JP2010038490A - Ceiling embedded type air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a ceiling embedded type air conditioner capable of preventing dew condensation, and suppressing generation of noise. <P>SOLUTION: This ceiling embedded type air conditioner 100 has an air guide 18 for covering an upper part of a drain pan supply air trunk-side side wall 5a1 of a drain pan 5 and a body side plate 10b side at a prescribed interval. The air guide 18 comprises a flat air guide inlet introducing section 18a, a curved air guide corner section 18b, and a flat air guide supply section 18c, the air guide inlet introducing section 18a is positioned between a lower end 1ba of a supply opening 1b of a turbo fan 1 and an upper end 5a3 of the drain pan supply air trunk-side side wall 5a1 in the height direction, an inlet tip section 18a1 of the air guide inlet introducing section 18a is positioned near a face 16a at a downstream-side of a heat exchanger 16 in the horizontal direction, and a lower end of the air guide supply section 18c is positioned below the upper end of the drain pan supply air trunk-side side wall 5a1 in the height direction. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a ceiling-embedded air conditioner, and more particularly, to a ceiling-embedded air conditioner having a main body embedded in the back of a ceiling and a decorative panel installed on substantially the same surface as the ceiling.

2. Description of the Related Art Conventionally, ceiling-embedded air conditioners have been known in which an air guide is provided in a blowing air path from a blowing surface of a heat exchanger to a panel blowing outlet in order to save energy and reduce noise.
For example, an air guide is inserted between the fins of the heat exchanger, and the blowout air passage is divided into a main flow and a subflow. An invention that suppresses an increase in pressure loss due to a reduction in the effective air path by pushing to the side is disclosed (see, for example, Patent Document 1).
Moreover, the invention which has an air guide supported by the drain pan and installed so that it may become substantially parallel to a side wall is disclosed (for example, refer patent document 2).

JP 2000-193264 A (page 3-4, FIG. 1) JP 2003-74960 A (page 2-4, FIG. 1)

In the invention disclosed in Patent Document 1, although the secondary flow pushes the main flow toward the outer wall side and the reduction of the effective air flow path can be suppressed, the flow speed of the secondary flow is small compared to the flow speed of the main flow, and the blowing air flow path A large wind speed difference occurs from the heat exchanger side to the outer wall side. For this reason, there has been a problem that pressure loss in the blowout air passage increases, fan motor power increases, and noise increases.
In addition, since the air guide is inserted between the fins of the heat exchanger, there is a problem that condensed water condensed on the heat exchanger may drop on the room from the panel outlet through the air guide and contaminate the floor. .

Furthermore, the invention disclosed in Patent Document 2 cannot suppress the flow that rises while accelerating the surface of the drain pan from the bottom of the drain pan toward the uppermost end of the side wall, and heat exchange in the vicinity of the drain pan is prevented by this rising flow. The flow after passing through the vessel is pushed upward. For this reason, in order to suppress the separation vortex on the side surface of the outlet of the drain pan, there is a problem that the air guide needs to be protruded larger than the uppermost end of the drain pan side wall.
Moreover, since peeling at the drain pan side wall uppermost end portion cannot be suppressed, there is a problem that noise increases.

  The present invention solves the above-described problems, and an object of the present invention is to provide a ceiling-embedded air conditioner that can prevent condensation and suppress generation of noise.

The ceiling-embedded air conditioner according to the present invention is a box-shaped main body that is embedded in the back of the ceiling and is formed of a main body top plate and a main body side plate, and has an open bottom.
A turbofan housed in the main body and fixed to the center of the main body top plate;
A heat exchanger housed in the main body and installed to surround the turbofan;
A bowl-shaped drain pan that is housed in the main body and into which the lower end of the heat exchanger has entered,
An air guide that covers the upper side of the drain pan outlet side wall and the main body side plate side of the drain pan near the main body side plate with a predetermined interval;
A decorative panel that covers a lower portion of the main body and includes a panel suction port formed in the center and a panel outlet formed near the periphery,
Have
The air guide includes a flat air guide inlet introduction part, a curved air guide corner part continuous with the air guide inlet introduction part, and a flat air guide outlet part continuous with the air guide corner part. And
The air guide inlet introduction part is located between the lower end of the blower outlet of the turbofan and the upper end of the drain pan outlet side wall, and the front end of the inlet of the air guide inlet introduction part is horizontal. In the direction, located near the downstream surface of the heat exchanger,
The lower end of the air guide outlet is in the height direction and is located below the upper end of the drain pan outlet side wall.

