JP5558121B2 - Air conditioner indoor unit - Google Patents

Description

  The present invention relates to an indoor unit of an air conditioner, and more particularly to an indoor unit of an air conditioner having means for discharging dewed water to the outside of an air path when the dew condensation water adheres to the air path of the indoor unit.

In a conventional air conditioner indoor unit, in order to prevent water droplets from dropping (sometimes referred to as “dew dripping” in the present invention) from the indoor unit during cooling operation, moisture adhering to the vicinity of the outlet is detected. Then, an invention has been disclosed in which the moisture is evaporated by a heater, the rotational speed of an indoor fan is increased, or the rotational speed of a compressor is decreased (see, for example, Patent Document 1).
In addition, condensation of suction air that is not sufficiently dehumidified blown out to the secondary side of the indoor heat exchanger and water generated when cooling and dehumidifying by the indoor heat exchanger (in the present invention, “dew condensation water in the air passage” Focusing on the generic name), detecting these, detecting the dew point temperature of the intake air, increasing the air volume of the indoor fan, or decreasing the rotational speed of the compressor (elevating the evaporation temperature) ) Is disclosed (for example, see Patent Document 2).

Japanese Patent Laid-Open No. 2-154930 (page 2-3, FIG. 1) JP 2003-106619 A (page 4-5, FIG. 2)

However, the invention disclosed in Patent Document 1 is a ceiling-embedded air conditioner, and in order to detect dew condensation due to room air attracted by the blown air, a dew condensation sensor is provided on the lower surface of the decorative panel around the blowout port. There are the following problems.
(A) Condensation in the air passage is not considered. Therefore, since the large water droplet which the dew condensation water gathered and grew in the air channel is not detected, the water droplet is dripped indoors (dew dripping cannot be prevented).
(Ii) Even if the condensation sensor is installed in the air channel (surface on the air channel side of the air channel wall) to detect the occurrence of dewed water in the air channel, it is installed in the center in the width direction. Therefore, it is impossible to detect dew condensation water in a range other than the position. Further, an increase in air path resistance is predicted, and if the load of the blower is increased to compensate for this, energy saving operation is hindered.
(C) Furthermore, assuming that the condensed water flows down along the surface of the air channel wall on the air channel side, if a drain pan is provided on the inner surface of the air channel wall, the air channel resistance is further increased and energy saving operation is performed. And the opening area of the air outlet is reduced, impairing comfort and design.

On the other hand, the invention disclosed in Patent Document 2 is an excellent solution to solve the above (a) and (ii), but on the air channel side surface of the air channel wall where the air blown from the blower collides, Adhered to almost the entire length in the longitudinal direction of the water sensor (a pair of conductive wires is surrounded by a non-woven fabric for water retention and changes in electrical resistance due to water retention are detected). Therefore, there were the following problems.
(E) Since the water sensor is bonded over almost the entire length in the longitudinal direction of the inner surface of the air passage wall, it is predicted that the air flow may be disturbed and the air passage resistance may increase.
(O) In particular, if the water retention capacity is increased to prevent dripping water from dropping into the room, the volume (cross-sectional area) of the water sensor increases and the air path resistance may increase.
In addition, the water sensor is long and is glued over its entire width, thereby incurring additional costs.

  The present invention has been made to solve the above problems, and a first object is to prevent or minimize dew dripping even if dew condensation water occurs at any position in a wide range in the air passage. An object of the present invention is to provide an indoor unit for an air conditioner that can be suppressed to a low level.

An indoor unit of an air conditioner according to the present invention includes an indoor unit main body in which an inlet and an outlet are formed, an air passage wall that forms an air passage from the inlet to the outlet, and the air passage An air blower and a heat exchanger that are arranged, a main drain pan that receives moisture dripping from the heat exchanger, and a position closer to the air outlet than the air blower on the air passage wall, and the air passage side of the air passage wall as an is an incoming dew water attached to the surface freely pass one or more pieces of the slit opening is formed on the surface of the anti-wind roadside of the air passage wall below the slit opening, the slit opening One or a plurality of dew water pans through which the dew water that flows into the opposite wind channel side of the wind channel wall flows and the dew water that flows out of the dew water pan flows into the main drain pan for drainage. A drainage channel, and is formed in the dew water pan, A full water discharge means for discharging the dew water flowing in more than a predetermined amount into the drainage channel, and a pool prevention unit formed in the dew water pan to prevent the flow of the dew water flowing in and to discharge into the drain channel And a water level sensor that is installed in the dew water pan and detects that dew water has flowed into the dew water pan, and a part of the drainage channel is formed on the surface of the air channel wall on the side opposite to the wind channel Is formed, and the dew water overflowing through the full water discharge means flows into the sub drain pan, and above the slit-like opening on the surface on the side opposite to the wind path of the wind path wall, The dew water pan bowl that covers the dew water pan is formed, and the dew water that has passed through the slit-shaped opening and entered the anti-airway side is dripped onto the dew water pan along the lower surface of the dew water pan bowl. , And adhere to the surface of the wind channel wall on the side opposite to the wind channel Moisture, characterized in that dropped into the sub-drain pan transmitted to the upper surface of the adhesive dew water bread eaves.

In the indoor unit of the air conditioner according to the present invention, the dewdrop adhering to the surface of the airway wall on the airway side passes through the slit-shaped opening and enters the anti-airway side of the airway wall, and enters the dewwater pan. And one or a plurality of slit-like openings through which the dewdrop adhering to the airway wall surface of the baffle wall can pass freely. ) Is prevented.
Moreover, even if a sensor for detecting the occurrence of the dew water is installed in the dew water pan, the air path resistance does not increase, so that the energy saving operation is not hindered.
In addition, the slit-shaped opening is formed to have the approximate width of the air passage wall (same as the distance perpendicular to the wind flow), and it is attached to the position where the dew water flowing into the dew water pan gathers (the lowest position, etc.). If a sensor for detecting the presence or absence or increase / decrease of dew water is installed, it is possible to detect the occurrence of dew water generated at any position in the air passage at an early stage. If early prevention of occurrence of dew condensation water is performed by early detection, generation of dew condensation water can be suppressed, dripping (dew drop) from the outlet of dew condensation water into the room can be further prevented, and comfort can be improved. .

The whole sectional view explaining the indoor unit of the air harmony machine concerning Embodiment 1 of the present invention. The fragmentary sectional view of front view which expands and shows the part of the harmony machine shown in FIG. The fragmentary sectional view of front view which expands and shows the modification of the part of the conditioner shown in FIG. The fragmentary sectional view of front view which expands and shows the modification of the part of the conditioner shown in FIG. The fragmentary sectional view explaining the indoor unit of the air conditioner which concerns on Embodiment 2 of this invention. The flowchart which shows the control flow of the indoor unit shown in FIG. The partial expanded sectional view of the indoor unit of the air conditioner which concerns on Embodiment 3 of this invention. The flowchart which shows the control flow of the indoor unit shown in FIG. The partial expanded sectional view of the indoor unit of the air conditioner which concerns on Embodiment 4 of this invention. The flowchart which shows the control flow of the indoor unit shown in FIG. The partial expanded sectional view of the indoor unit of the air conditioner which concerns on Embodiment 5 of this invention. The flowchart which shows the control flow of the indoor unit shown in FIG. The partial expanded sectional view of the indoor unit of the air conditioner which concerns on Embodiment 6 of this invention. The partial expanded sectional view of the indoor unit of the air conditioner which concerns on Embodiment 7 of this invention. The flowchart which shows the control flow of the indoor unit shown in FIG. The whole sectional view of the indoor unit of the air harmony machine concerning Embodiment 8 of the present invention. The whole sectional view of the indoor unit of the air harmony machine concerning Embodiment 9 of the present invention.

