JP6951858B2 - Indoor unit of air conditioner - Google Patents

Description

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

In recent years, in order to prevent global warming as a refrigerant used in an air conditioner, the development and use of a refrigerant having a low global warming potential (hereinafter referred to as "GWP: Global Warming Potential") has been promoted. This so-called low GWP refrigerant contains a substance that is easily destroyed in the atmosphere and has a low global warming effect but is flammable, and ensuring safety in its use is an important issue.
In a conventional heat pump type air conditioner, when a highly flammable refrigerant such as hydrocarbon or a flammable refrigerant such as R32 or other less flammable refrigerant is used, if the refrigerant leaks, it may cause an external factor. Depending on the appearance, it is possible to reach a concentration at which flammability becomes a problem (hereinafter, referred to as "lower limit combustion limit LFL"). Therefore, in a heat pump type air conditioner, when a flammable refrigerant such as a highly flammable refrigerant or a less flammable refrigerant is used, the leakage of the refrigerant is appropriately detected and the concentration of the leaked refrigerant is the lower limit combustion. It is conceivable to prevent the limit LFL from being reached.

To ensure safety, when using flammable and slightly flammable refrigerants (hereinafter referred to as "flammable refrigerants"), a refrigerant gas detection sensor (hereinafter referred to as "detection sensor") is installed in the air conditioner. Measures to be taken are common.
By installing the detection sensor, even if the flammable refrigerant leaks, the formation of the flammable concentration range by the flammable refrigerant can be suppressed and an accident such as a fire can be prevented.
Examples of the installation method include Patent Document 1 and Patent Document 2.

Patent Document 1 includes a sensor for detecting flammable refrigerant gas on the outer surface of a casing having a suction port and an air outlet, and controls the rotation of a fan when the sensor detects flammable refrigerant gas. A control unit is provided, the indoor unit is a floor-standing type, and the sensor describes an air conditioner provided in the lower part of the indoor unit.

Patent Document 2 describes an indoor unit of an air conditioner in which a flammable refrigerant is used, a casing, an indoor heat exchanger housed in the casing, and a drain pan arranged below the indoor heat exchanger. And an indoor unit of an air conditioner including a refrigerant gas detection sensor arranged outside in the longitudinal direction of the drain pan are described.

Japanese Patent No. 4599699 Japanese Patent No. 5983707

A commonly used air conditioner is configured to include an outdoor unit, an indoor unit, and a refrigerant pipe connected by on-site installation work. The outdoor unit and indoor unit are airtightly tested at the time of shipment at the manufacturing plant. Therefore, there is a high probability that the flammable refrigerant will leak from the locally constructed refrigerant piping and its connection with the indoor unit.
Further, since the flammable refrigerant has a higher specific density than air, when a leak occurs, it flows downward from the leaked portion. Therefore, in order to detect flammable refrigerant leakage at an early stage, it is preferable to install a detection sensor directly under the refrigerant pipe connection portion.
On the other hand, if the detection sensor is installed directly under the refrigerant pipe, the condensed water in the pipe portion may drip directly onto the detection sensor, and the detection sensor may be damaged. However, if the detection sensor is placed at a position avoiding directly under the pipe connection in order to avoid condensed water, the detection accuracy of refrigerant leakage may decrease.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide an indoor unit of an air conditioner capable of preventing a malfunction of a detection sensor while ensuring the detection accuracy of a refrigerant gas leak.

In order to solve the above problems, the indoor unit of the air conditioner of the present invention is installed below the heat exchanger, a housing, a heat exchanger having a pipe through which a refrigerant having a specific gravity larger than that of air passes, and the heat exchanger. The lower base includes a lower base serving as a base of the housing and a sensor for detecting the leakage of the refrigerant, the lower base has an inclined surface for receiving the leaked refrigerant, and the sensor is below the inclined surface. The sensor is installed at the position of, the detection element for detecting the refrigerant, the sensor board on which the detection element is attached so that the detection surface of the detection element faces downward, and the back surface of the sensor board inside. A sensor case that is mounted and accommodated at a ceiling position, and the inclined surface is provided with a peripheral wall portion having a predetermined height that extends upward at a position corresponding to the sensor case, and extends downward from the sensor case. The height position of the detection element is set so that the lower end thereof is lower than the predetermined height of the peripheral wall on the inclined surface, and when the refrigerant leaks, the refrigerant that has overcome the peripheral wall is the detection surface of the detection sensor. Is reached and is detected by the detection sensor .

According to the present invention, there is provided an indoor unit of an air conditioner capable of preventing a malfunction of a detection sensor while ensuring the detection accuracy of a refrigerant gas leak.