According to the ceiling-embedded air conditioner of the present invention, the air guide inlet introduction portion of the air guide is positioned in the height direction above the upper end of the drain pan outlet side wall forming the drain pan, and the turbofan It is located below the lower end of the air outlet. For this reason, the air guide does not become a mainstream ventilation resistance blown directly from the turbo fan toward the heat exchanger directly to the heat exchanger, and it cannot pass through the heat exchanger and is not between the turbo fan and the heat exchanger. Since only the flow in the vicinity of the inner drain pan of the side flow that circulates while passing through the heat exchanger is rectified, the ventilation resistance to the turbo fan is reduced and the fan motor power can be reduced.
In addition, the air guide inlet introduction portion has a front end portion away from the vicinity of the surface on the downstream side of the heat exchanger by a predetermined distance and covers the upper side of the drain pan outlet side wall, so that the drain pan outlet side from the drain pan bottom side The flow that rises while increasing the speed along the side wall can be received and prevented from rising, and can be made to flow downward along the air guide corner portion and the air guide blowing portion. That is, the main flow that has passed through the heat exchanger is not pushed upward, and the separation vortex on the drain pan side wall due to the side flow can be suppressed.
Furthermore, it is possible to prevent dew from dropping into the room even when the condensed water of the heat exchanger is directly transmitted, or even when the air guide itself cooled by direct heat transfer from the heat exchanger is condensed.
Furthermore, when stacking and storing the drain pan with the air guide integrally attached, the air guide does not pierce the drain pan, so that the drain pan is prevented from being damaged and water leakage does not occur after assembly.
Therefore, a high-quality ceiling-embedded air conditioner that provides an energy saving effect and a low noise effect can be obtained.

[Embodiment 1: Ceiling embedded air conditioner]
Hereinafter, a ceiling-embedded air conditioner according to Embodiment 1 of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals.
1 to 8 illustrate a ceiling-embedded air conditioner according to Embodiment 1 of the present invention. FIG. 1 is an external view when the room is installed, and FIG. 2 is a ceiling-embedded air conditioner shown in FIG. 3 is a horizontal cross-sectional view of the air conditioner, FIG. 3 is a vertical cross-sectional view of the ceiling-embedded air conditioner shown in FIG. 1 (cross-sectional view in the XX cross section of the horizontal cross-sectional view shown in FIG. 2), and FIG. FIG. 5 is a partially enlarged view of a part (outlet air passage), FIG. 5 is a partially enlarged view of a part of FIG. 4 (near the air guide), and FIG. 6 is a perspective view of the air guide shown in FIG. 7 is a perspective view of the air guide shown in FIG. 5 viewed from the outer wall surface side of the air guide, and FIG. 8 is a longitudinal sectional view showing a portion (drain pan) of the ceiling-embedded air conditioner shown in FIG. It is sectional drawing in the XOYYZ cross section of a horizontal sectional view.

(Main unit)
1 and 3, a ceiling-embedded air conditioner (hereinafter referred to as “air conditioner”) 100 includes a main body 10 embedded in a ceiling back 92 and a decorative panel 11 covering one surface of the main body 10. Have. The main body 10 is a box with one side open, and is formed of a rectangular main body top plate 10a and four main body side plates 10b connected to the main body top plate 10a.
The decorative panel 11 has a substantially rectangular plate shape, is arranged in parallel with the main body top plate 10 a, is attached so as to contact the ceiling 91 of the room 90, and faces the room 90. A suction grill 11 a that is an air inlet to the main body 10 is formed near the center of the decorative panel 11, and a panel outlet that is an air outlet from the main body 10 is formed near the outer periphery of the decorative panel 11. 11b is formed along each side.
Further, a filter 12 for removing dust after passing through the suction grill 11a is installed on the downstream side (the main body 10 side) of the suction grill 11a, and a wind direction vane 13 for adjusting the wind direction is installed at the panel outlet 11b. Has been.