[Embodiment 1]
(Air conditioner indoor unit)
1 to 4 illustrate an indoor unit of an air conditioner according to Embodiment 1 of the present invention. FIG. 1 is an overall cross-sectional view showing a cross section of the air conditioner viewed from the front, and FIG. FIG. 3 and FIG. 4 are partial cross-sectional views in front view showing, on an enlarged scale, a modification of the harmonic machine portion. In addition, each figure is drawn typically and this invention is not limited to the form (Aspect ratio, thickness, etc. of a structural member) illustrated. Moreover, in each figure, the same code | symbol is attached | subjected to the same part or an equivalent part, and a part of description is abbreviate | omitted.

(Indoor unit body)
In FIG. 1, an air conditioner indoor unit (hereinafter may be abbreviated as “indoor unit”) 100 is installed on an indoor ceiling 1000, and has a suction port 11 and an air outlet 15 on the lower surface. The formed indoor unit body 10 and a blower 4 (same as a cross-flow fan) 4 installed in the indoor unit body 10 are provided.
Then, the conditioned air blown out from the suction port 11 to the blower 4 (same on the upstream side), the suction air passage 1 through which the sucked room air flows, and the blower 4 to the blowout port 15 (same on the downstream side). The blow-out air passage 5 through which the air flows is formed. The suction air passage 1 includes an air purification filter 2 through which the sucked room air passes and the contained dust is removed, and a heat exchanger 3 that cools or heats the room air that has passed through the air purification filter 2. Has been placed. The indoor air that has passed through the heat exchanger 3 is referred to as “conditioned air”.
Furthermore, the heat exchanger 3 is arranged in a substantially inverted C shape when viewed from the front, and a main drain pan 6 that receives the water (dew condensation water, etc.) adhering thereto is disposed below the heat exchanger 3. Has been. The heat exchanger (corresponding to an indoor heat exchanger) 3 constitutes a refrigeration cycle together with a refrigerant compressor, an outdoor heat exchanger, and refrigerant expansion means installed in an outdoor unit (not shown). By changing the flow of the refrigerant, it functions as a condenser (releases hot heat) and an evaporator (releases cold heat).

(Blowout wind path)
The blow-out air passage 5 has a substantially arc shape or a substantially Γ (gamma) shape having a circular arc portion when viewed from the front, and is disposed on the upper side or the side far from the blower 4 and has a large-diameter blow wall (with a relatively large curvature radius). (Same as the air channel wall) 12, a small-diameter outlet wall (same as the air channel wall) 13 which is disposed on the lower side or near the blower 4 and has a smaller radius of curvature than the large-diameter outlet wall 12, and the large-diameter outlet wall 12 And an end blowing wall 14 that forms a bent tube by connecting both ends of the small diameter blowing wall 13.
In the following, for convenience, the blow-out air passage 5 has a horizontal flow portion 5a in which conditioned air is blown out in a substantially horizontal direction within a range close to the blower 4, and an arc shape in which the flow direction is changed following the horizontal flow portion 5a. The arc flow portion 5b and the vertical flow portion 5c that forms a flow that flows substantially vertically downward to the blowout port 15 following the arc flow portion 5b are generally described. However, the boundaries are not always clear. Not.
The horizontal flow portion 5 a is formed by the large-diameter horizontal wall portion 12 a of the large-diameter blowing wall 12. The arc flow portion 5b is formed by a large-diameter arc wall portion 12b of the large-diameter blowing wall 12 and a small-diameter arc wall portion 13b of the small-diameter blowing wall 13 opposed to the large-diameter arc wall portion 12b. The vertical flow portion 5c is formed by a large-diameter vertical wall portion 12c of the large-diameter blowing wall 12 and a small-diameter vertical wall portion 13c of the small-diameter blowing wall 13 facing the large-diameter vertical wall portion 12c. In addition, each boundary is not necessarily clear.

(Large-diameter frost water discharge part)
In FIG. 2, the surface of the large-diameter blowing wall 12 that is not touched by the conditioned air (same as the surface that is not the surface of the blowing air passage 5, the left surface in FIG. 2, hereinafter referred to as “surface on the anti-air passage side”) A frosted water discharge portion 20 is formed.
The frost water discharge part 20 is formed at a position substantially corresponding to the boundary between the large-diameter arc wall part 12b and the large-diameter vertical wall part 12c of the large-diameter outlet wall 12, and is a slit-like opening through which the dew-deposition water can pass. 21 and dewed water that has been installed on the surface of the large-diameter outlet wall 12 below the slit-shaped opening 21 on the side opposite to the wind path, and that has passed through the slit-shaped opening 21 and entered the counter-airway side of the large-diameter outlet wall 12. A dew water pan 22 to be received.

(Large-diameter dew water pan)
The dew water pan 22 is a bowl-shaped (upper surface opened) formed of a part of the large-diameter vertical wall portion 12c on the side opposite to the wind path, a pan bottom plate 22a, a pan side plate 22b, and a pan end plate 22c. Box-like). The bread side plate 22b is smoothly connected to the lower end of the large-diameter arc wall portion 12b (same as the upper edge of the slit-shaped opening 21). Accordingly, it can be considered that the lower end of the large-diameter arc wall portion 12b is smoothly extended downward on the side opposite to the wind path and joined to the pan bottom plate 22a.
Further, the upper edge of the bread end plate 22 c is located at a position lower than the lower edge of the slit-shaped opening 21. Therefore, the dew water adhering to the surface on the air passage side of the large-diameter outlet wall 12 (particularly, the large-diameter arc wall portion 12b) flows down along the surface, passes through the slit-shaped opening 21 and moves toward the anti-air passage side. It enters and is stored in the dew water pan 22. Therefore, it is prevented that the dew water drops (dew drops) into the room from the outlet 15.

The surface of the large diameter vertical wall portion 12c on the side opposite to the wind path is provided with a sub-drain pan 7 that receives moisture adhering to the surface on the side opposite to the wind path of the large-diameter blowing wall 12, and the water accumulated in the sub-drain pan 7 is not shown. It is led to the main drain pan 6 by the drainage channel.
When the dew water flowing into the dew water pan 22 overflows from the upper edge of the pan end plate 22c, the dew water flows into the sub drain pan 7 and is guided to the main drain pan 6 via a drainage channel (not shown). Further, the water stored in the main drain pan 6 (which may not include dew condensation water) is guided to an outdoor unit (not shown) by a discharge means (not shown).

  The present invention is not limited to the illustrated form of the dew water pan 22; for example, the pan end plate 22c may be removed so that the dew water flows out from the end of the pan bottom plate 22a. Alternatively, the dew water pan 22 itself may be removed so that the dew water flows directly into the auxiliary drain pan 7 (at this time, the dew water is not stored (does not accumulate) in the dew water pan 22). ). Alternatively, the dew water stored in the dew water pan 22 may be guided directly to the main drain pan 6 without passing through the sub drain pan 7.

(Small diameter side frost water discharge part)
On the other hand, a frosted water discharge portion 30 is formed on the surface of the small diameter outlet wall 13 on the side opposite to the wind path.
The frost water discharge part 30 is formed at a position substantially corresponding to the boundary between the small-diameter arc wall portion 13b and the small-diameter vertical wall portion 13c of the small-diameter outlet wall 13, and a slit-like opening 31 through which the dew-deposited water can pass. And a dew water pan 32 that receives the dew water that has passed through the slit-shaped opening 31 and entered the anti-wind passage side of the small-diameter blowing wall 13.

