 17 of the housing 10 . Since R32 refrigerant has a higher specific gravity than air, when refrigerant leakage occurs, the leaked refrigerant stays near the bottom plate. In addition, the air blown out from the outlet 17 does not flow near the bottom plate of the heat exchanger chamber 14, and the air remains there. Therefore, by arranging the heat exchanger room side opening 42 at a position lower than the lower edge of the air outlet 17 of the housing 10, the influence of the air blown out from the air outlet 17 is reduced, and the leaked refrigerant is transferred to the heat exchanger room. It can be made easier to flow into the side opening 42.

[1-2. Effect】
Next, the operation of this embodiment will be explained.
By driving the electric motor 34 to rotationally drive the sirocco fan 30, air is taken in from the suction port 16, and this air flows into the inside of the scroll casing 31 from the direction of the rotating shaft 35 through the fan opening 32, The conditioned air that is blown from the air passage 33 to the heat exchanger 20 and heat exchanged with the heat exchanger 20 is discharged from the air outlet 17.

Since the vicinity of the opening 44 on the side of the ventilation chamber of the branch duct 43 is under negative pressure, when leakage of refrigerant occurs in the heat exchanger chamber 14, the leaked refrigerant in the heat exchanger chamber 14 is transferred to the side of the heat exchanger chamber. It is sucked in through the opening 42 and flows through the refrigerant duct and the branch duct 43 to the ventilation chamber side opening 44 .
In this case, the refrigerant can be detected by the refrigerant detection sensor 46 housed in the housing part in the middle of the branch duct 43.

In addition, since the heat exchanger room side opening 42 is arranged at a lower position than the air outlet 17, if refrigerant leaks while the sirocco fan 30 is stopped, the refrigerant is heavier than air. Before leaking from the blow-off port 17, the refrigerant enters the heat exchanger chamber side opening 42 and accumulates in the refrigerant trap 45.
Thereby, even when the sirocco fan 30 is stopped, leaked refrigerant can be sent to the refrigerant detection sensor 46, and refrigerant leakage can be detected.

[1-3. Effects, etc.]
As described above, according to the present embodiment, the refrigerant detection duct 40 has both ends open to the heat exchanger chamber 14 and the ventilation chamber 13, respectively, and the refrigerant detection sensor that detects the refrigerant inside the refrigerant detection duct 40. 46, and the blowing chamber side opening 44 of the refrigerant detection duct 40 is located on the suction port 16 side with respect to the imaginary vertical line passing through the rotation axis 35 of the fan opening 32 when viewed from the direction of the rotation axis 35 of the sirocco fan 30. It is arranged in an area that overlaps with the area of the semicircular part.
Thereby, the vicinity of the ventilation chamber side opening 44 of the refrigerant detection duct 40 can be maintained at negative pressure. Therefore, leaking refrigerant on the heat exchanger chamber 14 side can be detected with high accuracy.

Further, according to the present embodiment, the blowing chamber side opening 44 of the refrigerant detection duct 40 is arranged at the peripheral edge of the fan opening 32 when viewed from the direction of the rotation axis 35 of the sirocco fan 30.
As a result, when the sirocco fan 30 is driven to rotate, the fan opening 32 has a more negative pressure at the periphery than at the center where the rotating shaft 35 is located, so the refrigerant flows from the ventilation chamber side opening 44. becomes easily leaked. Therefore, the leaked refrigerant from the refrigerant detection duct 41 can be smoothly sucked into the fan opening 32.

Further, according to the present embodiment, the ventilation chamber side opening 44 of the refrigerant detection duct 40 opens toward the top plate 11 of the housing 10 .
Thereby, by providing the ventilation chamber side opening 44 facing upward, the refrigerant flow direction of the ventilation chamber side opening 44 and the rotation direction of the sirocco fan 30 can be made to substantially match. Therefore, the leaked refrigerant from the refrigerant detection duct 40 can be smoothly sucked into the fan opening 32.

Further, according to the present embodiment, the blowing chamber side opening 44 of the refrigerant detection duct 40 is arranged in an area that overlaps with an area of the fan opening 32 that is closer to the bottom plate 12 of the housing 10 than the rotation axis 35 of the sirocco fan 30. has been done.
As a result, the refrigerant detection duct 40 prevents air collisions in the sirocco fan 30 by arranging the ventilation chamber side opening 44 of the branch duct 43 in an area that overlaps with the area on the bottom plate 12 side of the housing 10 rather than the rotating shaft 35. It can also play the role of a protective barrier. Therefore, the negative pressure space in the area below the fan opening 32 can be expanded, and the inflow of refrigerant from the refrigerant detection duct 40 can be promoted, and the suction of mainstream air from the fan opening 32 can also be promoted.

Further, according to the present embodiment, when viewed from the direction of the rotation axis 35 of the sirocco fan 30, the blower chamber side opening 44 of the refrigerant detection duct 40 is arranged near the end of the fan opening 32 on the suction port 16 side. ing.
Thereby, by arranging the ventilation chamber side opening 44 near the end of the fan opening 32 on the suction port 16 side, the refrigerant flow direction of the ventilation chamber side opening 44 and the rotation direction of the sirocco fan 30 can be made to substantially match. Can be done. Therefore, the refrigerant in the branch duct 43 is easily discharged to the ventilation chamber side opening 44.