(Drain pan)
2 or 3, the main body 10 includes a fan motor 15 fixed at the center of the main body top plate 10a, a turbo fan 1 that is rotationally driven by the fan motor 15, and a suction air passage for the turbo fan 1. A bell mouth 14 to be formed, a heat exchanger 16 formed in a substantially quadrangular shape in a plan view so as to surround the outer peripheral side of the turbofan 1 (a cylindrical section having a partly opened in the axial direction), Are installed.
The heat exchanger 16 is connected to an outdoor unit (not shown) by a connection pipe (not shown).
In addition, a drain pan 5 for receiving condensed water dewed on the heat exchanger 16 is disposed below the heat exchanger 16. The drain pan 5 has a concave drain pan flange 5a (see FIG. 4) having a side wall so as to receive condensed water, and a drain pan outlet 5b constituting the main body outlet 10d.

(Blowout wind path)
And the main body heat insulating material 10e is installed in the inner surface of the main body top plate 10a and the main body side plate 10b so that the blowing air path 10f may be formed along the main body heat insulating material 10e. Moreover, the outer side wind path wall 10f1 is comprised by the drain pan blowing part 5b and the blowing wind path 10f.
The upstream side of the blowout air passage 10 f communicates with a main body suction port 10 c installed at the center of the lower surface of the main body 10 and a suction grill 11 a formed at the center of the decorative panel 11. Further, the downstream side (blowing side) of the blowout air passage 10 f communicates with a panel blowout port 11 b formed near the periphery of the decorative panel 11.

(Air guide)
FIG. 4 shows an enlarged view of the fan blowout air passage 2 from the fan blower outlet 1b to the heat exchanger 16 and an elbow-shaped blowout air passage 10f that passes through the heat exchanger 16 and reaches the main body air outlet 10d. Has been. In FIG. 4, the air guide 18 is attached below the fan blower outlet lower end part 1ba of the fan blower outlet 1b on the drain pan outlet side wall 5a1 of the drain pan flange part 5a.

  5 to 7, the air guide 18 is open at the heat exchanger 16 side and below, and is substantially perpendicular to the heat exchanger 16 (same as substantially horizontal), the air guide inlet introduction portion 18 a, and the heat exchanger 16. An air guide outer wall surface 18f that is substantially parallel to (substantially vertically), and an air guide corner portion 18b having an arc-shaped cross section that smoothly connects the air guide inlet introduction portion 18a and the air guide outer wall surface 18f. Yes. An air guide mounting portion 18d that is orthogonal to both the air guide inlet introduction portion 18a and the air guide outer wall surface 18f and is joined to each of the air guide inlet introduction portion 18a, the air guide corner portion 18b, and the air guide outer wall surface 18f. Are arranged at predetermined intervals.

  That is, the inlet front end portion 18a1 of the air guide inlet introduction portion 18a has a predetermined distance H1 upward (in the direction of the main body top plate 10a) from the drain pan side wall uppermost end 5a3 of the drain pan outlet air passage side wall 5a1 of the drain pan flange portion 5a in the vertical direction. It is separated from the heat exchanger downstream surface 16a of the heat exchanger 16 by a predetermined distance L1 on the outside in the horizontal direction (in the direction of the main body side plate 10b). The inlet tip 18a1 of the air guide inlet introduction portion 18a is formed in a substantially arc shape (substantially cylindrical shape) in the longitudinal direction (horizontal direction) so that the side facing the heat exchanger 16 is an arc. (See FIG. 6).

(Air guide outlet)
The range near the lower end of the air guide outer wall surface 18f is substantially parallel to the drain pan outlet side wall 5a1 of the drain pan flange 5a and is separated by a predetermined horizontal distance L2. That is, an air guide blowing portion 18c sandwiched between a range near the lower end of the air guide outer wall surface 18f and the drain pan blowing air passage side wall 5a1 is formed.
That is, the air guide outlet 18c extends toward the main body outlet 10d so as to be substantially parallel to the drain pan outlet side wall surface 5b1 of the drain pan outlet 5b, and in the height direction, the drain pan flange 5a and the drain pan flange 5a. Between the upper end portion 5a3 of the drain pan side wall and a step 5d in a direction in which the short side dimension of the blowout outlet is enlarged on the side surface of the blowout air passage 10f of the drainpan blowout air passage side wall 5a1, The part exit side end 18c1 is formed to be substantially the same height as the step 5d.