(Dew condensation water pan on the small diameter side)
The dew water pan 32 is formed of a surface on the side opposite to the wind path of the small-diameter vertical wall portion 13c, a pan bottom plate 32a, a pan side plate 32b, and a pan end plate 32c. The pan side plate 32b is smoothly connected to the lower end of the small-diameter arc wall portion 13b (same as the upper edge of the slit-shaped opening 31). Therefore, it can be considered that the lower end of the small-diameter arc wall portion 13b is smoothly extended downward on the side opposite to the wind path and joined to the pan bottom plate 32a. Further, the upper edge of the bread end plate 32 c is located at a position lower than the lower edge of the slit-shaped opening 31.
Therefore, the dew condensation water adhering to the surface of the small-diameter blowing wall 13 (small-diameter arc wall portion 13b) on the air passage side flows down along the surface, passes through the slit-shaped opening 31 and enters the counter-air passage side, and is attached. It is stored in the dew water pan 32. Therefore, it is prevented that the dew water drops (dew drops) into the room from the outlet 15.

The sub-drain pan 8 is provided on the surface of the small-diameter vertical wall portion 13c on the side opposite to the wind path, and overflowed from the upper edge of the pan end plate 32c of the dew water pan 32 in the same manner as the large-diameter side frost water discharge unit 20. The dewed water flows into the auxiliary drain pan 8 and is guided to the main drain pan 6 by a drainage channel (not shown).
In addition, it is the same as the dew water pan 32 that this invention is not limited to what shows the form of the dew water pan 32 in the figure.

As described above, in the indoor unit 100, the dew condensation water generated in the blowout air passage 5 is guided to the outside of the air passage, so that the dew condensation water is prevented from dropping (dew drop) from the air outlet 15 into the room. At this time, since the large-diameter blowout walls 12 and 13 do not have protrusions (ridges) that disturb the wind flow, the wind flow is not hindered and energy saving operation is ensured.
In addition, since it is thought that adhesion of dew condensation water is remarkable on the large diameter blowing wall 12 side where the conditioned air sent out from the blower 4 collides, the indoor unit 100 removes the frosted water discharge part 30 on the small diameter side. And you may have only the frosted water discharge part 20 by the side of a large diameter.

(Modified example of slit-shaped opening)
In FIG. 3, the slit-shaped opening 21 is covered with a moisture-permeable permeable membrane 23 through which the dew condensation water passes (permeates) but does not pass the conditioned air (precisely, it is difficult to pass through). At this time, the air passage side surface of the moisture permeable permeation membrane 23 smoothly connects the air passage side surface of the large-diameter arc wall portion 12b and the air passage side surface of the large-diameter vertical wall portion 12c.
Therefore, since the air flow in the blowout air path 5 is not disturbed more, energy saving operation is further secured.

(Pan side wall modification)
In FIG. 4, the lower end of the large-diameter arc wall portion 12b is smoothly extended downward on the anti-airway side to form a large-diameter arc wall extension portion (corresponding to a ridge) 12d, and the lower end is connected to the pan side plate 22b. It has not been. Accordingly, a gap 25 is formed between the lower edge of the former extension and the upper edge of the bread side plate 22b. The upper edge of the bread side plate 22b and the upper edge of the bread end plate 22c are substantially the same height. Therefore, the dew water flowing in after the dew water is full overflows from both the upper edge of the bread side plate 22b and the upper edge of the bread end plate 22c (exactly, it flows out of the drain hole 24), and the sub drain pan. 7 is accepted.

The large-diameter arc wall extension portion 12 d covers the upper side of the dew water pan 22, that is, the lower end (hereinafter referred to as “extension portion lower end”) 12 e of the large-diameter arc wall extension portion 12 d is the pan of the dew water pan 22. It is located on the side opposite the wind path from the side plate 22b (left side in the figure). Further, a ridge 26 is formed on the lower surface of the large-diameter arc wall extension portion 12d in a range included immediately above the dew water pan 22 (on the right side from directly above the pan side plate 22b in the drawing).
Therefore, even if dew condensation occurs outside the blowout air passage 5 and the water flowing down along the surface on the side opposite to the airflow passage of the large-diameter blowout wall 12 drops from the lower end 12e of the extension portion of the large-diameter arc wall extension portion 12d. Such moisture does not drip into the dew water pan 22. Further, when the frost water is generated in the blowout air passage 5 and the dew condensation water flowing down along the air passage side surface of the large-diameter arc wall portion 12b passes through the slit-shaped opening 21, the large-diameter arc wall extension portion 12d. It flows along the lower surface of the water and drops from the ridge 26 and is received by the dew water pan 22.

[Embodiment 2]
(Air conditioner indoor unit)
5 and 6 illustrate an indoor unit of an air conditioner according to Embodiment 2 of the present invention, and FIG. 5 (a) is a partial sectional view in front view showing an enlarged part of the conditioner. FIG. 5, (b) of FIG. 5 is a partial sectional view in side view showing an enlarged portion of the conditioner, and FIG. 6 is a flowchart showing a control flow of the indoor unit. In addition, each figure is drawn typically and this invention is not limited to the form (Aspect ratio, thickness, etc. of a structural member) illustrated. In addition, the same reference numerals are given to the same or corresponding parts as in the first embodiment, and a part of the description is omitted.

  In FIG. 5, an indoor unit 200 of an air conditioner (hereinafter, may be abbreviated as “indoor unit”) 200 includes detection means for detecting the occurrence of dewed water in the indoor unit 100 shown in Embodiment 1. Control means for preventing the occurrence of dewed water based on the detection result of the detection means. In addition, the same code | symbol is attached | subjected to the part which is the same as that of Embodiment 1, or an equivalent part, and one part description is abbreviate | omitted.

(Large-diameter frost water discharge part)
In FIG. 5, a water level sensor 80 is installed in the dew water pan 22 of the indoor unit 200. At this time, the bread bottom plate 22a is inclined so as to become lower toward the one bread end plate 22c, and a drain hole (corresponding to a pool prevention means) 24 is formed near one bread end plate 22c of the bread bottom plate 22a. ing. A water level sensor 80 is installed near the drain hole 24.
Therefore, in the indoor unit 200, even if dewed water is generated at any position (particularly, any position in the width direction of the arc flow portion 5 b) of the blowout air passage 5, it flows into the dewed water pan 22. And when it flows in the direction of the water level sensor 80 and the amount of generated dew water is larger than the amount flowing out of the drain hole 24, the dew water is stored in the dew water pan 22 (the water volume increases). Eventually, when it becomes full, it overflows from the upper edge of one bread end plate 22 c and flows into the auxiliary drain pan 7 via the drainage channel 16.

(Water level sensor)
The water level sensor 80 detects a change in electric resistance or capacitance between a pair of conductors 80a and 80b facing each other with a predetermined interval and when dew condensation water enters between them. Means (not shown). The present invention is not limited in its form, and the dew condensation water has flowed in (is present) near the drain hole 24 or the dew condensation water is stored near the drain hole 24 (reserved). Any of them (for example, optical type or the like) may be used.
Therefore, if the detection position of the water level sensor 80 is lowered (for example, if it is installed on the pan bottom plate 22a), even if the amount of dew water generation is small, the occurrence can be detected at an early stage. At this time, one bread end plate 22c and the drain hole 24 may be removed.

