JP2023071327A - indoor unit - Google Patents

Abstract

To provide an indoor unit capable of mounting a refrigerant sensor in a limited space.SOLUTION: In an indoor unit 100 including a housing 101 for housing a heat exchanger 120 including a refrigerant pipe and a blower fan 115 inside, the heat exchanger 120 includes a pipe connection portion where refrigerant pipes through which a refrigerant flows, are connected with each other, the housing 101 is provided with an arrangement space S2 in which the pipe connection portion is disposed, and a front wall 101a surrounding the arrangement space S2 and extending along a longitudinal direction of the housing 101, and a refrigerant sensor 180 detecting the refrigerant, is disposed on the front wall 101a.SELECTED DRAWING: Figure 4

Description

The present disclosure relates to indoor units.

Patent Literature 1 discloses an indoor unit of a duct-type air conditioner capable of sufficiently cooling electrical components.
In this indoor unit, a partition plate is provided to divide the inside of the housing into left and right, one end of the partition plate is fixed to the back surface of the front plate, and a heat exchanger is provided on the pipe outlet side of the heat exchanger to hold the heat exchanger in a vertical position. A heat exchanger side plate is arranged, and one end of the heat exchanger side plate is fixed to the rear plate. Further, in this indoor unit, the other end of the heat exchanger side plate and the other end of the partition plate are fixed to each other, and the heat exchanger side plate and the partition plate are erected in a row to form a partition wall, and one side partitioned by the partition wall A blowing chamber for arranging a blower and a heat exchanger is formed on the side, and an electric component room is formed on the other side partitioned by the partition wall. In this indoor unit, an air passage is formed to lead air from the inside of the frame of the safety drain pan into the electrical component room and further guide air from the electrical component room to the blower chamber.

JP 2012-141069 A

The present disclosure provides an indoor unit in which a refrigerant sensor can be arranged in a limited space.

The present disclosure is an indoor unit including a housing that accommodates a heat exchanger having refrigerant pipes and a blower fan inside, wherein the heat exchanger has a pipe joint where the refrigerant pipes through which refrigerant flows are connected to each other. The housing is provided with an arrangement space in which the pipe connection portion is arranged, and a front wall facing the arrangement space and extending along the longitudinal direction of the housing, the front wall comprising: A refrigerant sensor for detecting refrigerant is provided.

According to the present disclosure, a refrigerant sensor is provided on a side wall extending along the longitudinal direction of the housing. Therefore, the refrigerant sensor can be arranged in a limited space of the housing.

The perspective view which looked at the indoor unit which concerns on Embodiment 1 from the front Front view of indoor unit The perspective view which shows the internal structure of an indoor unit The perspective view which shows the internal structure of an indoor unit Perspective view of the vent from above Plan view of the indoor unit viewed from above Plan view of the indoor unit viewed from below Front view of left side wall Perspective view of the side plate of the housing viewed from the front left Perspective view showing the piping room A perspective view of an indoor unit according to Embodiment 2

(Knowledge, etc. on which this disclosure is based)
At the time when the inventors came up with the present disclosure, an indoor unit of an air conditioner was provided with a housing provided with an electrical box and a blower chamber, and an air passage for guiding air from the electrical box to the blower chamber. There is a technology that enables effective cooling of heat-generating components existing in the electrical box by providing them in the housing. This indoor unit includes a housing and partition walls that partition the interior of the housing. Inside the housing, a blower chamber in which a blower and a heat exchanger are arranged is provided on one side of the partition wall, and an electrical box and a pipe connection part of the heat exchanger are arranged on the other side of the partition wall. A space is provided for

Some of such indoor units are provided with a refrigerant sensor for detecting the refrigerant in the space where the pipe connection portion is arranged. This refrigerant sensor is provided along with an electrical box, a drain pump, and the like on the side surface of the housing, which is positioned in the longitudinal direction, where the pipe connection portion is arranged.

However, in such an indoor unit, when the size of the housing is reduced, or when the electrical box is increased in size, the space for installing the refrigerant sensor on the side surface of the housing may be limited. The inventors have discovered and come to constitute the subject of this disclosure in order to solve that problem.
Therefore, the present disclosure provides an indoor unit in which a refrigerant sensor can be arranged in the limited space of the housing.

Hereinafter, embodiments will be described in detail with reference to the drawings. However, more detailed description than necessary may be omitted. For example, detailed descriptions of well-known matters or redundant descriptions of substantially the same configurations may be omitted. This is to avoid the following description from becoming more redundant than necessary and to facilitate understanding by those skilled in the art.
It should be noted that the accompanying drawings and the following description are provided to allow those skilled in the art to fully understand the present disclosure and are not intended to limit the claimed subject matter thereby.