It is a system diagram which shows the refrigerant circuit of the air conditioner which concerns on embodiment of this invention. It is a figure which shows the appearance of the floor-standing type indoor unit of the air conditioner which concerns on the said embodiment, (a) is the front view, (b) is the side view. It is a vertical sectional view of the floor-standing type indoor unit of the air conditioner which concerns on the said embodiment. It is a perspective view which shows the detail of the vicinity of the lower base of the floor-standing type indoor unit of the air conditioner which concerns on the said embodiment. It is a perspective view which looked at the lower base of the floor-standing type indoor unit of the air conditioner which concerns on the said Embodiment from the back upper side to the left side. It is a perspective view which shows the back surface of the lower base of the floor-standing type indoor unit of the air conditioner which concerns on the said embodiment. FIG. 4 is a cross-sectional view taken along the line AA of FIG. FIG. 4 is a cross-sectional view taken along the line BB of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In addition, the same reference numerals are given to common parts in each figure, and duplicate description is omitted.
FIG. 1 is a system diagram showing a refrigerant circuit of an air conditioner according to an embodiment of the present invention.
As shown in FIG. 1, the air conditioner 100 includes an outdoor unit 1 installed outdoors (non-air-conditioned space) on the heat source side and a floor-standing indoor unit 2 (indoor) installed indoors (air-conditioned space) on the user side. It is composed of a machine) and is connected by a refrigerant liquid pipe 3 and a refrigerant gas pipe 4.
The outdoor unit 1 includes an outdoor heat exchanger 5, a compressor 6, an accumulator 7, a four-way valve 8, a control valve 9 composed of an electronic expansion valve, and an outdoor fan 10 for blowing external air to the outdoor heat exchanger 5. The fan motor 11 is provided, a liquid blocking valve 12 provided near the connection portion with the refrigerant liquid pipe 3, and a gas blocking valve 13 provided near the connection portion with the refrigerant gas pipe 4.

The floor-standing indoor unit 2 includes an indoor heat exchanger 14, a control valve 15 composed of an electronic expansion valve, an indoor fan 16 for blowing indoor air to the indoor unit heat exchanger 14, and a fan motor for driving the indoor fan 16. 17 is provided.

The basic operation of the air conditioner 100 will be described separately for heating operation and cooling operation.
First, the flow of the refrigerant when the air conditioner 100 is heated and operated will be described. During the heating operation, the refrigerant flows as shown by the broken line arrow in FIG.
In the case of heating operation, the gas-state refrigerant compressed by the compressor 6 flows to the indoor heat exchanger 14 through the four-way valve 8, and the refrigerant is exchanged with the indoor air by the airflow generated by the indoor fan 16. It condenses from the gas state and changes to the liquid state. The liquid refrigerant flows to the outdoor heat exchanger 5 via the control valves 15 and 9, and the airflow generated by the outdoor fan 10 absorbs the heat of the outdoor air to exchange heat, so that the refrigerant becomes liquid. It evaporates from the state to a gas state and flows to the compressor 6.

Next, the flow of the refrigerant when the air conditioner 100 is cooled and operated will be described. During the cooling operation, the refrigerant flows as shown by the solid arrow in FIG.
In the case of cooling operation, the high-pressure gas refrigerant discharged from the compressor 6 flows to the outdoor heat exchanger 5 through the four-way valve 8 and exchanges heat with the outdoor air blown by the outdoor fan 10 driven by the fan motor 11. It condenses and becomes a liquid refrigerant. This liquid refrigerant flows into the refrigerant liquid pipe 3 through the control valve 9 having a large opening degree and the liquid blocking valve 12 in the open state, and is sent to the indoor unit 2.
The refrigerant that has entered the indoor unit 2 is decompressed by the control valve 15 whose opening is narrowed, then enters the indoor unit heat exchanger 14, and is blown by the indoor fan 16 driven by the fan motor 17. Heat exchange. By this heat exchange, the indoor air is cooled, the refrigerant takes heat from the indoor air and evaporates, becomes a low-pressure gas refrigerant, passes through the refrigerant gas pipe 4, and returns to the outdoor unit 1. The low-pressure gas refrigerant returned to the outdoor unit 1 passes through the gas blocking valve 13 in the open state, enters the accumulator 7 via the four-way valve 8, and is sucked into the compressor 6 from here to be compressed again. repeat.