On the other hand, if the detection position of the water level sensor 80 is set high, the generation rate of dew water (the generation amount per unit time) is relatively large (the outflow rate from the drain hole 24 (outflow amount per unit time)). The occurrence can be detected only when there are more). That is, erroneous detection is prevented, and frequent control for preventing the occurrence of dew condensation water, which will be described later, is prevented, and comfort is not hindered.
In the above, the bread bottom plate 22a is inclined toward one end. However, the present invention is not limited to this, and the both sides are inclined toward both ends (in a mountain shape), and drain holes are provided at both ends. 24 may be provided. Further, the periphery of the drain hole 24 may be depressed (this will be described in detail separately).
Further, instead of the water level sensor, a water level change sensor that detects a change in the level of the dew water stored (stored) near the drain hole 24 may be installed (this will be described in detail separately). ).

(Control means)
The control means (not shown) detects the evaporation temperature of the refrigerant supplied to the heat exchanger 3 (hereinafter referred to as “indoor heat exchanger temperature”) when the water level sensor 80 detects that the dew water flows into the dew water pan 22. And then evaporating temperature of the refrigerant supplied to the heat exchanger 3 when the water level sensor 80 detects that the dew water flows out of the dew water pan 22. (Return) control is executed. Hereinafter, the control flow will be described along a flowchart (each step is indicated as “S”).

(Control flow)
6, when the cooling operation is started (ON) (S1), the control unit of the indoor unit 200 confirms that the cooling operation is being performed (S2), and refers to the detection result of the water level sensor 80 ( S3). If the water level sensor 80 does not detect dew condensation water (denoted as OFF in the figure), it is determined that there is no occurrence of dew condensation water (S4), and no action is taken to prevent the occurrence of dew condensation water. (S5), it returns to step 2. At this time, it may return continuously or at regular intervals.
On the other hand, when the water level sensor 80 detects dew condensation water (denoted as ON in the figure), the time during which the action is continued (action duration Hm) is referred to (S6). If the predetermined time H1 has not elapsed (Hm <H1), it is determined that the dew water pan 22 is not full (S7), and the action is executed (execution start or execution continuation, S8). Return to step 2.
On the other hand, if the action duration time Hm of the action has passed the predetermined time H1 (H1 ≦ Hm), it is determined that the dew water pan 22 is full (S9), and the action is not successful. Is determined and the cooling operation is stopped (OFF) (S10). At this time, the fact that the action is not successful may be notified by displaying a voice or a character graphic.

(action)
The action for preventing the occurrence of dewed water is to increase the temperature of the refrigerant supplied to the heat exchanger 3. Further, the rotational speed of the blower 4 is increased. Alternatively, both are executed simultaneously.
At this time, since the dew water is generated in the cooling operation (when the heat exchanger 3 functions as an evaporator and the cooling heat is released), this action acts in the direction of weakening the cooling, but the temperature of the refrigerant rises. Is minimal (for example, 1 ° C.), so that discomfort is minimized. In addition, the point which raises the temperature of a refrigerant | coolant is well-known, Comprising: The rotation speed of the compressor of a refrigerant | coolant is made small, or the aperture ratio of a refrigerant | coolant expansion means is changed.
Furthermore, an electric heater for raising the temperature of the wall surface may be installed in the blowout air passage 5 (particularly, the arc flow portion 5b) so that the electric heater is energized. At this time, if one or both of the actions are used in combination, the effect increases.

(Small diameter side frost water discharge part)
Although the indoor unit 200 detects generation | occurrence | production of dew condensation water in the frost water discharge part 20 by the side of large diameter, this invention is not limited to this, The frost water discharge part 30 of small diameter side ( In the case where the small-diameter-side frosted water discharge section 30 is provided), the generation of dewed water may be similarly detected. At this time, the detection result is referred to for both the large-diameter-side frost water discharge unit 20 and the small-diameter-side frost water discharge unit 30, and if one of the detection conditions is satisfied, the action is executed (or stopped). )

  As described above, in the indoor unit 200, even if dewed water is generated at any position of the blowout air channel 5, it flows into the dewed water pan 22 installed outside the air channel, and the occurrence thereof is detected at an early stage. And the action is executed. Therefore, generation | occurrence | production of dewdrop is suppressed and dripping (dewdrop) of dewdrop from the blower outlet 15 to a room | room is prevented more reliably. At this time, the energy-saving operation is secured as in the indoor unit 100.

  As described above, in the indoor unit 200, the water level sensor 80 is installed in the dew water pan 22, but the dew water pan 22 is removed and one of the upper edge or the lower edge of the slit-shaped opening 31 is removed. Or, along both, a water level sensor 80 is installed on the surface of the wind path wall 12 on the side opposite to the wind path, and when this detects that the dew water has passed through the slit-shaped opening 31, the action is performed, The action may be stopped when the water level sensor 80 detects a decrease or disappearance of the dewed water passing through the slit-shaped opening 31.

[Embodiment 3]
(Air conditioner indoor unit)
7 and 8 illustrate an indoor unit of an air conditioner according to Embodiment 3 of the present invention. FIG. 7 is an enlarged partial sectional view of the conditioner in a side view, FIG. These are flowcharts which show the control flow of an indoor unit. In addition, each figure is drawn typically and this invention is not limited to the form (Aspect ratio, thickness, etc. of a structural member) illustrated. In addition, the same reference numerals are given to the same or corresponding parts as in the first embodiment, and a part of the description is omitted.

In FIG. 7, an indoor unit 300 of an air conditioner (hereinafter sometimes abbreviated as “indoor unit”) 300 is provided with a dew water pit 40 on a dew water pan 22 in the indoor unit 200 shown in the second embodiment. A pair of water level sensors 80 are installed in the dew water pit 40.
That is, the dew water pit 40 which is a recessed part indented in a cup shape is formed at the lower end of the inclined dew water pan 22, and the drain hole 24 is formed in the pit bottom 40 a of the dew water pit 40. ing. A water level sensor 80 (hereinafter referred to as “sewage level sensor 81”) is located near the upper edge of the pit wall 40c of the dew water pit 40 at a position near the pit bottom 40a of the pit wall 40c of the dew water pit 40. Water level sensors 80 (hereinafter referred to as “full water level sensor 82”) are respectively installed.

Therefore, the dew water received by the dew water pan 22 enters the dew water pit 40. At this time, since the cross-sectional area parallel to the horizontal plane of the dew water pit 40 is smaller than the cross-sectional area parallel to the horizontal plane of the dew water pan 22, even if there is little occurrence of dew water, it enters the dew water pit 40. The water level of the dewed water rises rapidly. That is, it is possible to detect the occurrence of dew condensation water in an “amplified” state.
Moreover, since the dew water that has reached the full water level sensor 82 overflows from the upper edge of the pit wall 40c, the full water level sensor 82 functions as a sensor that detects full water. Therefore, “reference of action duration (S6)” in the control flow in the indoor unit 200 can be replaced with “detection of dewed water in the full water level sensor 82 (ON)”. Similar effects can be obtained.

The indoor unit 200 has the frost water pit 40, but the present invention is not limited to this. The frost water pit 40 is removed, and the full water level sensor 82 is formed on the upper edge of the bread side plate 22b. The same effect can be obtained even if the is installed.
The shape of the frosted water pit 40 is not limited. For example, the upper edge of the pit wall 40c of the frost water pit 40 may be at a position lower than the bread bottom plate 22a. On the other hand, when the upper edge of the pit wall 40c is positioned higher than the upper edge of the bread end plate 22c or the bread side plate 22b, the upper edge of the bread end plate 22c or the bread side plate 22b is naturally filled with water. Function as.