(Embodiment 1)
Embodiment 1 will be described below with reference to FIGS. 1 to 10. FIG. In each figure, the symbol FR indicates the front of the indoor unit in a horizontally suspended state, the symbol UP indicates the upper side of the indoor unit, and the symbol LH indicates the left side of the indoor unit. In the following description, each direction is a direction along the directions of these indoor units.

[1-1. composition]
[1-1-1. Configuration of indoor unit]
FIG. 1 is a front perspective view of an indoor unit 100 according to the present embodiment.
The indoor unit 100 of the present embodiment is included in an air conditioner. In this air conditioner, a heat exchanger 120 (FIG. 3) housed in an indoor unit 100, a pressure reducing device such as a compressor and an electronic expansion valve housed in an outdoor unit, and an outdoor heat exchanger are connected by refrigerant pipes. a refrigeration cycle formed by An air conditioner air-conditions a predetermined space to be conditioned by circulating a refrigerant through the refrigeration cycle.
In the present embodiment, the refrigerant used in the air conditioner including the indoor unit 100 is a mildly flammable or combustible refrigerant such as R32.

The indoor unit 100 is a duct type indoor unit installed in a ceiling space, inside a wall, or under a floor. The indoor unit 100 is formed so that the arrangement direction of the air outlet 108 for blowing out the air to be conditioned can be changed so that the blowing direction can be changed according to the installation location. For this reason, for example, when blowing air in the horizontal direction, the indoor unit 100 is installed in a so-called flat suspended state in which the air outlet 108 is positioned on the side, as shown in FIG. 1 . Further, when air is blown upward, the indoor unit 100 is installed in a so-called vertically suspended state in which the air outlet is positioned upward.
In the following description, the vertical direction means the vertical direction when the indoor unit 100 is installed in a horizontally suspended state.

As shown in FIG. 1 , the indoor unit 100 includes a box-shaped housing 101 . The housing 101 has a flat rectangular parallelepiped shape with the longitudinal direction extending along the left-right direction.
The housing 101 includes a front wall 101a positioned forward, a rear wall 101b positioned rearward, a left side wall 101c positioned leftward, and a right side wall 101d positioned rightward. The four side walls of 101 are formed. The housing 101 includes a top panel 101e forming a top surface and a bottom panel 101f forming a bottom surface.
The housing 101 is provided with a fixture 101n. The indoor unit 100 is fixed to the ceiling via this fixture 101n.

FIG. 2 is a front view of the indoor unit 100. FIG. In FIG. 2, the decorative panel 102 is omitted.
As shown in FIG. 2, the front wall 101a is provided with an air outlet 108. As shown in FIG. The air outlet 108 is a rectangular opening extending along the left-right direction of the front wall 101a. The indoor unit 100 air-conditions the space to be conditioned by blowing off the air to be conditioned from the outlet 108 .

As shown in FIG. 1, in the present embodiment, indoor unit 100 includes decorative panel 102 covering front wall 101a. The decorative panel 102 is a panel for improving appearance, which is provided so as to face the space to be harmonized. In the indoor unit 100, the air to be conditioned that is blown out from the air outlet 108 is sent to the space to be conditioned through the panel air outlet 102a.

3 and 4 are perspective views showing the internal configuration of the indoor unit 100. FIG. 3 and 4 omit the decorative panel 102 and the top panel 101e.
As shown in FIGS. 3 and 4, a partition plate 103 is provided inside the housing 101 . The partition plate 103 is a plate-like member having a predetermined length dimension extending along the lateral direction of the housing 101 .
The internal space of the housing 101 is partitioned by a partition plate 103 into a fan chamber 105 located on the front side of the housing 101 and a heat exchanger chamber 107 located on the rear side of the housing 101 . Both ends of the partition plate 103 are respectively connected to the left side wall 101c and the right side wall 101d.

Two fans 110 are provided in the fan room 105 . Blower 110 of the present embodiment is a sirocco fan. Each blower 110 includes a blower fan 115 . Each blower fan 115 is connected to a fan motor 111 via a drive shaft 113 and is rotated by being driven by the fan motor 111 .

When each blower fan 115 is driven, each blower 110 causes the air in the blower chamber 105 to flow into the heat exchanger chamber 107 via each of the plurality of ventilation holes 103 a provided in the partition plate 103 . At this time, air flows into the fan chamber 105 from the outside of the housing 101 through the air intake 106 provided in the bottom panel 101f. This air passes through an intake duct connected to the intake port 106 and flows in from the space to be harmonized, the outdoors, or the like.
Note that the configuration of blower room 105 in the present embodiment is an example, and the number of blowers 110 and fan motors 111 is not limited to the above configuration.