2A and 2B are views showing the appearance of the floor-standing indoor unit 2 of the air conditioner 100, in which FIG. 2A is a front view thereof and FIG. 2B is a side view thereof. FIG. 3 is a vertical sectional view of the floor-standing indoor unit 2 of the air conditioner 100. In the description, "up, down", "left, right", "front (front), back (rear)" follow the arrows in FIG.
The floor-standing indoor unit 2 is an indoor unit that is directly installed on the floor surface of the room.
As shown in FIG. 2, the floor-standing indoor unit 2 includes a cabinet 21 as a housing, a front panel 22 arranged in front of the cabinet 21, and a lower base 23 (detailed later) installed at the bottom of the cabinet 21. To be equipped. Refrigerant pipe intake ports 24 (hereinafter referred to as “pipe intakes”) are formed on the left and right side surfaces and the back surface (see FIG. 4) of the lower portion of the cabinet 21. Further, a remote controller 25 for operating the air conditioner 100 is installed in the central portion of the front panel 22.

As shown in FIG. 3, in the cabinet 21, the indoor heat exchanger 31 (heat exchanger), the blower (fan motor) 32, the fan guide 33, the suction port 34, the outlet 35, the heat insulating plate 36, the drain pan 37, and electricity. It includes a product box 38, a refrigerant pipe 39, and a pipe connection portion 40.
The floor-standing indoor unit 2 sucks indoor air from the suction port 34 at the lower part of the cabinet 21, sends air to the indoor heat exchanger 31 at the upper part of the cabinet 21 via the blower 32, and heat exchanges with the indoor heat exchanger 31. The generated air is blown into the room from the outlet 35.
The blower 32 includes a centrifugal fan (not shown) that rotates in a plane parallel to the front surface of the cabinet 21, and has a fan guide 33 that rectifies the flow generated by the centrifugal fan in one direction.
The front panel 22 is attached to the front surface of the indoor heat exchanger 31 so as to cover the cabinet 21. Further, the remote controller 25 is embedded and installed so that the front side of the front panel 22 becomes a flat surface. Further, the heat insulating plate 36 is attached between the front panel 22 and the indoor heat exchanger 31 in order to insulate the indoor air and the inside of the machine. The heat insulating plate 36 uses a foaming material such as a foamed plastic heat insulating material as a material.
In the floor-standing indoor unit 2, dew condensation may occur on the indoor heat exchanger 31 during the cooling operation. In order to receive the condensed water (condensed water or condensed water), a drain pan 37 is provided directly under the indoor heat exchanger 31. The drain pan 37 is attached to the lower part of the indoor heat exchanger 31, and an electric component box 38 is attached under the drain pan 37.

FIG. 4 is a perspective view showing details of the vicinity of the lower base 23 of the floor-standing indoor unit 2.
As shown in FIG. 4, a total of three pipe intakes 24 are formed on the left and right side surfaces and the surface of the lower part of the cabinet 21. Further, the lower base 23 is installed as the bottom of the cabinet 21 and constitutes the floor-standing portion of the floor-standing indoor unit 2. A pipe intake 233 is formed on the lower base 23. The pipe intake 24 of the cabinet 21 and the pipe intake 233 of the lower base 23 are intake ports for taking the refrigerant pipes 3 and 4 in FIG. 1 into the floor-standing indoor unit 2. The pipe intake 24 is configured as a surface in which knockout holes are machined at one location on each of the left and right side surfaces and the back surface of the cabinet 21. Further, the pipe intake 233 of the lower base 23 is integrally formed at the time of resin formation. Of the left and right side surfaces and surfaces shown in FIG. 4, the pipe intake 24 is formed by making a hole (penetrating) in the pipe intake 24 at an arbitrary location according to the on-site installation environment, and from the refrigerant pipes 3 and 4 at any location. (See FIG. 1) can be pulled in.
Then, as shown in FIGS. 3 and 4, the refrigerant pipes 3 and 4 taken in from the pipe intake 24 of the cabinet 21 and the pipe intake 233 of the lower base 23 are the pipe connection portions inside the floor-standing indoor unit 2. At 40, it is connected to the refrigerant pipe 39.

When the refrigerant flows inside the indoor heat exchanger 31 and the refrigerant pipe 39, the refrigerant leaks into the floor-standing indoor unit 2 due to deterioration or damage of the indoor heat exchanger 31, the refrigerant pipe 39, and the pipe connection portion 40. May be done. At that time, when a refrigerant having a heavier specific gravity than air, for example, R32, R1234yf, and R1234ze, which are single refrigerants having low combustibility, or a mixed refrigerant containing these as main components is used, the leaked refrigerant is in the direction of gravity. Will move to.
Since the flammable refrigerant used in the present embodiment has a higher specific gravity than air, when a leak occurs, the flammable refrigerant flows downward inside the cabinet 21. Therefore, as shown in FIGS. 3 and 4, the detection sensor 50 for detecting the leakage of the flammable refrigerant is mounted on the lower base 23 which is the bottom of the floor-standing indoor unit 2 (details will be described later).