(Control flow)
8, when the cooling operation is started (ON) (S1), the control unit of the indoor unit 300 confirms that the cooling operation is being performed (S2), and refers to the detection result of the sewage level sensor 81. (S3). When the sewage level sensor 81 does not detect the dew water (OFF), it is determined that there is no dew water (S4), and the action for preventing the dew water generation is not executed (S5), step Return to 2. At this time, it may return continuously or at regular intervals.
On the other hand, when the sewage level sensor 81 detects dew water (ON), the detection result of the full water level sensor 82 is referred to (S6-2). If the full water level sensor 82 does not detect dew water (OFF), it is determined that there is dew water in the dew water pit 40 (S7), and the action is executed (start of execution or continued execution, S8). Return to step 2.
Furthermore, when both the sewage level sensor 81 and the full water level sensor 82 detect dew water (ON), it is determined that the dew water pit 40 is full (S9), and the action is not successful. Judgment is made and cooling operation is stopped (OFF) (S10).

[Embodiment 4]
(Air conditioner indoor unit)
9 and 10 illustrate an indoor unit of an air conditioner according to Embodiment 4 of the present invention. FIG. 9 is a partial cross-sectional view in side view showing an enlarged part of the conditioner. These are flowcharts which show the control flow of an indoor unit. In addition, each figure is drawn typically and this invention is not limited to the form (Aspect ratio, thickness, etc. of a structural member) illustrated. In addition, the same reference numerals are given to the same or corresponding parts as in the first embodiment, and a part of the description is omitted.

In FIG. 9, an indoor unit (hereinafter, may be abbreviated as “indoor unit”) 400 of the air conditioner 400 has a full water level sensor 82 in the indoor unit 300 shown in the third embodiment. It was installed away from the upper edge.
That is, a dew water pit 40 having a drain hole 24 formed in the pit bottom 40 a is provided at the lower end of the inclined dew water pan 22, and is formed on the pit bottom 40 a of the pit wall 40 c of the dew water pit 40. A water level sensor 80 (hereinafter referred to as “sewage level sensor 81”) is installed at a close position, and a water level sensor 80 (hereinafter referred to as “full water level sensor 82”) is installed at a position higher than the sewage level sensor 81. Yes.

Therefore, when the dew water received by the dew water pan 22 flows into the dew water pit 40 and the inflow amount per unit time is larger than the discharge amount per unit time discharged from the drain hole 24, The sewage level sensor 81 detects that there is dew water (ON), and then the water level sensor 83 detects that there is dew water (ON).
Then, since the time from when the sewage level sensor 81 is turned on to when the sewage level sensor 83 is turned on means that the amount of inflow per unit time of the dew water is large, the generation of dew water is prevented. This suggests that action needs to be strengthened.
In addition, instead of installing the lower water level sensor 81 and the upper water level sensor 83 in two stages, a similar effect can be obtained by installing one water level change sensor (this will be described in detail separately). To do).

(Control flow)
10, when the cooling operation is started (ON) (S1), the control unit of the indoor unit 400 confirms that the cooling operation is being performed (S2), and refers to the detection result of the sewage level sensor 81. ( S3 ). When the sewage level sensor 81 does not detect the dew water (OFF), it is determined that there is no dew water (S4), and the action for preventing the dew water generation is not executed (S5), step Return to 2. At this time, it may return continuously or at regular intervals.
On the other hand, when the sewage level sensor 81 detects dew water (ON), the detection result of the sewage level sensor 83 is referred to (S6-3). When the water level sensor 83 does not detect the dew water (OFF), it is determined that the dew water is in the initial stage of generation (S7-2), and the first action is executed (start or continue execution, S8). 2) Return to step 2.

Further, in the case where both the lower water level sensor 81 and the upper water level sensor 83 detect dew condensation water (ON), the elapsed time from when the lower water level sensor 81 is turned ON until the upper water level sensor 83 is turned ON (water surface rising time) Tm) is referred to (S6-4).
When the water surface rising time Tm is less than the predetermined flow rate determination time T1 (Tm <T1), it is determined that the generation of dew water is relatively rapid (S7-3), and the second action is executed. (S8-3), return to Step 2.
Further, when the water surface rising time Tm is equal to or longer than the predetermined flow rate determination time T1 and less than the predetermined full water determination time T2 (T1 ≦ Tm <T2), the generation of dewed water is relatively slow. Judge (S7-4), execute the first action (S8-2), and return to step 2.
Furthermore, when the water surface rising time Tm is equal to or greater than the predetermined full water determination time T2 (T2 ≦ Tm), it is determined that the dew water pit 40 is full (S9), and it is determined that the action is not successful. Then, the cooling operation is stopped (OFF) (S10).

(Second action)
The second action is selected according to the length of the water surface rising time after the execution of the first action. In other words, since the water surface rise time reflects the amount of generated dew water per unit time, the shorter the water surface rise time, the greater the amount of dew water generated per unit time. .
Therefore, the action when the water surface rising time Tm is shorter than the predetermined time is referred to as a second action, and is made stronger than the first action (for example, the evaporation temperature of the refrigerant is increased by 1 ° C.) (for example, the evaporation of the refrigerant) Increase the temperature by 2 ° C or 3 ° C). Or you may determine the intensity | strength (for example, raise amount of the evaporating temperature of a refrigerant | coolant) of a 2nd action with the function of water surface rise time.

  In the present invention, the number of installed water level sensors 80 is not limited to two, and a total of three water sensors 83 may be installed in the indoor unit 300 (Embodiment 3). At this time, the determination whether or not the water is full is replaced with the fact that the full water sensor 83 is ON instead of the water surface rising time Tm being equal to or greater than the predetermined full water determination time T2 (T2 ≦ Tm). .

[Embodiment 5]
(Air conditioner indoor unit)
11 and 12 illustrate an indoor unit of an air conditioner according to Embodiment 5 of the present invention. FIG. 11 is a partial cross-sectional view in side view showing an enlarged part of the conditioner. These are flowcharts which show the control flow of an indoor unit. In addition, each figure is drawn typically and this invention is not limited to the form (Aspect ratio, thickness, etc. of a structural member) illustrated. In addition, the same reference numerals are given to the same or corresponding parts as in the first embodiment, and a part of the description is omitted.

In FIG. 11, an indoor unit (hereinafter sometimes abbreviated as “indoor unit”) 500 of an air conditioner 500 is replaced with a sewage level sensor 81 and an upper water level sensor 83 in the indoor unit 400 shown in the fourth embodiment. The water level change sensor 90 is installed on the pit wall 40c of the dew water pit 40, and the full water level sensor 82 is installed near the upper edge of the pit wall 40c.
That is, the water level change sensor 90 can detect the change speed of the surface of the dew water (the rising speed, the falling speed or the water surface height does not change). Similar effects can be obtained.

(Control flow)
In FIG. 12, when the cooling operation is started (ON) (S1), the control unit of the indoor unit 500 confirms that the cooling operation is performed (S2), and refers to the detection result of the water level change sensor 90. (S3-2).
Then, change the water level change sensor 90 is the water surface height ChakuRo water (hereinafter, referred to as "water rising speed") Ide such not detect Vm, still, when (S6 not running action, action duration When Hm is less than the predetermined determination time H2, Hm <H2), it is determined that there is no occurrence of dew water or is in the very initial stage of generation (S4), and no action is taken to prevent the generation of dew water (S5). Return to step 2 and repeat continuously.
Further, when the water level change sensor 90 does not detect the water surface rising speed Vm (Vm = 0) and the action duration time Hm has passed the predetermined determination time H2 (in S6, H2 ≦ Hm), Since the dew water pit 40 is full (S9), it is determined that the second action is not successful, and the cooling operation is stopped (OFF) (S10).