The heat exchanger chamber 107 is the internal space of the housing 101 in which the heat exchanger 120 is housed.
A heat insulating material is provided in each of the front wall 101a, the left side wall 101c, and the right side wall 101d at portions facing the heat exchanger chamber 107. As shown in FIG. The heat insulating material is made of, for example, foamed polystyrene or the like, and is formed into a shape that does not interfere with various members, pipes, etc. housed in the heat exchanger chamber 107 .

A drain pan 121 is provided over the entire portion of the bottom panel 101f facing the heat exchanger chamber 107 . The drain pan 121 is a plate-shaped member that functions as a water receiving portion that receives drain water generated in the heat exchanger chamber 107 . The drain pan 121 is made of foamed polystyrene, for example. Both the drain pan 121 and the portion of the bottom panel 101f where the drain pan 121 is provided are detachable from the housing 101 .

The heat exchanger 120 is a utilization side heat exchanger that functions as an evaporator that evaporates the refrigerant supplied from the outdoor unit or a condenser that condenses the refrigerant.
The heat exchanger 120 of the present embodiment is a so-called fin-and-tube heat exchanger. The heat exchanger 120 has a plurality of metal fins joined to a copper refrigerant pipe, and has an elongated shape as a whole. It is formed in a flat plate shape.

The heat exchanger 120 is arranged such that its longitudinal direction extends along the lateral direction of the heat exchanger chamber 107 . The upper edge of the heat exchanger 120 arranged in this way is supported by the heat insulating material provided on the front wall 101a and the top panel 101e, and the lower edge of the heat exchanger 120 is located on the partition plate 103 side of the drain pan 121. supported by the point where Therefore, the heat exchanger 120 is arranged in the heat exchanger chamber 107 so as to be inclined from the front wall 101a side toward the partition plate 103 side from the upper edge toward the lower edge.
That is, the heat exchanger 120 is arranged such that the vertical direction is oblique with respect to the vertical direction of the partition plate 103 when the indoor unit 100 is viewed from the side. Therefore, the heat exchanger 120 is arranged so that one plane faces the partition plate 103 and the ventilation holes 103 a and the other plane faces the outlet 108 .

The heat exchanger 120 exchanges heat between the air sent from the blower chamber 105 and the refrigerant flowing from the external refrigerant pipe through the refrigerant pipe connector 150 . Thereby, the heat exchanger 120 functions as an evaporator during the cooling operation of the indoor unit 100 and functions as a condenser during the heating operation of the indoor unit 100 . The air that has exchanged heat with the refrigerant in heat exchanger 120 passes through outlet 108 and is blown out of housing 101 .
The drain pan 121 is provided so as to cover substantially the entire bottom surface of the heat exchanger 120 and receives drain water generated in the heat exchanger 120 .

FIG. 5 is a perspective view of the vent portion 140 viewed from above.
As shown in FIG. 5, a vent portion 140 is provided at the end portion of the heat exchanger 120 located on the right side wall 101d side.
The vent portion 140 is a pipe connection portion in which refrigerant pipes provided in the heat exchanger 120 are bent and connected to each other by welding or the like. The vent part 140 is provided over the entire vertical direction of the heat exchanger 120 . That is, the heat exchanger 120 has pipe connections at both ends in the longitudinal direction.

The vent part 140 is covered on the front wall 101a side by a mounting plate 141 at the end of the heat exchanger. The mounting plate 141 at the end of the heat exchanger is a plate-like member that covers the entire top-bottom direction of the heat exchanger 120 at the end of the heat exchanger 120 so as to cover the entire vent portion 140 . The mounting plate 141 at the end of the heat exchanger is supported at its upper edge by the heat insulating material provided on the front wall 101 a and the top panel 101 e and supported by the drain pan 121 at its lower edge. Further, the mounting plate 141 at the end of the heat exchanger is connected to the fins arranged at the end located on the right side wall 101d side of the heat exchanger 120, and supports the heat exchanger 120 from the front wall 101a side.

The right side wall 101d side of the vent part 140 is covered with a heat exchanger support plate 142 provided on the right side wall 101d. The heat exchanger support plate 142 is a plate-shaped member that covers the entire vertical direction of the heat exchanger 120 at the end of the heat exchanger 120 so as to cover the entire vent portion 140 . The edge of the heat exchanger support plate 142 located on the front wall 101a side is wholly connected to the mounting plate 141 at the end of the heat exchanger. Thereby, the vent portion 140 is arranged in the space surrounded by the heat exchanger end mounting plate 141 and the heat exchanger support plate 142 . The vent portion 140 is surrounded by the heat exchanger end mounting plate 141 and the heat exchanger support plate 142 , so that the inside of the housing 101 is separated from the front wall 101 a side.
Hereinafter, a space formed by being surrounded by the heat exchanger end mounting plate 141 and the heat exchanger support plate 142 and in which the vent portion 140 is arranged is referred to as an arrangement space S1.