Further, the air guide corner portion 18b is connected to the air guide inlet introduction portion 18a and the air guide blowout portion 18c, is formed with a curved surface that protrudes outward, and the air guide mounting portion 18d that extends from the air guide 18 causes a drain pan. It is fixed to the drain pan outlet side wall 5a1 of the flange 5a (see FIGS. 5 and 6).
The distance H1 between the air guide inlet introducing portion 18a and the drain pan side wall upper end 5a3 of the drain pan outlet side wall 5a1 of the drain pan flange 5a is the closest distance L2 between the drain pan outlet side wall 5a1 and the air guide outlet 18c. , And at least the air guide inlet introduction portion 18a to the air guide corner portion 18b so that the relationship between the closest distance L3 between the drain pan outlet side wall 5a1 and the air guide corner portion 18b is “H1> L3 ≧ L2”. It is formed to gradually shrink.
Further, a concave groove 6 extending from the air guide inlet introducing portion 18a to the air guide blowing portion 18c is formed on the air guide outer wall surface 18f facing the main body side plate 10b of the air guide 18 (FIGS. 6 and 6). 7).

  The air guide mounting portion 18d does not protrude from the inlet tip portion 18a1 of the air guide inlet introduction portion toward the heat exchanger 16, but at least at both longitudinal end portions 18e of the air guide 18, and the blowout air passage 10f is provided with air. The inner air passage B1 surrounded by the guide 18 and the drain pan outlet air passage side wall 5a1 is formed so as to be separated from the other outer air passage B2, and has a substantially U shape so as to sandwich the air guide inlet introduction portion 18a1. It is formed (see FIGS. 5 and 6).

In FIG. 8, the height M1 from the bottom surface of the drain pan flange 5a of the drain pan 5 to the uppermost end of the air guide 18 in a state where the air guide 18 is attached to the drain pan outlet side wall 5a1, the outside of the substantially square drain pan 5 The relationship between the height M2 from the drain pan bottom surface of the drain pan corner portion 5c excluding the drain pan blowing portion 5b in the air passage wall 10f1, and the height M3 from the drain pan bottom surface of the outer wind passage wall 10f1 corresponding to the drain pan blowing portion 5b, The outer air passage wall 10f1 of the drain pan 5 is formed so that at least “M2> M1”, the air guide 18 is lower than the drain pan corner portion 5c, and the four drain pan corner portions 5c have the same height. Yes.
Moreover, in FIG. 8, it forms so that it may become "M1> = M3", and the main body heat insulating material 10e and the drain pan 5 are formed so that it may engage in uneven shape.

  As shown in FIG. 2, the air guide longitudinal direction both ends 18e are formed at a position separated by a predetermined distance L4 from the drain pan outlet part side face 5b2 of the drain pan outlet 5b which is the longitudinal end of the main body outlet 10d. Yes.

(Wind flow)
In the air conditioner 100 configured as described above, when the turbo fan 1 rotates, the air in the room 90 passes through the suction grille 11a and the filter 12 of the decorative panel 11 and is removed (see FIG. 1), and the main body suction port 10c, After passing through the bell mouth 14, it is sucked into the turbo fan 1 (see FIG. 3) and blown radially from the turbo fan 1 toward the heat exchanger 16 on the downstream side (see FIG. 2). Then, the air that has been subjected to heat exchange or dehumidification such as heating or cooling in the heat exchanger 16 passes from the heat exchanger 16 to the main body outlet 10d through the elbow-shaped outlet air passage 10f, and communicates with the room from the communicating panel outlet 11b. The air is blown to the airflow direction controlled by the airflow direction vane 13 and air-conditioning is performed (see FIGS. 3 and 4).

In FIG. 4, in the blowout air passage 10f, immediately after the blowout from the turbo fan 1, a main flow C1 that passes through the heat exchanger 16 and flows into the blowout air passage 10f is formed. Furthermore, the fan blowout air path 2 between the turbofan 1 and the heat exchanger 16 below the fan outlet 1 b of the turbofan 1 cannot pass through the heat exchanger 16 immediately after blowing out from the turbofan 1. A side stream C2 passing through the heat exchanger 16 is formed while swirling inside. Then, the main stream C1 and the substream C2 merge and flow toward the main body outlet 10d.
At this time, the side flow C2 passes through the heat exchanger 16 and goes to the blowout air passage 10f, and passes through the concave drain pan flange portion 5a and the drain pan discharge portion side wall 5a1 of the drain pan flange portion to the drain pan side wall uppermost end 5a3. The substream C22, which is an upward flow that accelerates toward the front, is generically named, and a part of the substream C21 and the substream C22 are joined and rectified by the air guide 18 in the inner air passage B1 of the air guide 18. Is done. Further, the remaining side flow C21 is rectified by the air guide outer wall surface 18f of the air guide 18, and is blown into the room 90 through the main body outlet 10d and the panel outlet 11b together with the main stream C1 to be air-conditioned.