Further, according to the present embodiment, the blowing chamber side opening 44 of the refrigerant detection duct 40 is arranged in an area that overlaps with an area closer to the top plate 11 of the casing 10 than the rotating shaft 35 of the sirocco fan 30.
By arranging the ventilation chamber side opening 44 in an area closer to the top plate 11 than the rotating shaft 35 of the sirocco fan 30, the mainstream suction speed to the fan opening 32 increases, making it easier to generate negative pressure. can do. Therefore, the refrigerant easily flows into the fan opening 32.

Further, according to the present embodiment, the sirocco fan 30 includes a plurality of scroll casings 31, and the blowing chamber side opening 44 of the refrigerant detection duct 40 is arranged in a region between the plurality of fan casings.
As a result, the position between the fan openings 32 of the two scroll casings 31 has a more negative pressure than the space between the scroll casing 31 and the side wall of the housing 10, so the pressure near the ventilation chamber side opening 44 becomes more negative. It can be done. Therefore, the refrigerant in the refrigerant detection duct 40 can be easily discharged to the fan opening 32.

Further, according to the present embodiment, the height of the heat exchanger room side opening 42 of the refrigerant detection duct 40 is placed higher than the top of the bank portion 26 of the drain pan 21 provided in the housing 10. There is.
Thereby, it is possible to suppress the drain water accumulated in the drain pan 21 from flowing into the refrigerant detection duct 40 from the heat exchanger room side opening 42.

Further, according to the present embodiment, a refrigerant trap 45 is formed in the middle of the refrigerant detection duct 40, and a refrigerant detection sensor 46 is disposed in the refrigerant trap 45.
Thereby, leaked refrigerant can be stored in the refrigerant trap 45 even when the sirocco fan 30 is stopped. Therefore, refrigerant leakage can be detected even when the sirocco fan 30 is stopped.

Note that the above-described embodiments are for illustrating the technology of the present disclosure, and therefore various changes, substitutions, additions, omissions, etc. can be made within the scope of the claims or equivalents thereof.

As described above, when refrigerant leaks in the heat exchanger room, the air conditioner according to the present invention draws the leaked refrigerant into the refrigerant detection duct by maintaining negative pressure near the opening on the side of the ventilation chamber. Therefore, it can be suitably used in an air conditioner in which refrigerant leakage can be detected with a refrigerant detection sensor provided in a refrigerant detection duct.

1 Air conditioner 10 Housing 11 Top plate 12 Bottom plate 13 Blow room 14 Heat exchanger room 15 Partition wall 16 Inlet 17 Outlet 20 Heat exchanger 21 Drain pan 22 Heat exchange area 23 Header area 24 Refrigerant piping 25 Partition plate 26 Bank Part 30 Sirocco fan 31 Scroll casing 32 Fan opening 33 Air blowing path 34 Electric motor 35 Rotating shaft 40 Refrigerant detection duct 41 Refrigerant suction duct 42 Heat exchanger room side opening 43 Branch duct 44 Air blowing room side opening 45 Refrigerant trap 46 Refrigerant detection sensor

Claims (9)

a casing in which an inlet for air to flow in and an outlet for air to flow out;
a partition wall that partitions the inside of the casing into a ventilation chamber and a heat exchanger chamber having a heat exchanger;
a refrigerant detection duct that communicates the ventilation chamber and the heat exchanger chamber;
An air conditioner comprising: a refrigerant detection sensor that detects refrigerant in the refrigerant detection duct;
a scroll casing in which a fan opening is formed; a sirocco fan housed in the scroll casing; and an air passage that discharges air sucked in from the fan opening toward the heat exchanger chamber by rotation of the sirocco fan. and,
One end of the refrigerant detection duct is an opening on the side of the ventilation chamber disposed within the ventilation chamber,
The other end of the refrigerant detection duct is a heat exchanger room side opening arranged in the heat exchanger room,
An air conditioner characterized in that the ventilation chamber side opening is disposed within a region of the fan opening and in a region closer to the suction port than the rotation shaft when viewed from the direction of the rotation axis of the sirocco fan. The air conditioner according to claim 1, wherein the blowing chamber side opening of the refrigerant detection duct is arranged at a peripheral edge of the fan opening when viewed from the rotation axis direction of the sirocco fan. The air conditioner according to claim 1, wherein the blower chamber side opening of the refrigerant detection duct opens toward a top plate of the housing. 3. The blowing chamber side opening of the refrigerant detection duct is arranged in an area of the fan opening that overlaps with an area closer to the bottom plate of the housing than the rotation axis of the sirocco fan. Air conditioner described in. 4 . Viewed from the direction of the rotation axis of the sirocco fan, the blower chamber side opening of the refrigerant detection duct is arranged near the suction port side end of the fan opening. 4 . Air conditioner described in. The air blowing chamber side opening of the refrigerant detection duct is arranged in an area that overlaps with an area closer to the top plate of the housing than the rotation axis of the sirocco fan. harmonizer. The sirocco fan includes a plurality of the scroll casings,
The air conditioner according to claim 1, wherein the blowing chamber side opening of the refrigerant detection duct is arranged in a region between the plurality of scroll casings. 2. The air filter according to claim 1, wherein the height of the opening of the refrigerant detection duct on the side of the heat exchanger room is located at a higher position than the top of the bank of a drain pan provided in the casing. harmonizer. The air conditioner according to claim 1, wherein a refrigerant trap is formed in the middle of the refrigerant detection duct, and the refrigerant detection sensor is disposed in the refrigerant trap.

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