The heat exchanger support plate 142 is provided with a refrigerant sensor 143 that detects refrigerant. The refrigerant sensor 143 has a sensor main body housed in a box. The refrigerant sensor 143 is arranged inside the arrangement space S1.
Accordingly, in the indoor unit 100, when the refrigerant leaks from the vent portion 140, the refrigerant sensor 143 can detect the leaked refrigerant.
Since refrigerant generally has a higher specific gravity than air, refrigerant sensor 143 is desirably arranged below heat exchanger support plate 142 , in other words, at a position close to drain pan 121 .

6 is a plan view of the indoor unit 100 viewed from above, and FIG. 7 is a plan view of the indoor unit 100 viewed from below. FIG. 6 omits the top panel 101e, and FIG. 7 omits the bottom panel 101f.
As shown in FIGS. 6 and 7, in the heat exchanger chamber 107, the heat exchanger 120 and the refrigerant pipe outside the indoor unit 100 are connected to the end located on the right side wall 101d side of the heat exchanger 120. A refrigerant pipe connection portion 150, which is a pipe connection portion to be connected, is provided.
The refrigerant pipe connection portion 150 includes a liquid connection pipe 155 and a gas connection pipe 157 . Both the liquid connection pipe 155 and the gas connection pipe 157 are refrigerant pipes. The liquid connection pipe 155 is connected to liquid refrigerant piping outside the indoor unit 100 , and the gas connection pipe 157 is connected to gas refrigerant piping outside the indoor unit 100 . The liquid connection pipe 155 and the gas connection pipe 157 each branch within the heat exchanger chamber 107 of the housing 101 and connect with the heat exchanger 120 .
Hereinafter, in the internal space of the housing 101, the space in which the refrigerant pipe connection portion 150 is arranged is referred to as an arrangement space S2.

The arrangement space S2 is provided at a corner of the housing 101 surrounded by the front wall 101a and the left side wall 101c.
In this embodiment, the left side wall 101 c is formed by the substrate supporting plate 131 and the side plate 151 .
The substrate support plate 131 is a plate-like member extending from the rear wall 101b of the left side wall 101c across the partition plate 103 to the heat exchanger chamber 107. As shown in FIG. The substrate support plate 131 includes a support portion 131a extending in the front-rear direction of the indoor unit 100, and bent portions 131b that are bent toward the outside of the housing 101 at both end portions in the front-rear direction of the support portion 131a. A substrate 133 is attached to the support portion 131a.
Furthermore, the board support plate 131 forms the electrical equipment box 130 by being covered with an electrical equipment cover 137 indicated by a two-dot chain line in FIG. That is, the board support plate 131 serves as the bottom surface of the electrical box 130 . Further, the substrate support plate 131 is located inside the housing 101 with respect to the side plate 151 . Therefore, the electrical box 130 is prevented from protruding outward from the side plate 151, and the space of the indoor unit 100 can be saved.
Further, the support portion 131 a of the substrate support plate 131 is located on the left side of the left end of the heat exchanger 120 . That is, the fan chamber 105 is provided to the left of the left end of the heat exchanger 120 .

The side plate 151 is a plate-shaped member connected to the substrate support plate 131 and extending to the front wall 101a. The side plate 151 has a side plate body portion 152 along the longitudinal direction of the indoor unit 100 and a bent portion 154 bent in two stages. The side plate body portion 152 of the side plate 151 is positioned outside the housing 101 with respect to the support portion 131 a of the substrate support plate 131 .
The bent portion 154 is provided at the rear end portion of the side plate body portion 152 . The bent portion 154 has an inner bent portion 154a bent inward in the left-right direction from the side plate body portion 152, and a rear bent portion 154b bent rearward from the inner bent portion 154a. The inner curved portion 154a is a surface in contact with the bent portion 131b, and the rear curved portion 154b is a surface in contact with the support portion 131a.
The left end of the partition plate 103 is connected to the rear curved portion 154b.

FIG. 8 is a front view of the left side wall 101c, and FIG. 9 is a perspective view of the side plate 151 viewed from the front left. In FIG. 9, the drain pump support plate 160 and the pipe support plate 168 are omitted.
As shown in FIG. 9, the bent portion 131b at the front end of the substrate support plate 131 is provided with a first opening 131c, and the inwardly curved portion 154a of the side plate 151 is provided with a second opening 154c. The first opening 131c and the second opening 154c overlap together to form an opening A, as shown in FIGS. The opening A communicates the interior of the electrical equipment box 130 with the heat exchanger chamber 107 . A wiring 135 connected to the substrate 133 is drawn into the heat exchanger chamber 107 by being inserted through the opening A. As shown in FIG.