FIG. 5 is a perspective view of the lower base 23 of the floor-standing indoor unit 2 as viewed from above the rear surface on the left side, and FIG. 6 is a perspective view showing the back surface of the lower base 23 of FIG.
As shown in FIG. 5 (see also FIG. 4), the lower base 23 has a rectangular recess 231 having a flat surface for receiving condensed water or leaked refrigerant, and condensed water or refrigerant to the outside of the floor-standing indoor unit 2. A side wall 232 that surrounds the outer periphery of the recess 231 is provided so as not to flow out. Further, the lower base 23 includes a screw hole 232b and a protrusion 232c for screwing and fixing the bottom portion of the cabinet 21 to the upper end surface 232a of the side wall 232. The lower base 23 includes a flange portion 234 that serves as a leg portion of the floor-standing indoor unit 2 that extends outward from the side wall 232. The side wall 232 is partially lightened in order to reduce the weight and improve the bending rigidity.

As shown in FIG. 6, the back surface of the lower base 23 forms the bottom surface of the floor-standing indoor unit 2. Ribs 235 are formed on the outer periphery of the back surface corresponding to the side wall 232 on the surface of the lower base 23. The upper end portion 235a (the portion facing the floor) of the rib 235 is formed flat. Further, inside the rib 235, a lattice-shaped reinforcing rib 236 lower than the height of the upper end portion 235a of the rib 235 is formed. By forming the reinforcing rib 236, the rigidity of the lower base 23 is increased. Further, since the reinforcing rib 236 is formed to be lower than the height of the upper end portion 235a of the rib 235, when the floor-standing indoor unit 2 is installed on the floor surface, the reinforcing rib 236 does not get caught on the floor surface or the like. Further, the upper end portion 235a of the flat rib 235 evenly contacts the floor surface or the like, so that the floor-standing indoor unit 2 can be stably supported.
By the way, in the conventional example, the reinforcing ribs are also provided on the surface of the lower base (not shown), but in such a conventional configuration, the reinforcing ribs formed on the surface of the lower base are the leaking refrigerant. It is difficult to obtain the effect of the present application because it interferes with the flow.

As shown in FIGS. 4 and 5, the recess 231 of the lower base 23 has a flat surface in order to allow drain water or leaked refrigerant dropped on the surface to smoothly flow to the bottom (lowermost position). It is formed. A coating having a water-repellent function may be applied on the flat surface.

The recess 231 has an inclined surface 231a that is inclined so that the most separated portion from directly below the pipe connecting portion 40 is the lowest with respect to the horizontal plane. In the present embodiment, as shown in FIG. 4, the pipe connection portion 40 and the like are arranged directly above the left front side (left front side) of the lower base 23. Therefore, it is assumed that the condensed water or the leaked refrigerant flows down into the recess 231 directly under the pipe connection portion 40 or the like. Therefore, as shown in FIGS. 4 and 5, the lower base 23 has the highest surface height on the left front side (left front side) of the recess 231 and the surface height on the right rear side (right back side) of the recess 231. An inclined surface 231a inclined from the left front side to the right rear side of the recess 231 is formed so as to make the height the lowest. Then, the sensor case 53 is attached to the right rear side (right back side) of the recess 231 having the lowest surface height (see FIG. 4).

The inclined surface 231a of the recess 231 of the lower base 23 will be described.
As shown in FIGS. 4 and 5, the lower base 23 includes a recess 231 and a side wall 232 on the outer periphery thereof.
As described above, the lower base 23 is inclined so that the surface height on the left front side (left front side) of the recess 231 is the highest and the surface height on the right rear side (right back side) of the recess 231 is the lowest. It has an inclined surface 231a. The sensor case 53 is installed on the right rear side (right back side) of the recess 231 having the lowest surface height (see FIG. 4).
Therefore, as shown in FIG. 5, the dimension h1 of the upper end surface 232a of the side wall 232 and the surface height of the inclined surface 231a on the left front side (left front side) of the recess 231 is the dimension h1 of the upper end surface 232a and the recess 231 of the side wall 232. It is smaller than the dimension h2 with the surface height of the inclined surface 231a on the right front side (right front side) (h2> h1). Further, the dimension h2 of the upper end surface 232a of the side wall 232 and the surface height of the inclined surface 231a on the right front side (right front side) of the recess 231 is the upper end surface 232a of the side wall 232 and the right rear side (right back side) of the recess 231. It is smaller than the dimension h3 with the surface height of the inclined surface 231a (h3> h2). Although not shown, the dimensions of the upper end surface 232a of the side wall 232 and the surface height of the inclined surface 231a on the left rear side (left back side) of the recess 231 are the dimensions of the upper end surface 232a and the recess 231 of the side wall 232. It is smaller than the dimension h3 with the surface height of the inclined surface 231a on the right rear side (right back side).