In the air guide 18 formed in this way, the air guide inlet introduction portion 18a is located below the fan outlet lower end portion 1ba of the fan outlet 1b of the fan side plate 3, and therefore toward the heat exchanger 16. Ventilation resistance is not provided to the mainstream C1 that is directly blown from the turbo fan 1 and contributes to the ventilation resistance of the turbo fan.
Further, the air guide inlet introduction portion 18a is separated from the heat exchanger downstream surface 16a by a predetermined distance L1 in the horizontal direction, and upward from the drain pan side wall upper end 5a3 of the drain pan outlet side wall 5a1 of the drain pan flange portion 5a in the vertical direction ( Since it has a flat shape that is separated by a predetermined distance H1 in the direction of the main body top plate 10a and extends substantially horizontally from the portion corresponding to the drain pan flange 5a, the drain pan surface is increased from the drain pan flange 5a toward the drain pan side wall uppermost end 5a3. Since the flow that has passed through the heat exchanger 16 cannot be pushed upward by the flow side flow C22 that rises at high speed, the separation vortex at the drain pan side wall uppermost end 5a3 due to the side flow C22 and the drain pan outlet side wall 5a1 of the drain pan 5 It is possible to suppress the separation vortex on the surface of the film.

Furthermore, since the air guide inlet introduction part 18a is flat from the inlet front end part 18a1 to the position corresponding to the uppermost end part 5a3 of the drain pan outlet side wall 5a1 of the drain pan flange part 5a in the horizontal direction, When the flow side stream C22 rising on the air passage side wall 5a1 and the flow side stream C21 passing through the heat exchanger 16 and flowing into the air guide 18 merge, they are not suddenly turned. Therefore, the flat portion can be gradually rectified before flowing into the air guide corner portion 18b and the air guide blowing portion 18c as a running section, and noise due to turbulence at the time of merging can be suppressed.
It should be noted that some warping occurs at the time of molding, and the change in the above effect is small even if it has a wavy shape.

Further, when the drain pan 5 is stacked and stored as a part, the air guide 18 contacts the drain pan 5 on a flat surface, so that the air guide 18 does not pierce the drain pan 5 and the quality of the part is ensured. For example, if it is 10 mm or more, the rectifying effect and the drain pan 5 can be prevented from being damaged.
Furthermore, since the heat exchanger 16 and the air guide inlet introduction part 18a1 are separated from each other, when condensed water is directly transmitted or when the air guide 18 itself cooled by direct heat transfer from the heat exchanger 16 is condensed, The (dew) is prevented from dripping into the room 90. For example, if it is 2 mm or more away, even if a water droplet is transmitted on the heat exchanger downstream surface 16 a, it will not drop on the air guide 18, and if it is 5 mm or more away, dripping can be reliably avoided.

  Further, since the air guide inlet introduction portion 18a1 facing the heat exchanger 16 is formed in a substantially arc shape extending in the longitudinal direction, local pressure fluctuations in the air guide inlet introduction portion 18a1 are alleviated and peeling is also suppressed. The Moreover, when it forms in a column shape like FIG. 6, the intensity | strength of the air guide 18 can increase further.

  Since the air guide corner portion 18b has an arc shape in cross section, the air guide inner wall surface 18g on the side of the drain pan 5 of the air guide 18 rectifies the side flow C21 and the side flow C22 that are wind flows from the air guide inlet introduction portion 18a. However, the air guide can be smoothly guided to the air guide outlet 18c. Further, the air guide outer wall surface 18f of the air guide 18 can guide the substream C21, which is a flow passed from the heat exchanger 16, to the air guide outlet 18c without being smoothly peeled off due to the Counder effect.