On the other hand, when the water level change sensor 90 detects an increase in the water level of the dew water ( 0 <Vm ), it is determined that the dew water has been generated ( S7 ), an action is executed (S8), and the process returns to step 2. At this time, according to the size of the water rise velocity Vm, it may change the intensity of the action. For example, when the water surface rising speed Vm is smaller than the predetermined rising speed V1, assuming that the amount of dew water generated per unit time is relatively small, the amount of increase in evaporation temperature is reduced (for example, 1 ° C.), When the water surface rising speed Vm is larger than the predetermined rising speed V1, the amount of dew water generated per unit time is relatively large and the amount of increase in evaporation temperature is increased (for example, 3 ° C.). Alternatively, the amount of increase in evaporation temperature may be determined by a function of the water surface rising speed Vm.

Further, when the water level change sensor 90 detects the lowering of the surface of the dew water (Vm <0), it is determined that the generation of the dew water has ended or the amount of the water has reached a very small amount (S4), and the action is stopped (S5). Return to 2.
In the above, the state in which the dew water pit 40 is full is determined based on the action duration time Hm after the action is executed. Instead, the water is near the upper edge of the pit wall 40c. A position sensor 82 (see Embodiment 3) may be additionally provided to detect the presence or absence of full water.

[Embodiment 6]
(Air conditioner indoor unit)
FIG. 13 explains an indoor unit of an air conditioner according to Embodiment 6 of the present invention, and is a partial cross-sectional view in side view showing an enlarged part of the conditioner. Note that FIG. 13 is schematically drawn, and the present invention is not limited to the illustrated form (aspect ratio and thickness of constituent members). In addition, the same reference numerals are given to the same or corresponding parts as in the first embodiment, and a part of the description is omitted.
In FIG. 13, an air conditioner indoor unit (hereinafter also abbreviated as “indoor unit”) 600 has a capacitance sensor 70 installed on the pit wall 40 c of the dew water pit 40.

(Capacitance sensor)
The capacitance sensor 70 detects a capacitance between a pair of conductors (not shown) and outputs a capacitance corresponding to the length of the conductor immersed in the dew water. . That is, it functions as a water level sensor that measures the water level of the dew water, and also functions as a water level change sensor that measures the amount of change per unit time of the water level of the dew water.
Therefore, the indoor unit 600 can execute any control of the indoor unit 200 (Embodiment 2) to the indoor unit 500 (Embodiment 5) by appropriately selecting the output from the capacitance sensor 70. In addition, it is possible to execute control in which these are appropriately combined.
In addition, one electrostatic capacity sensor 70 functions as a plurality of water level sensors 80, and is small and inexpensive. Therefore, it can be easily installed in the dew water pit 40, and the manufacturing cost is increased. Can be suppressed.

[Embodiment 7]
(Air conditioner indoor unit)
14 and 15 illustrate an indoor unit of an air conditioner according to Embodiment 7 of the present invention. FIG. 14 is a partial cross-sectional view in side view showing an enlarged part of the conditioner. These are flowcharts which show the control flow of an indoor unit. In addition, each figure is drawn typically and this invention is not limited to the form (Aspect ratio, thickness, etc. of a structural member) illustrated. In addition, the same reference numerals are given to the same or corresponding parts as in the first embodiment, and a part of the description is omitted.

In FIG. 14, an indoor unit (hereinafter, may be abbreviated as “indoor unit”) 700 of an air conditioner is the same between the sewage level sensor 81 and the full water level sensor 82 in the indoor unit 400 (Embodiment 4). In addition, a water drain hole (corresponding to the pool preventing means, hereinafter referred to as “wall water drain hole 44”) is formed.
In the indoor unit 200 to the indoor unit 700, the conditioned air passes through the air filter 2 to remove dust and the like, so that the water drain hole (hereinafter referred to as “bottom water drain hole”) 24 is prevented from being clogged. However, if the bottom water drain hole 24 is clogged for some reason, it is determined that the dew water pan 22 or the dew water pit 40 is full, and there is no possibility that the cooling operation will be stopped.
Therefore, in the indoor unit 700, a wall drain hole 44 is formed between a water level sensor (hereinafter referred to as “sewage level sensor”) 81 and a water level sensor (hereinafter referred to as “upper water level sensor”) 82, and temporarily Even when the bottom water drain hole 24 is blocked, it is possible to execute an action for preventing the occurrence of dewed water without stopping the cooling operation.

(Control flow)
15, when the cooling operation is started (ON) (S1), the control unit of the indoor unit 700 confirms that the cooling operation is being performed (S2), and refers to the detection result of the sewage level sensor 81. (S3). When the sewage level sensor 81 does not detect the dew water (OFF), it is determined that there is no dew water (S4), and the action for preventing the dew water generation is not executed (S5), step Return to 2. At this time, it may return continuously or at regular intervals.
On the other hand, when the sewage level sensor 81 has detected (ON) the ChakuRo water, above the water level sensor 83 refers to the detection results of ChakuRo water with (3 S6), the elapsed time from the sewage level sensor 81 is ON (Hereinafter referred to as “sensor elapsed time Sm”) ( S6-5 ).

When the water level sensor 83 does not detect dew condensation water (OFF) and the sensor elapsed time Sm is shorter than the predetermined sensor judgment time S1 (Sm <S1), there is no clogging and the initial generation of dew water. ( S7 ), the action is executed (execution start or execution continuation, S8), and the process returns to step 2.
Further, in the upper water level sensor 83 does not detect the ChakuRo water (OFF), and, (in 5 of S6, S1 ≦ Sm) when the sensor elapsed time S m is equal to or greater than a predetermined sensor determination time S1, the generation of ChakuRosui It is determined that the bottom drainage hole 24 is clogged despite the absence of the water (S7-5), the action is stopped (S5), and the process returns to Step 2.

Further, when the water level sensor 83 detects dew condensation water (ON) and the sensor-elapsed time Sm is shorter than the predetermined sensor judgment time S1 (S4 of S6, Sm <S1), the bottom water drain hole 24 Although it is clogged, it is determined that the generation of dew water has occurred (S7-6), the action is executed (S8), and the process returns to Step 2.
Further, when the water level sensor 83 detects dew water (ON) and the sensor elapsed time Sm is equal to or longer than the predetermined sensor judgment time S1 (S4 of S1 , S1 ≦ Sm), the bottom water drain hole 24 is clogged. Thus, it is determined that the dew water pit 40 is full (S9), and the cooling operation is stopped (OFF) (S10).
In addition, in the state where both the bottom water drain hole 24 and the wall water drain hole 44 are clogged, it is impossible to continue the cooling operation. Therefore, the duration time after the water level sensor 83 detects (ON) the dew water is set. Measurement may be made to notify that “both the bottom drain hole 24 and the wall drain hole 44 are clogged” when the duration exceeds a predetermined determination time.

Therefore, the indoor unit 700 can execute an action for preventing the occurrence of dewed water even when the bottom water drain hole 24 is clogged.
In addition, arrangement | positioning of the water level sensor 80 in the indoor unit 700 is not limited to what is illustrated. For example, one or more of the water level sensor 80, the water level change sensor 90, or the capacitance sensor 70 may be installed in one or both of the range below or above the wall drain hole 44. Furthermore, two or more wall drain holes 44 may be provided, and one or two or more water level sensors 80 may be installed between them.