As shown in FIG. 9, the side plate main body portion 152 is provided with a notch 153 that is an opening. A liquid connection pipe 155 and a gas connection pipe 157 extend to the outside of the housing 101 from the notch 153 . The notch 153 includes a first pressing portion 153c and a second pressing portion 153d, which are semicircular concave portions. A drain pump support plate 160 indicated by a dashed line in the drawing and a pipe support plate 168 indicated by a dashed line in the drawing are attached to the notch 153 . Furthermore, the lower part of the notch 153 is covered by a side plate lower panel 152a attached to the side plate 151. As shown in FIG.

As shown in FIG. 8 , the drain pump support plate 160 includes a drain pump support portion 161 and a drain water discharge portion 163 . The drain pump support portion 161 (broken line in the drawing) supports the drain pump 123 (chain line in the drawing) inside the heat exchanger chamber 107 via the notch 153 .
The drain pump 123 pumps up the drain water received by the drain pan 121 . The pumped-up drain water flows through a drain pipe 125 (a two-dot chain line in the figure) and a drain water discharge portion 163 in order, and is discharged from the outside of the housing 101 through a drain hose connected to the drain water discharge portion 163. .

The drain pump support plate 160 is detachably attached to the side plate body portion 152 . That is, when the drain pump support plate 160 is removed from the side plate main body portion 152, the drain pump 123 supported by the drain pump support plate 160 can be removed. Thereby, in the indoor unit 100, the drain pump 123 can be easily inspected or replaced.
Further, in the indoor unit 100, the worker can easily access the installation space S2 through the notch 153 by removing the drain pump support plate 160. FIG.

Further, as shown in FIGS. 8 and 9, the pipe support plate 168 includes a third holding portion 165 and a fourth holding portion 167. As shown in FIGS. Each of the third pressing portion 165 and the fourth pressing portion 167 is a semicircular concave portion.
The side plate 151 and the drain pump support plate 160 hold the liquid connection pipe 155 between the first pressing portion 153 c and the third pressing portion 165 . Also, the side plate 151 and the drain pump support plate 160 support the gas connection pipe 157 between the second pressing portion 153 d and the fourth pressing portion 167 .

The front wall 101a has a front panel 170 at the connecting portion with the left side wall 101c.
As shown in FIG. 2 , the front panel 170 includes a front portion 171 , mounting holes 173 , a mounting plate 175 and a heat exchanger support portion 177 .
The front part 171 faces the front of the housing 101 and is provided so as to be adjacent to the outlet 108 on the left side wall 101c side. The mounting hole 173 is a rectangular hole formed in the front portion 171 . The mounting plate 175 is attached to the front surface portion 171 by screw fastening so as to cover the mounting holes 173 . This mounting plate 175 is detachably provided from the front surface portion 171 .

The heat exchanger support portion 177 is a triangular portion formed by bending the front portion 171 toward the outlet 108 rearward. An upper edge of the heat exchanger support 177 is connected to the left front surface of the heat exchanger 120 . Thereby, the heat exchanger support portion 177 supports the left end of the heat exchanger 120 from the front wall 101a side.

The arrangement space S<b>2 is surrounded by the partition plate 103 , the substrate support plate 131 , the side plates 151 , the front surface portion 171 and the mounting plate 175 , and the heat exchanger support portion 177 .
The width dimension of the arrangement space S2 between the heat exchanger support portion 177 and the left side wall 101c in the left-right direction is determined by the width dimension of the heat exchanger 120 in the left-right direction. Also, the heat exchanger support portion 177 is provided independently of the substrate support plate 131 . Therefore, the horizontal width of the arrangement space S2 and the horizontal width of the fan chamber 105 determined by the arrangement of the substrate support plate 131 can be designed independently of each other. As a result, in the indoor unit 100, it becomes easy to achieve both securing of the installation space S2 and highly efficient air conditioning by widening the fan room 105. FIG.

FIG. 10 is a perspective view of the indoor unit 100 as seen from the rear.
As shown in FIG. 10 , a refrigerant sensor 180 and a sterilization unit 190 are attached to the inner side of the mounting plate 175 , that is, the surface of the mounting plate 175 located on the inner side of the housing 101 . Since the mounting plate 175 is arranged facing the arrangement space S2, the refrigerant sensor 180 and the sterilization unit 190 are arranged in the arrangement space S2. The refrigerant sensor 180 and the sterilization unit 190 can be removed from the housing 101 by removing the mounting plate 175 from the front surface portion 171 .
Like the refrigerant sensor 143, the refrigerant sensor 180 is a sensor that detects refrigerant, and the refrigerant sensor 180 has a sensor main body housed in a box. A wiring 135 is connected to the refrigerant sensor 180 , and is connected to the substrate 133 via the wiring 135 .
Refrigerant sensor 180 is attached to the lower part of the surface of mounting plate 175 that is the inner side of housing 101 .