The place where the refrigerant is likely to leak is wide, but it is considered that there are many places directly under the pipe connection portion 40. This place is also a place where condensed water is dropped. As shown by the arrow in FIG. 5, the condensed water or the leaked refrigerant dropped on the inclined surface 231a of the concave portion 231 of the lower base 23 moves in the direction of gravity along the inclined surface 231a, and the concave portion 231 having the lowest surface height. It will move to the right rear side (right back side) of. A sensor case 53 is installed on the right rear side (right back side) (see FIG. 4). As a result, the condensed water or the leaked refrigerant that has flowed down to the left front side of the recess 231 flows downward along the inclined surface 231a and flows down to the sensor case 53. Then, the detection sensor 50 in the sensor case 53 detects only the refrigerant among the condensed water that has reached the sensor case 53 or the leaked refrigerant (details will be described later).

On the inclined surface 231a on the right rear side (right back side) of the recess 231 having the lowest surface height, a screw thread 231b for attaching the sensor case 53 and condensed water that has entered the sensor case 53 as described later are sensors. A peripheral wall portion 231c (see FIG. 5) that prevents the space below the substrate 52 from being reached is formed.
The pipe intake 233 is formed on the inclined surface 231a of the recess 231. However, since the standing wall 233a is formed on the outer periphery of the pipe intake 233, the condensed water or the leaked refrigerant is discharged by the standing wall 233a. It is blocked and does not overflow to the outside of the lower base 23 (outside of the floor-standing indoor unit 2).

7 and 8 are cross-sectional views of a main part of the detection sensor 50 and its surroundings. 7 is a cross-sectional view taken along the line AA of FIG. 4, and FIG. 8 is a cross-sectional view taken along the line BB of FIG.
As shown in FIGS. 7 and 8, the detection sensor 50 includes a detection element 51 that detects a refrigerant, a sensor substrate 52 to which the detection element 51 is attached, and a sensor case 53 that houses the detection element 51 and the sensor substrate 52. Be prepared.
In this embodiment, the detection element 51 is attached to the sensor substrate 52 so that the detection surface of the flammable refrigerant faces downward. The sensor substrate 52 is fixed to the inner ceiling position of the sensor case 53 with, for example, an adhesive.

The sensor case 53 has a rectangular parallelepiped thin lid shape, and is formed so as to cover the peripheral wall portion 231c formed on the inclined surface 231a of the recess 231 of the lower base 23 from the outside. The sensor case 53 has a side outer peripheral portion 53a. As shown in FIG. 8, the end of the outer peripheral portion 53a of the side surface does not reach the inclined surface 231a of the recess 231, and there is a gap between this end and the inclined surface 231a. The condensed water that has penetrated to the inside of the outer peripheral portion 53a of the side surface of the sensor case 53 through this gap is blocked by the peripheral wall portion 231c and is prevented from further entering the inside. Further, a slit-shaped refrigerant intake port 53b is formed on the outer peripheral portion 53a of the side surface of the sensor case 53. The leaked refrigerant (gas) passes through the refrigerant intake port 53b, further overcomes the peripheral wall portion 231c, and enters the detection position of the detection element 51.
Here, since the sensor case 53 has a lid shape and the detection element 51 and the sensor substrate 52 are attached to the inner ceiling position of the lid, even if condensed water is applied to the upper surface of the sensor case 53, the condensed water is inside. Does not invade.

Hereinafter, the action and effect of the floor-standing indoor unit 2 configured as described above will be described.
Since the flammable refrigerant used in the present embodiment has a higher specific gravity than air, when a leak occurs, the refrigerant flows downward in the cabinet 21. The detection sensor 50 for detecting the leakage of the flammable refrigerant is attached to the lower base 23, which is the lowermost part of the floor-standing indoor unit 2.

Next, the positional relationship between the pipe connection portion 40 and the detection sensor 50 will be described with reference to FIG.
As shown in FIG. 4, the refrigerant leakage is assumed to occur particularly at the pipe connection portion 40. Therefore, it is preferable to install the detection sensor 50 directly under the pipe connection portion 40, but it is difficult to install the detection sensor 50 directly under the pipe connection portion 40 for the following reasons.
(1) When the detection sensor 50 is installed directly under the pipe connection portion 40, the dropped condensed water directly hits the detection sensor 50, or the condensed water bounced off on the lower base 23 infiltrates the detection sensor 50 and the detection sensor 50. 50 may break down.