[Embodiment 8]
(Air conditioner indoor unit)
FIG. 16 is an overall cross-sectional view illustrating a cross section of the air conditioner viewed from the front, explaining an indoor unit of an air conditioner according to Embodiment 8 of the present invention. In addition, each figure is drawn typically and this invention is not limited to the form (Aspect ratio, thickness, etc. of a structural member) illustrated. Further, the same or corresponding parts as those in the first embodiment may be given the same numerals in the second digit of the reference numerals, and some explanations may be omitted.

(Indoor unit body)
In FIG. 16, an air conditioner indoor unit (hereinafter sometimes abbreviated as “indoor unit”) 800 is installed on an indoor ceiling 1000 and includes a main body top plate 816 and four main bodies. It is a rectangular box formed from the side plate 817, and a suction port 811 is arranged at the center of the lower surface, and blowout ports 815 are arranged at four locations along the four main body side plates 817, respectively. A blower (same as an axial fan) 804 is installed directly above the suction port 811 (substantially the center of the indoor unit main body 810).

Then, from the suction port 811 to the blower 804 (same on the upstream side), the suction air passage 801 through which the sucked room air flows, and from the blower 804 to the blowout port 815 (same on the downstream side) blown out conditioned air A blowing air passage 805 through which the air flows is formed. The suction air passage 801 is provided with an air purification filter 802 through which sucked room air passes and dust contained therein is removed.
On the other hand, a heat exchanger 803 that cools or heats indoor air that has passed through the air purification filter 2 is disposed in the blowout air passage 805. The indoor air that has passed through the heat exchanger 803 is referred to as “conditioned air”.

At this time, since the blower 804 sucks room air from the bottom to the top and blows it out in a substantially horizontal direction (substantially in the radial direction), the heat exchanger 803 is arranged in a substantially rectangular shape in plan view and surrounds the blower 804. (Also arranged along the four main body side plates 817 of the indoor unit main body 810).
Further, a main drain pan 806 is disposed below the heat exchanger 803 to receive moisture (dew condensation water or the like) adhering to the heat exchanger 803 when dripping. That is, the main drain pan 806 is also formed in a substantially rectangular shape in plan view. A heat exchanger (corresponding to an indoor heat exchanger) 803 constitutes a refrigeration cycle together with a refrigerant compressor, an outdoor heat exchanger, and refrigerant expansion means installed in an outdoor unit (not shown). By changing the flow of the refrigerant, it functions as a condenser (releases hot heat) and an evaporator (releases cold heat).

(Blowout wind path)
The blowout air passage 805 has a substantially Γ (gamma) shape in a front view, and is disposed in the vicinity of the main body top plate 816 in parallel with the main body upper discharge wall (same as the air passage wall) 812a, A main body middle blowing wall (same as an air passage wall) 812b arranged in a range close to the main body top plate 816 and parallel to the main body side plate 817, and a main body middle blowing wall 812b. A main body lower outlet wall (same as the air channel wall) 812c arranged in a range parallel to the side plate 817 and close to the outlet port 815, and a substantially horizontal pan upper outlet wall (same as the air channel wall) forming the main drain pan 806 813a and a substantially vertical pan lower blowout wall (same as the air channel wall) 813c forming the main drain pan 806.

Hereinafter, for the sake of convenience, the blow-out air passage 805 passes through the horizontal flow portion 805a in which conditioned air flows in a substantially horizontal direction between the outlet side of the blower 804 and the heat exchanger 803, and then passes through the heat exchanger 803. The direction changing portion 805b that changes the flow direction and the vertical flow portion 805c that flows substantially vertically downward toward the blowout port 15 are described below. However, the respective boundaries are not always clear.
And the horizontal flow part 5a is formed of the main body upper blowing wall 812a and the bread upper blowing wall 813a. Further, the direction changing portion 805b is formed by the main body outlet wall 812b and the heat exchanger 803, and the vertical flow portion 805c is formed by the main body outlet wall 812c and the pan lower outlet wall 813c.

(Frosting water discharge part)
In FIG. 16, the frosted water discharge unit 20 is formed on the surface of the direction changing unit 805 b that is not touched by the conditioned air (same as the surface on the anti-airway side).
The frosted water discharge part 20 is formed on the main body outlet wall 812b, and has a slit-like opening 21 through which dew condensation water can pass, and a surface of the main body outlet wall 812b on the side opposite to the wind path below the slit-like opening 21. And a dew water pan 22 that receives the dew water that has passed through the slit-shaped opening 21 and entered the opposite wind path side of the main body blowout wall 812b (see FIGS. 4 and 5).

Further, a sub-drain pan 807 for receiving moisture adhering to the surface on the counter-air passage side of the main body outlet wall 812b is provided on the surface on the side of the main air outlet wall 812b opposite to the air path. It is led to the main drain pan 806 by the drainage channel that does not.
When the dew water flowing into the dew water pan 22 overflows from the upper edge of the pan end plate 22c, the dew water flows into the sub drain pan 807 and is guided to the main drain pan 806 via a drainage channel (not shown). Further, the water stored in the main drain pan 806 (which may not include dew condensation water) is guided to an outdoor unit (not shown) by a discharge means (not shown).

  The present invention is not limited to the illustrated form of the dew water pan 22; for example, the pan end plate 22c may be removed so that the dew water flows out from the end of the pan bottom plate 22a. Alternatively, the dew water pan 22 itself may be removed so that the dew water flows directly into the auxiliary drain pan 7 (at this time, the dew water is not stored (does not accumulate) in the dew water pan 22). ). Alternatively, the dew water stored in the dew water pan 22 may be guided directly to the main drain pan 6 without passing through the sub drain pan 7.

  A water level sensor 80 is installed in the dew water pan 22 and an action for preventing the occurrence of dew water is executed as in the indoor unit 200 (Embodiment 2). One or more water level displacement sensors 90 or capacitance sensors 70 may be installed. Further, according to the indoor unit 700 (Embodiment 7), one or two or more wall drain holes 44 may be provided in the dew condensation water pan 22.

[Embodiment 9]
(Air conditioner indoor unit)
FIG. 17 is an overall cross-sectional view illustrating a cross section of the air conditioner viewed from the front, explaining an indoor unit of an air conditioner according to Embodiment 9 of the present invention. In addition, each figure is drawn typically and this invention is not limited to the form (Aspect ratio, thickness, etc. of a structural member) illustrated. Further, the same or corresponding parts as those in the first embodiment may be given the same numerals in the second digit of the reference numerals, and some explanations may be omitted.

(Indoor unit body)
In FIG. 17, an air conditioner indoor unit (hereinafter sometimes abbreviated as “indoor unit”) 900 is installed on an indoor wall surface (not shown), and has a suction port 911 on its upper surface. An indoor unit body 910 having an air outlet 915 formed on the lower surface, a blower (same as a cross-flow fan) 904 installed in the indoor unit body 910, and a makeup covering the front surface (left side in the figure) of the indoor unit body 910 A panel 918.
And from the inlet 911 to the blower 904 (same on the upstream side), the suction air passage 901 through which the sucked room air flows, and from the blower 904 to the outlet 915 (same on the downstream side) blown out conditioned air A blowing air passage 905 through which the air flows is formed. The suction air passage 901 includes an air purification filter 902 through which the sucked room air passes and the contained dust is removed, and a heat exchanger 903 that cools or heats the room air that has passed through the air purification filter 902. Has been placed. The indoor air that has passed through the heat exchanger 903 is referred to as “conditioned air”.