A protruding piece 172 protruding from the mounting plate 175 is provided on the surface of the mounting plate 175 that is inside the housing 101 . The projecting piece 172 has a flat surface, and the flat surface is arranged to face the drain pan 121 . This plane is also provided with screw holes.
The refrigerant sensor 180 is provided with a mounting piece 182 . This mounting piece 182 has a flat surface provided with a screw hole.

Refrigerant sensor 180 has a flat surface of mounting piece 182 and a flat surface of protruding piece 172 that are in contact with each other. It is fixed to the mounting plate 175 . As described above, the plane of the projecting piece 172 faces the drain pan 121, so the screw head of the screw member 189 that fixes the refrigerant sensor 180 to the mounting plate 175 is arranged to face the drain pan 121 or the top panel 101e. be. In this embodiment, the screw head of the screw member 189 is arranged to face the drain pan 121 .
Thus, in the indoor unit 100, when the bottom panel 101f and the drain pan 121 are removed and the refrigerant sensor 180 is attached and detached from below the housing 101, the operator can easily attach and detach the screw member 189. can be done.

The sterilization unit 190 includes an electrostatic atomizer and an electrostatic atomizer substrate. An electrostatic atomizer is a device that generates mist containing charged fine particle water. Mist containing charged fine particle water can suppress viruses, molds, allergenic substances, and bacteria in the air, and can deodorize the air. The charged fine particle water contains active ingredients such as radicals that exhibit sterilizing action, deodorizing action, and the like. The mist generated by the electrostatic atomizer of the sterilization unit 190 flows to the blowout port 108 and flows out of the housing 101 together with the air blown out from the blowout port 108 .
The electrostatic atomizer substrate is a substrate for controlling the electrostatic atomizer. Wiring 135 is connected to the electrostatic atomizer substrate, and the wiring 135 is connected to the substrate 133 .

On the mounting plate 175 attached to the front surface portion 171 , the refrigerant sensor 180 is attached below the sterilization unit 190 , that is, at a position close to the drain pan 121 .
This allows the refrigerant sensor 180 to more reliably detect refrigerant having a higher specific gravity than air. Further, in the indoor unit 100 , if the refrigerant leaks from the refrigerant pipe connection portion 150 , the refrigerant sensor 180 can detect the leaked refrigerant.

[1-2. motion]
The operation of the indoor unit 100 configured as described above will be described below.
When the indoor unit 100 performs the air conditioning operation, the gas refrigerant flows into the heat exchanger 120 through the refrigerant pipe connection portion 150 during the heating operation, and the liquid refrigerant flows into the cooling operation.

In the blower chamber 105, the blower 110 sucks air from the outside of the housing 101 through the air inlet 106, and causes the sucked air to flow into the heat exchanger chamber 107 through the air inlet 103a.
Here, as described above, the fan chamber 105 is formed so that the width in the left-right direction increases from the left end of the heat exchanger 120 to the left side. Therefore, in the blower chamber 105, outside air can be easily taken in through the intake port 106. As shown in FIG.

The air that has flowed into the heat exchanger chamber 107 exchanges heat with the refrigerant in the heat exchanger 120, is heated during the heating operation, is cooled during the cooling operation, and is then blown out of the housing 101 from the outlet 108. .
At this time, the sterilization unit 190 provided on the mounting plate 175 of the front panel 170 generates mist containing charged fine particle water. The generated mist is carried to the space to be conditioned by the flow of air blown out from the outlet 108, and exerts a sterilization effect in the space to be conditioned.

The side plate 151 facing the installation space S2 and the left side wall 101c having the side plate 151 are provided with the drain pump 123, the electrical box 130, and the like. In the indoor unit 100, when the housing 101 is downsized or the electrical box 130 is upsized, there is a possibility that the space for attaching other members to the side plate 151 may be limited.

In this embodiment, the refrigerant sensor 180 is attached to the front panel 170 of the front wall 101a, so even if the space of the side plate 151 is limited, the refrigerant sensor 180 can be provided inside the arrangement space S2.
Furthermore, since the refrigerant sensor 180 is provided on the mounting plate 175 that is detachable from the front panel 170, the operator can easily remove the refrigerant sensor 180 from the housing 101 for inspection, replacement, and the like.

In the present embodiment, indoor unit 100 includes decorative panel 102 covering front wall 101a. However, not limited to this, an air supply duct may be attached to the front wall 101a. Some of the air supply ducts cover the entire front wall 101 a , ie, up to the front panel 170 .
Even in such a case, in the indoor unit 100, the worker can access the refrigerant sensor 180 from below the housing 101 by removing the bottom panel 101f and the drain pan 121. FIG. Therefore, the operator can easily attach and detach the refrigerant sensor 180 . Furthermore, the screw head of the screw member 189 that fixes the refrigerant sensor 180 to the mounting plate 175 is arranged to face the drain pan 121 . Therefore, in the indoor unit 100, an operator can easily attach and detach the screw member 189. FIG.
That is, the indoor unit 100 is formed so that the refrigerant sensor 180 can be accessed from three directions: the front wall 101a side, the bottom panel 101f side, and the left side wall 101c side.