(2) The position directly below the pipe connection portion 40 is also a site installation work space for connecting the pipes from the pipe connection portion 40 to the pipe intake 24 of the cabinet 21 and the pipe intake 233 of the lower base 23. Therefore, in order to secure a work space for on-site installation work, it is desirable to avoid occupying the detection sensor 50 at this location. If the detection sensor 50 is installed at this location, it is desired to eliminate the possibility of damaging the detection sensor 50 by coming into contact with the detection sensor 50 during the on-site installation work.

(3) Assuming the use of the pipe intake 233 of the lower base 23 at the bottom of the floor-standing indoor unit 2, it is appropriate to provide the pipe intake 233 on the lower base 23 directly below the pipe connection 40. be. Therefore, the detection sensor 50 is arranged in a place avoiding the pipe intake 233. On the other hand, assuming maintenance of the detection sensor 50, it is preferable to install it on the back side (rear side) of the floor-standing indoor unit 2. In the present embodiment, as shown in FIG. 4, the detection sensor 50 detects the right front side (right back side) of the lower base 23 as a portion located in front of the floor-standing indoor unit 2 while avoiding the pipe intake 233. It is the installation location.

For the above reasons, in the present embodiment, the detection sensor 50 is installed in front of the lower left side of the floor-standing indoor unit 2. However, the installation location of the detection sensor 50 is not limited, and may be, for example, the central front side of the lower base 23, the central portion of the lower base 23, or the like. In this case, the central part is the lowest position.

Here, the position directly below the pipe connection portion 40 does not have to be at the uppermost position (higher position) on the lower base 23. The detection sensor 50 is preferably located at the lowermost position on the lower base 23, but the detection sensor 50 does not necessarily have to be directly below the pipe connection portion 40 at the uppermost position (higher position) on the lower base 23. Also in FIG. 4, the position directly below the pipe connection portion 40 is not the uppermost position (high position) on the lower base 23.

Next, the shape of the lower base 23 on which the detection sensor 50 is installed will be described.
As shown in FIGS. 4 and 5, the lower base 23 has a recess 231 forming a bottom surface having an inclined surface 231a. The inclined surface 231a is inclined so that the position where the sensor case 53 (detection sensor 51) is installed is at the lowest position (lowest position) of the recess 231 of the lower base 23. Specifically, an inclined surface 231a inclined from the left front side to the right rear side of the recess 231 of the lower base 23 is formed. That is, the floor-standing indoor unit 2 is inclined from the left side to the right side, and is inclined from the front side to the back side of the floor-standing indoor unit 2. Further, the inclined surface 231a is a flat surface. Then, the sensor case 53 is attached to the right rear side (right back side) of the recess 231 having the lowest surface height (see FIG. 4).

Since the lower base 23 has the inclined surface 231a, when the refrigerant leaks from the pipe connection portion 40 or the like, the leaked refrigerant travels along the flat inclined surface 231a to the sensor case as shown by the arrow in FIG. Reach 53.

Next, a method of detecting the leaked refrigerant of the detection sensor 50 will be described.
As shown in FIGS. 7 and 8, the detection sensor 50 includes a detection element 51, a sensor substrate 52, and a sensor case 53, so that the detection element 51 has a flammable refrigerant detection surface facing downward. It is attached to the sensor board 52. The sensor board 52 is fixed to the inner ceiling position of the sensor case 53. The sensor case 53 has a side outer peripheral portion 53a and a refrigerant intake port 53b formed in the side outer peripheral portion 53a.

As described above, since the leaked refrigerant has a higher specific gravity than air, it reaches the sensor case 53 along the inclined surface 231a of the lower base 23. As shown by the arrow in FIG. 8, the refrigerant that has reached the sensor case 53 passes through the refrigerant intake port 53b formed in the outer peripheral portion 53a of the side surface of the sensor case 53, and enters the inside of the sensor case 53 from the side surface direction (lateral direction). Inflow. The refrigerant that has flowed into the sensor case 53 reaches the detection surface of the detection sensor 51 over the peripheral wall portion 231c formed on the inclined surface 231a of the lower base 23, and is detected by the detection sensor 51.

Further, in addition to the leaked refrigerant, it is assumed that condensed water flows downward along the inclined surface 231a and flows down to the sensor case 53. Incidentally, when both the condensed water and the leaked refrigerant are generated, both the condensed water and the leaked refrigerant move to the sensor case 53 along the inclined surface 231a. More specifically, the leaked refrigerant rides on the condensed water, and the condensed water and the refrigerant reach the sensor case 53 together.

As shown in FIG. 8, the condensed water that has reached the sensor case 53 penetrates to the inside of the side outer peripheral portion 53a of the sensor case 53, but it is caused by the peripheral wall portion 231c formed on the inclined surface 231a of the lower base 23. The above intrusion into the inside is prevented. It is possible to prevent the infiltrated condensed water from coming into contact with the sensor substrate 52. Then, the detection sensor 50 detects only the leaked refrigerant that has reached the sensor case 53. The condensed water that has penetrated to the inside of the sensor case 53 constantly evaporates, so that the water level does not exceed the peripheral wall portion 231c.