Further, the air guide outlet 18c is directed toward the main body outlet 10d at a position separated from the drain pan outlet side wall 5a1 of the drain pan flange 5a of the outlet air passage 10f by a predetermined distance L2 toward the main body outlet 10d, and the drain pan outlet of the drain pan outlet 5b. Since it extends so as to be substantially parallel to the side wall surface 5b1, the flow of the air guide inner wall surface 18g is further rectified in the gap with the drain pan side wall, and the main flow C1 and the side flow C21 are rectified on the air guide outer wall surface 18f. Can join.
Further, in the height direction, the blower outlet short dimension is expanded on the side surface of the outlet air passage 10f of the drain pan outlet side wall 5a1 between the drain pan flange 5a and the drain pan side wall uppermost end 5a3 of the drain pan flange 5a. Since the air guide outlet 18c1 of the air guide outlet 18c has a level difference 5d and is formed so as to have substantially the same height as the level difference 5d, the level difference 5d immediately after exiting the air guide 18 is obtained. As a result, a negative pressure is generated, so that the flow is attracted to the drain pan surface, the shear disturbance on the drain pan surface is reduced, and the noise is reduced.

  As a result, the entire air flow is rectified by the air guide 18 and flows into the panel outlet 11b on the downstream side. For this reason, since pressure fluctuation is not given to the wind direction vane 13 arrange | positioned at the panel blower outlet 11b, it can achieve noise reduction and the effective blowing area which was reduced by peeling conventionally is expanded. Ventilation resistance can be reduced.

Further, as shown in FIG. 8, the distance H1 between the air guide inlet introducing portion 18a and the drain pan side wall upper end 5a3 of the drain pan outlet side wall 5a1 of the drain pan flange 5a is equal to the drain pan outlet side wall 5a1, the air guide outlet 18c, And the closest distance L3 between the drain pan outlet side wall 5a1 and the air guide corner portion 18b is “H1> L3 ≧ L2”, and at least gradually from the air guide inlet introduction portion 18a to the air guide corner portion 18b. Since the substream C21 and the substream C22 in the vicinity of the drain pan are gradually contracted and the turbulence can be attenuated efficiently, the air guide 18 and the drain pan outlet air passage side wall 5a1 are surrounded. The ventilation resistance of the air guide internal air passage 18h can be reduced.
Since the ventilation resistance can be reduced as described above, the motor power can be reduced and energy can be saved.

And since the air guide attachment part 18d extended from the air guide 18 is fixed to the drain pan outlet air passage side wall 5a1, the positional relationship between the drain pan 5 and the air guide 18 is maintained, variation in the effect is suppressed, and the quality Is stable.
Moreover, since the air guide 18 has the air guide longitudinal direction both ends 18e at both ends in the longitudinal direction, the air guide inner air path 18h is formed so as to be separated from the other air paths, and the air guide Since both end portions 18e in the longitudinal direction are formed in a substantially U-shape so as to sandwich the drain pan outlet air side wall 5a1, the side flow C22 can be rectified without being influenced by the flow flowing in from the side of the air guide 18. Therefore, the rectification effect is stabilized and a low noise effect is obtained.
Furthermore, since the close contact surface between the air guide longitudinal direction both ends 18e and the drain pan outlet air passage side wall 5a1 is wide, even if stress is applied to the air guide 18, it is difficult to drop and break.
Further, since the air guide inlet inlet tip 18d1 does not protrude toward the heat exchanger 16 with respect to the air guide inlet inlet 18a, there is no direct heat transfer from the heat exchanger 16, and condensation at the air guide inlet inlet 18a. Is prevented and quality is ensured.

  Further, the height M1 of the air pan 18 attached to the drain pan outlet air passage side wall 5a1 of the drain pan 5, the height M2 of the drain pan corner 5c of the outer air passage wall 10f1 of the drain pan outlet 5b, and the drain pan corner 5c. When the height M3 of the other outer air passage wall 10f1 is substantially the same (M1≈M2≈M3), when the drain pan 5 is stacked, stored and transported as a part with the air guide 18 attached, the adjacent drain pan 5 They are in contact with the outside air passage wall 10f1 on the wide surface of the flat air guide inlet introduction portion 18a, and the stress is dispersed compared to the case where the air guide 18 and the drain pan 5 are in surface contact with each other. Therefore, it can be loaded a lot with trucks, etc., and the transportation efficiency becomes high.