[1-3. effects, etc.]
As described above, in the present embodiment, the heat exchanger 120 of the indoor unit 100 includes the refrigerant pipe connection portion 150 to which the refrigerant pipes through which the refrigerant flows are connected to each other. The housing 101 is provided with an arrangement space S2 in which the refrigerant pipe connection portion 150 is arranged, and a front wall 101a that surrounds the arrangement space S2 and extends along the longitudinal direction of the housing 101 . A refrigerant sensor 180 for detecting refrigerant is provided on the front wall 101a.

Thereby, even if the space of the side plate 151 is limited, the refrigerant sensor 180 can be provided inside the arrangement space S2. Therefore, in the indoor unit 100, it is possible to detect the refrigerant that has leaked into the installation space S2.

As in the present embodiment, a mounting plate 175 detachable from the front wall 101a is provided at a position corresponding to the arrangement space S2 of the front wall 101a, and the refrigerant sensor 180 may be provided on the mounting plate 175. .
Thereby, the refrigerant sensor 180 is provided detachably from the front panel 170 together with the front mounting plate 175 . Therefore, the operator can easily remove the refrigerant sensor 180 from the housing 101 and perform operations such as inspection and replacement.

As in the present embodiment, mounting plate 175 may be provided with sterilization unit 190 , and refrigerant sensor 180 may be provided below sterilization unit 190 .
Thereby, refrigerant sensor 180 can more reliably detect a refrigerant having a higher specific gravity than air. Therefore, in the indoor unit 100, when refrigerant leakage occurs at the refrigerant pipe connection portion 150, the refrigerant sensor 180 can detect the leaked refrigerant.

As in the present embodiment, refrigerant sensor 180 may be detachably provided from the bottom side of housing 101 .
Thereby, in the indoor unit 100, the bottom panel 101f and the drain pan 121 can be removed, and the refrigerant sensor 180 can be attached and detached from below the housing 101. FIG. Therefore, in the indoor unit 100, the refrigerant sensor 180 can be accessed from three directions: the front wall 101a side, the bottom panel 101f side, and the left side wall 101c side.

As in the present embodiment, heat exchanger 120 is provided with vent portion 140 and refrigerant pipe connection portion 150, and housing 101 is provided with vent portion 140 and refrigerant pipe connection portion 150, respectively. A plurality of arrangement spaces S1 and S2 are provided. Refrigerant sensor 143 may be provided in arrangement space S1, and refrigerant sensor 180 may be provided in each of arrangement spaces S2.
As a result, in the indoor unit 100, when a refrigerant leak occurs in each of the vent portions 140 provided on both sides of the heat exchanger 120 and the refrigerant pipe connection portion 150, the refrigerant sensors 143 and 180 can detect leaked refrigerant. Therefore, in the indoor unit 100, leakage of refrigerant can be detected at a plurality of locations of the heat exchanger 120. FIG.

(Embodiment 2)
Embodiment 2 will be described below with reference to FIG.
[2-1. overall structure]
The indoor unit 200 according to Embodiment 2 differs from the indoor unit 100 according to Embodiment 1 at least in that the refrigerant sensor 143 is omitted and the piping member 210 is provided.

FIG. 11 is a perspective view of the indoor unit 200 according to Embodiment 2. FIG. In FIG. 11, the same parts as those in FIG. 3 are assigned the same reference numerals, and the description thereof is omitted.
As shown in FIG. 11 , a piping member 210 is provided in the heat exchanger chamber 107 of the housing 101 . The piping member 210 is a tubular member made of flexible resin and having both ends opened.

One end 212 of the piping member 210 is arranged in the arrangement space S1.
The piping member 210 extending from the arrangement space S1 is placed on the edge of the drain pan 121, and after being routed along the right side wall 101d, is routed along the partition plate 103 in the left-right direction. The other end 214 of the piping member 210 is arranged in the arrangement space S2.
Accordingly, the arrangement space S1 and the arrangement space S2 are communicated with each other by the piping member 210 .
It should be noted that since the blower 110 is a sirocco fan, the air volume is greater on the upper edge side of the intake port 106 . Therefore, piping member 210 is desirably arranged to pass below intake port 106 .
Also, the other end 214 of the piping member 210 may be connected to the box of the refrigerant sensor 180 .