In the present embodiment, the peripheral wall portion 231c is formed on the inclined surface 231a of the lower base 23 inside the sensor case 53, and the peripheral wall portion 231c prevents the condensed water from entering the inside. Instead of this configuration, it is conceivable to prevent the infiltration of condensed water into the inside of the sensor case 53 itself by adopting a configuration in which the outer peripheral portion 53a of the side surface inside the sensor case 53 extends downward and is in close contact with the inclined surface 231a. Be done. However, in order for the side outer peripheral portion 53a to be accurately brought into close contact with the inclined surface 231a, the length of the side outer peripheral portion 53a must be accurately manufactured in accordance with the inclined surface 231a, and there must be distortion. It doesn't become. These are cost increases. Further, since the sensor case 53 fitted to the inclined surface 231a cannot be arranged at an arbitrary position on the recess 231 of the lower base 23, it lacks versatility and freedom of arrangement.
On the other hand, in this configuration, the leaked refrigerant is taken in from the refrigerant intake port 53b of the side outer peripheral portion 53a of the sensor case 53, while the condensed water is prevented by the peripheral wall portion 231c formed on the inclined surface 231a of the lower base 23. do. As a result, it is possible to realize the arrangement of the detection sensor 50 which is excellent in versatility and degree of freedom of arrangement at low cost.

In this embodiment, the lower base 23 is assumed to be a resin part. Generally, in a resin part, in order to secure the strength of the part, as shown in FIG. 6, a grid-like rib 236 is formed inside the lower base 23. In the present embodiment, the rib 236 is provided not on the front surface side (upper surface side) of the lower base 23 but on the back surface side, so that the front surface side (upper surface side) of the lower base 23 is a flat surface. By forming the inclined surface 231a through which the condensed water or the leaked refrigerant flows on a flat surface, it is possible to prevent the leaked refrigerant from staying and shorten the time until the leaked refrigerant reaches the detection sensor 50.

Further, as shown in FIG. 6, since the reinforcing rib 236 is formed to be lower than the height of the upper end portion 235a of the rib 235, the reinforcing rib 236 is formed when the floor-standing indoor unit 2 is installed on the floor surface or during transportation. It can be prevented from being caught, and the floor-standing indoor unit 2 can be stably supported.

As described above, the air conditioner 100 of the present embodiment is installed below the indoor heat exchanger 31 and the indoor heat exchanger 31 having a refrigerant pipe 39 through which a refrigerant having a specific gravity larger than that of air passes. It includes a lower base 23 that serves as a base for the housing, and a detection sensor 50 that detects the leakage of refrigerant. The lower base 23 includes a recess 231 formed with an inclined surface 231a that receives the leaked refrigerant, and a side wall 232 that surrounds the outer periphery of the recess 231. The inclined surface 231a is formed so as to be in contact with the inner surface of the side wall 232 so that the height gradually decreases with respect to the horizontal plane. The detection sensor 50 is installed at a position below the inclined surface 231a (the lowest position). The lowermost position of the inclined surface 231a is a position separated from directly below the pipe connecting portion 40 by a predetermined distance, for example, the right rear side (right back side) of the recess 231 having the lowest surface height.
As a result, the leaked refrigerant can be collected at one of the lowermost positions of the inclined surface 231a of the lower base 23.

Further, since the lowermost position of the inclined surface 231a is away from directly below the pipe connecting portion 40, the condensed water does not directly drip onto the detection sensor 50. Even if the splashed condensed water is applied to the upper surface of the sensor case 53, the condensed water does not enter the inside of the sensor case 53. It is possible to prevent damage or malfunction of the detection sensor 50.

Further, since the inclined surface 231a of the recess 231 of the lower base 23 is a flat surface, the leaked refrigerant can be quickly moved to the installation position of the detection sensor 50, and the detection accuracy and the detection speed of the refrigerant leak can be ensured. can do.

Further, the sensor case 53 is formed so as to cover the peripheral wall portion 231c formed on the inclined surface 231a of the recess 231 of the lower base 23 from the outside. The condensed water is blocked by the peripheral wall portion 231c, and further prevented from entering the inside. The detection sensor 50 in the sensor case 53 can detect only the refrigerant among the condensed water that has reached the sensor case 53 or the leaked refrigerant.
As a result, the detection accuracy of the detection sensor 50 can be ensured while preventing the detection sensor 50 from failing due to the condensed water.