When the air guide 18 is formed so that the height M2 and the height M3 of the outer air passage wall 10f1 of the drain pan 5 are higher than the height M1 when the air guide 18 is attached to the drain pan side wall. Even if it is very thin and lightweight and the stacking strength is low, it can be stacked a lot and the transportation efficiency is high.
Further, the drain pan corner 5c and the outer air passage wall 10f1 are formed so that the height satisfies “M2>M1> M3”, and the drain pan 5 and the main body heat insulating material 10e mesh with each other in a concave-convex shape. When the blowout air passage 10f is formed together with 5a1, when the drain pan 5 is stacked and stored as a part, the air guide inlet 18a does not hit the drain pan 5 and the air guide inlet introduction portion 18a has a substantially horizontal flat shape even if it hits temporarily. The breakage is further prevented, the positioning of the main body heat insulating material 10e and the drain pan 5 is easy, and the variation in energy saving between products and the variation in low noise effect can be suppressed to a small extent.

  As shown in FIG. 6, a plurality of concave grooves 6 are formed in the air guide outer wall surface 18f of the air guide 18 in the longitudinal direction, and the grooves 6 extend from the air guide inlet introducing portion 18a to the air guide blowing portion 18c. Since it extends, the substream C21 that is a flow passing through the air guide outer wall surface 18f is guided along the groove 6 (a straight traveling property is obtained) and further rectified.

  Further, as shown in FIG. 2, the air guide longitudinal direction both ends 18e have a gap D that is separated by a predetermined distance L4 from the drain pan outlet part side face 5b2 of the drain pan outlet 5b that is the longitudinal end of the main body outlet 10d. Therefore, the flow that flows into the main body outlet 10d from the drain pan outlet end side surface 5b2 is redirected and rectified by the air guide mounting portions 18d provided at both ends 18e in the air guide longitudinal direction.

That is, by disposing the air guide 18, in the air conditioner 100, it is possible to suppress separation of the entire blowing air passage and to enlarge the effective air passage.
For this reason, since the pressure loss of the blowout air passage is reduced and the wind speed is reduced, energy saving can be achieved by reducing the power consumption of the fan motor, and noise can be reduced. Moreover, even when there is variation in the assembly of the main body, the fluctuation of the effect is suppressed to the minimum, and damage to the air guide, the drain pan, etc. is prevented. Furthermore, condensation of the air guide can be prevented.
As a result, the air conditioner 100 according to Embodiment 1 of the present invention can achieve energy saving, low noise, and high quality by having the air guide 18.

[Embodiment 2: Ceiling embedded air conditioner]
Hereinafter, a ceiling-embedded air conditioner according to Embodiment 2 of the present invention will be described with reference to the drawings. In each figure, the same reference numerals are given to the same or corresponding parts as those in the first embodiment.
9 to 15 illustrate a ceiling-embedded air conditioner according to Embodiment 2 of the present invention. FIG. 9 is an external view when the room is installed, and FIG. 10 is a ceiling-embedded type shown in FIG. 11 is a horizontal sectional view of the air conditioner, FIG. 11 is a vertical sectional view of the ceiling-embedded air conditioner shown in FIG. 9 (cross sectional view in the XX section of the horizontal sectional view shown in FIG. 10), and FIG. FIG. 13 is a partially enlarged view of a part (outlet air passage), FIG. 13 is a partially enlarged view of a part of FIG. 11 (near the air guide), and FIG. 12 is a perspective view of the air guide shown in FIG. 14 is a perspective view of the air guide shown in FIG. 11 as viewed from the outer wall surface side of the air guide, and FIG. 15 is a longitudinal sectional view showing a portion (drain pan) of the ceiling-embedded air conditioner shown in FIG. FIG. 16 and FIG. 17 are air guides. Is a perspective view from the air guide perspective viewed from the inner wall surface view and an air guide outer wall surface showing another embodiment of.

In the ceiling-embedded air conditioner (hereinafter referred to as “air conditioner”) 200 shown in FIGS. 9 and 10, an elbow-shaped air outlet 10 f is formed from the heat exchanger 16 to the main body outlet 10 d. . In the blowout air passage 10f, the air guide 18 disposed in the vicinity of the drain pan 5 has a different longitudinal cross-sectional shape in the longitudinal direction as shown in FIGS. 13 and 14, and is disposed in the vicinity of the drain pan side wall of the blowout air passage 10f. The height H1 (see FIG. 12) between the air guide inlet introduction portion 18a of the air guide 18 and the uppermost end 5a3 of the drain pan 5 is determined based on the closest point 16b between the heat exchanger 16 and the turbo fan 1 and the turbo fan rotation. The upstream side 16c is formed to be higher than the downstream side 16d in the direction A (see FIGS. 9 and 13).
In addition, a plurality of substantially triangular notches 7 serving as shear turbulence suppression means are formed in the longitudinal direction (substantially in a comb shape) at the air guide outlet outlet side end 18c1 (see FIGS. 13 and 14).