[2-2. motion]
The operation of the indoor unit 200 configured as above will be described. Operations similar to those of the indoor unit 100 in Embodiment 1 are omitted.
In this embodiment, a piping member 210 is provided to communicate the arrangement space S1 and the arrangement space S2.
As a result, the air in the arrangement space S1 is supplied to the arrangement space S2 through the piping member 210. As shown in FIG. Therefore, when refrigerant leaks in the arrangement space S1, the air in the arrangement space S1 containing the leaked refrigerant is supplied to the arrangement space S2, and the refrigerant sensor 180 can detect the refrigerant. That is, in the indoor unit 200 , one refrigerant sensor 180 can detect not only the refrigerant pipe connection portion 150 but also refrigerant leakage occurring at the vent portion 140 .

[2-3. effects, etc.]
As described above, in the present embodiment, heat exchanger 120 is provided with vent portion 140 and refrigerant pipe connection portion 150 . The housing 101 is provided with a plurality of arrangement spaces S1 and S2 in which the vent portions 140 and the refrigerant pipe connection portions 150 are respectively arranged, and a piping member 210 that communicates the plurality of arrangement spaces S1 and S2. .

As a result, the air in the arrangement space S1 is supplied to the arrangement space S2 through the piping member 210 . Therefore, when the refrigerant leaks in the installation space S1, the leaked refrigerant through the piping member 210 is supplied to the installation space S2. In the indoor unit 200 , by detecting the refrigerant with the refrigerant sensor 180 , not only the refrigerant pipe connection portion 150 but also the refrigerant leakage generated at the vent portion 140 can be detected. That is, in the indoor unit 200, even when the refrigerant leaks at the vent portions 140 provided on both sides of the heat exchanger 120 and the refrigerant pipe connection portion 150, the refrigerant leakage is detected. be able to.

(Other embodiments)
As described above, Embodiments 1 and 2 have been described as examples of the technology disclosed in the present application. However, the technology in the present disclosure is not limited to this, and can also be applied to embodiments with modifications, replacements, additions, omissions, and the like. Also, it is possible to combine the constituent elements described in the first and second embodiments to form a new embodiment.
Therefore, other embodiments will be exemplified below.

In the first and second embodiments, the indoor units 100 and 200 are provided with the heat exchanger chamber 107 on the side of the front wall 101a, and the outlet 108 is provided on the front wall 101a. However, without being limited to this, the fan chamber 105 may be provided on the front wall 101a side, and the heat exchanger chamber 107 may be provided on the rear wall 101b side. In this case, the refrigerant sensor 180 is provided on the rear wall 101b.

Note that the above-described embodiment is for illustrating the technology in the present disclosure, and various changes, replacements, additions, omissions, etc. can be made within the scope of the claims or equivalents thereof.

INDUSTRIAL APPLICABILITY The present disclosure is applicable to indoor units in which mounting positions of refrigerant sensors are limited. Specifically, the present disclosure is applicable to duct type air conditioners, built-in type air conditioners, and the like.

100, 200 indoor unit 101 housing 101a front wall 101f bottom panel (bottom)
120 heat exchanger 140 vent (piping connection)
143 Refrigerant sensor 150 Refrigerant pipe connection (pipe connection)
170 front panel 175 mounting plate 180 refrigerant sensor 190 sterilization unit (electrostatic atomizer)
210 piping member S1 arrangement space S2 arrangement space

Claims (6)

An indoor unit comprising a housing for housing a heat exchanger having a refrigerant pipe and a blower fan inside,
The heat exchanger includes a pipe connection portion where refrigerant pipes through which refrigerant flows are connected to each other,
An arrangement space in which the pipe connection portion is arranged in the housing;
a front wall facing the arrangement space and extending along the longitudinal direction of the housing;
The indoor unit, wherein the front wall is provided with a refrigerant sensor for detecting refrigerant. A mounting plate detachable from the front wall is provided at a position corresponding to the arrangement space of the front wall,
The indoor unit according to claim 1, wherein the refrigerant sensor is provided inside the mounting plate. The mounting plate is provided with an electrostatic atomizer,
The indoor unit according to claim 2, wherein the refrigerant sensor is provided below the electrostatic atomizer. The indoor unit according to any one of claims 1 to 3, wherein the refrigerant sensor is detachably provided from the bottom surface side of the housing. The pipe connection portions are provided on both sides of the heat exchanger,
The housing is provided with a plurality of the arrangement spaces in which each of the pipe connection parts is arranged,
The indoor unit according to any one of claims 1 to 4, wherein the refrigerant sensor is provided in each of the plurality of arrangement spaces. The pipe connection portions are provided on both sides of the heat exchanger,
a plurality of the arrangement spaces in which the pipe connection portions are arranged in the housing;
The indoor unit according to any one of claims 1 to 4, further comprising a piping member that communicates with the plurality of arrangement spaces.

Images