Further, the present invention is not limited to the configuration described in the above embodiment, and the configuration can be appropriately changed as long as it does not deviate from the gist of the present invention described in the claims.
For example, in the present embodiment, the floor-standing indoor unit 2 has been described as an example, but the embodiment of the present invention may be applied to a wall-mounted indoor unit.

Further, an example in which the inclined surface 231a of the lower base 23 is inclined so as to minimize the surface height on the left front side (left front side) of the lower base 23 has been described, but the inclination direction is an example, and what kind of inclination direction is used? It may be an inclined surface 231a.

The above-described embodiment has been described in detail in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to the one including all the described configurations. Further, it is possible to replace a part of the configuration of one embodiment with the configuration of another embodiment, and it is also possible to add the configuration of another embodiment to the configuration of one embodiment. .. Further, it is possible to add / delete / replace a part of the configuration of each embodiment with another configuration.

1 Outdoor unit 2 Floor-standing indoor unit (indoor unit)
14 Indoor heat exchanger 15 Control valve 16 Indoor fan 17 Fan motor 21 Cabinet (housing)
22 Front panel 23 Lower base 24 Refrigerant piping inlet 25 Remote control 31 Indoor heat exchanger (heat exchanger)
32 Blower (fan motor)
33 Fan guide 34 Suction port 35 Blow-out port 36 Insulation plate 37 Drain pan 38 Electrical product box 39 Refrigerant piping 40 Piping connection 50 Detection sensor 51 Detection element 52 Sensor board 53 Sensor case 53a Side outer circumference 53b Refrigerant intake port 100 Air conditioner 231 Recess 231a Inclined surface 231c Peripheral wall 232 Side wall 232a Upper end surface of side wall 233 Piping intake 235 Rib 235a Upper end of rib 236 Reinforcing rib

Claims (5)

With the housing
A heat exchanger with a pipe through which a refrigerant with a higher specific density than air can flow,
The lower base, which is installed below the heat exchanger and serves as the base of the housing,
A sensor for detecting the leakage of the refrigerant is provided.
The lower base
It has an inclined surface that receives the leaked refrigerant, and has an inclined surface.
The sensor is
It is installed at a position below the inclined surface and
The sensor is
A detection element that detects the refrigerant and
A sensor substrate on which the detection element is mounted so that the detection surface of the detection element faces downward,
A sensor case for accommodating the back surface of the sensor board attached to the inner ceiling position is provided.
The inclined surface is
At a position corresponding to the sensor case, a peripheral wall portion having a predetermined height extending upward is provided.
The height position of the detection element extending downward from the sensor case is
The lower end is set to be lower than the predetermined height of the peripheral wall on the inclined surface, and when the refrigerant leaks, the refrigerant that has passed over the peripheral wall reaches the detection surface of the detection sensor and is detected by the detection sensor. An indoor unit of an air conditioner characterized by being <br />. With the housing
A heat exchanger with a pipe through which a refrigerant with a higher specific density than air can flow,
The lower base, which is installed below the heat exchanger and serves as the base of the housing,
A sensor for detecting the leakage of the refrigerant is provided.
The lower base
It has an inclined surface that receives the leaked refrigerant, and has an inclined surface.
The sensor is
It is installed at a position below the inclined surface and
The sensor is
A detection element that detects the refrigerant and
A sensor substrate on which the detection element is mounted so that the detection surface of the detection element faces downward,
A sensor case for accommodating the back surface of the sensor board attached to the inner ceiling position is provided.
The sensor case is
The outer peripheral part of the side surface extending downward from the outer peripheral part,
A refrigerant intake port formed on the outer peripheral portion of the side surface is provided.
The inclined surface is
A peripheral wall portion having a predetermined height extending upward is provided at a position inside the outer peripheral portion of the side surface of the sensor case.
The sensor case is
An indoor unit of an air conditioner , wherein the outer peripheral portion of the side surface is installed so as to cover the peripheral wall portion. The sensor is installed at the lowest position on the inclined surface, and is installed at the lowest position.
The indoor unit of the air conditioner according to claim 1 or 2 , wherein the lowermost position is a position separated from directly below the connection portion of the pipe by a predetermined distance. The lower base
The recess on which the inclined surface is formed and
A side wall surrounding the outer periphery of the recess is provided.
The inclined surface is
The indoor unit of the air conditioner according to claim 1 or 2 , wherein the air conditioner is formed so as to be in contact with the inner surface of the side wall so that the height is gradually lowered with respect to the horizontal plane. The inclined surface has a flat surface and has a flat surface.
The back surface of the recess is
The ribs that form the outer frame and
The indoor unit of an air conditioner according to claim 4 , further comprising a reinforcing rib inside the rib and formed lower than the height of the upper end portion of the rib.

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