At this time, since the blower 904 sucks room air from above and from the front, the heat exchanger 803 is arranged in a substantially Λ (lambda) shape in a front view.
Furthermore, main drain pans 906a and 906b that receive moisture (dew condensation water or the like) that has adhered to the heat exchanger 903 are disposed below the heat exchanger 903. A heat exchanger (corresponding to an indoor heat exchanger) 903 constitutes a refrigeration cycle together with a refrigerant compressor, an outdoor heat exchanger, and refrigerant expansion means installed in an outdoor unit (not shown). By changing the flow of the refrigerant, it functions as a condenser (releases hot heat) and an evaporator (releases cold heat).

(Blowout wind path)
The blowout air passage 905 has a substantially arc shape when viewed from the front, and includes a rear blowout wall (same as the airway wall) 912 that forms a part of the indoor unit main body 910, and a front blowout that is a rear surface or a lower surface of the main drain pan 906a. A wall (same as the air passage wall) 913.
And the frost water discharge part 20 is formed in the surface (it is the same as the surface on the anti-airway side) where the conditioned air does not touch at a position slightly close to the air outlet 915 in the middle of the rear outlet wall 912 in the vertical direction. Yes.
The frosted water discharge part 20 is installed on the surface of the rear air outlet side of the rear outlet wall 912 below the slit opening 21 formed in the rear outlet wall 912 and through which the dew condensation water can pass. And a dew water pan 22 that receives the dew water that has passed through the slit-shaped opening 21 and entered the anti-wind passage side of the rear outlet wall 912 (see FIGS. 4 and 11).

  Then, the dew water flowing into the dew water pan 22 (through a drain hole not shown and overflowed) is guided to the main drain pan 906a by a drain channel and pump means (not shown). Further, the water stored in the main drain pan 906a (which may not include dew condensation water) is guided to an outdoor unit (not shown) by a discharge means (not shown).

  A water level sensor 80 is installed in the dew water pan 22 and an action for preventing the occurrence of dew water is executed as in the indoor unit 200 (Embodiment 2). One or more water level displacement sensors 90 or capacitance sensors 70 may be installed. Further, according to the indoor unit 700 (Embodiment 7), one or two or more wall drain holes 44 may be provided in the dew condensation water pan 22.

  According to the present invention, even if dew condensation water occurs at any position in a wide range in the air passage, dew dripping can be prevented, and the occurrence of dew condensation water can be detected at an early stage. Therefore, it can be widely used as an indoor unit of various types of air conditioners.

  1: suction air path, 2: air purification filter, 3: heat exchanger, 4: blower, 5: blowout air path, 5a: horizontal flow part, 5b: arc flow part, 5c: vertical flow part, 6: main drain pan 7: Sub-drain pan, 8: Sub-drain pan, 10: Indoor unit body, 11: Suction port, 12: Large-diameter outlet wall, 12a: Large-diameter horizontal wall portion, 12b: Large-diameter arc wall portion, 12c: Large-diameter vertical Wall part, 12d: Large-diameter arc wall extension part, 12e: Extension part lower end, 13: Small-diameter blowing wall, 13b: Small-diameter arc wall part, 13c: Small-diameter vertical wall part, 14: End blowing wall, 15: Outlet, 16: Drainage channel, 20: Frosted water discharge part, 21: Slit-shaped opening, 22: Dew water pan, 22a: Bread bottom plate, 22b: Bread side plate, 22c: Bread end plate, 23: Moisture permeable membrane, 24 : Water drain hole (bottom water drain hole), 25: gap, 26: protrusion, 30: frost water drain Part, 31: slit-shaped opening, 32: dew water pan, 32a: bread bottom plate, 32b: bread side plate, 32c: bread end plate, 40: frost water pit, 40a: pit bottom, 40c: pit wall, 44: Wall drain hole, 70: capacitance sensor, 80: water level sensor, 80a: conductor, 80b: conductor, 81: sewage level sensor, 82: full water level sensor, 83: water level sensor, 90: water level displacement sensor, 100: Indoor unit (Embodiment 1), 200: Indoor unit (Embodiment 2), 300: Indoor unit (Embodiment 3), 400: Indoor unit (Embodiment 4), 500: Indoor unit (Implementation) Embodiment 5), 600: Indoor unit (Embodiment 6), 700: Indoor unit (Embodiment 7), 800: Indoor unit (Embodiment 8), 801: Suction air path, 802: Air purification filter, 803: heat exchanger, 804 Blower, 805: Air outlet, 805a: Horizontal flow portion, 805b: Direction change portion, 805c: Vertical flow portion, 806: Main drain pan, 807: Sub drain pan, 810: Indoor unit main body, 811: Suction port, 812a: Main body Upper outlet wall, 812b: main body inner outlet wall, 812c: main body inner outlet wall, 813a: pan upper outlet wall, 813c: pan lower outlet wall, 815: outlet, 816: main body top plate, 817: main body side plate, 900: Indoor unit (Embodiment 9), 901: Suction air path, 902: Air purification filter, 903: Heat exchanger, 904: Blower, 905: Blow air path, 906a: Main drain pan, 910: Main body of indoor unit, 911: Suction port, 912: rear outlet wall, 913: front outlet wall, 915: outlet, 918: decorative panel, 1000: ceiling, Dm: sensor elapsed time, H1: predetermined time, H2 : Judgment time, Hm: Action duration, S1: Judgment time, Sm: Sensor elapsed time, T1: Flow rate judgment time, T2: Full water judgment time, Tm: Water surface rise time, V1: Predetermined rise speed, Vm: Water surface rise Speed.

Claims (2)

An indoor unit body in which a suction port and an air outlet are formed;
An air passage wall that forms an air passage from the suction port to the air outlet;
A blower and a heat exchanger disposed in the air passage;
A main drain pan that receives moisture dripping from the heat exchanger;
One or a plurality of slit-like openings that are formed at a position closer to the air outlet than the blower of the air passage wall, and through which dew condensation water attached to the air passage side surface of the air passage wall can pass freely;
A dew water pan that is formed on the surface of the air passage wall on the side opposite to the air flow path below the slit opening and into which the dew water that has entered the air passage side of the air passage wall passes through the slit opening. When,
One or more drainage channels for allowing the dew water flowing out of the dew water pan to flow into the main drain pan for drainage;
Have
A full water discharge means formed in the dew water pan for discharging dew water flowing into the drainage channel over a certain amount;
A pool prevention means formed on the dew water pan for preventing the dew water flowing in and stopping the drain water;
A water level sensor that is installed in the dew water pan and detects that dew water has flowed into the dew water pan;
Have
A sub-drain pan constituting a part of the drainage channel is installed on the surface of the wind channel wall on the side opposite to the wind channel, and the dew water overflowing through the full water discharge means flows into the sub-drain pan,
On the surface of the air channel wall on the side opposite to the air channel, a dew water pan is formed above the slit opening and covers the dew water pan. Moisture that has flowed through the lower surface of the dewdrop water pan dripping onto the dewdrop water pan and adheres to the surface of the wind channel wall on the side opposite to the wind channel flows down the upper surface of the dewwater pan pan. An indoor unit of an air conditioner, wherein the indoor unit is dropped on the sub-drain pan. The slit-shaped opening adhering to the surface of the air passage side of the air passage wall and flowing down is allowed to pass through, and the air blown out by the blower is blocked by a moisture permeable membrane that is difficult to pass through. The indoor unit of the air conditioner according to claim 1 .

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