  Since the air conditioner 200 is formed in such an air guide 18 such that the height H1 of the air guide inlet introduction portion 18a with the drain pan side wall uppermost end 5a3 is different in the longitudinal direction of the main body outlet, The flow is finely controlled in accordance with the suppression of separation at the air passage side wall 5a1 and the wind speed distribution of the mainstream, and an energy saving effect and a noise reduction effect are achieved by expanding the effective air passage.

Further, the turbofan 1 rotates in the rotation direction A in the horizontal direction with respect to the standing heat exchanger 16, and the drain pan of the air guide inlet introduction portion 18a disposed in the drain pan outlet side wall 5a1 of the outlet air passage 10f. The height H1 of the side wall uppermost end 5a3 is made higher on the upstream side in the rotational direction than on the downstream side in the rotational direction, thereby increasing the amount of air passing through the air guide on the upstream side in the rotational direction where separation is large. By suppressing the difference in wind speed from the internal flow, shear disturbance at the outlet of the air guide outlet is suppressed and low noise is achieved.
The rotational direction downstream side portion 16d has an angle difference α between the main flow C1 spirally blown from the turbo fan 1 and the aluminum fins 16e of the heat exchanger 16 with the closest point 16b between the heat exchanger 16 and the turbo fan as a reference. The heat flow rate through the heat exchanger is relatively large and the wind speed is relatively high, and the upstream side portion 16c in the rotational direction where the separation at the drain pan outlet side wall 5a1 is large, and the air flow rate through the heat exchanger is relatively small and the wind speed is low. Yes.

  Furthermore, since a plurality of substantially triangular notches 7 are formed in the longitudinal direction at the air guide outlet outlet side end 18c1, the flows of the air guide outer wall surface 18f and the air guide inner wall surface 18g are gradually merged. Further, the shear turbulence is reduced, and further rectification is performed to obtain a noise reduction effect. The same effect can be obtained when the shape of the notch 7 is substantially rectangular (see FIGS. 16 and 17) or substantially triangular.

In addition, in the air guide 18 of the air conditioner 100 according to the first embodiment, at least the notch portion is formed in the air guide outlet portion 18c1 of the air guide outlet portion 18c as in the air conditioner 200 according to the second embodiment. If 7 is formed, the same effect can be obtained.
As a result, in the air conditioner 200, a greater energy saving effect and noise reduction effect can be obtained.

  In the air conditioner 200, one air guide having a different inlet height H1 in the longitudinal direction of the outlet is shown at one outlet (inlet height H1 is two levels). 1 and the closest point 16b of the heat exchanger 16, when two air guides 18j and 18k having different inlet heights H1 on the upstream side and the downstream side are arranged in total (inlet height H1 is a total of four levels), Even when the wind speed distribution at the outlet differs between the outlets, the shape and arrangement can be finely adapted to each, and noise can be further reduced.

Further, when the inlet tip 18a1 of the air guide inlet introduction portion 18a shown in FIG. 17 is formed in a wave shape in the height direction, local pressure fluctuations even if the inflow flow from the heat exchanger 16 collides with the inlet tip 18a1. Can be reduced and noise can be reduced.
Further, in the case where the entire shape is formed from the inlet tip 18a1 to the air guide outlet part 18c1, the wave shape shown in FIG. 17, the groove 6 shown in FIG. 6, and the notch 7 shown in FIG. A rectifying effect is obtained, an energy saving effect and a noise reduction effect can be achieved, and even when stacked, the adjacent drain pan is not contacted at an acute angle, so that breakage can be prevented.

[Organization of invention]
As described above, the present invention described in the first embodiment and the second embodiment is organized as the following (2).
(2) The height of the air guide inlet introduction portion of the air guide is different in the longitudinal direction of the drain pan. Therefore, since the air guide has a shape in which the height of the air guide inlet introduction portion and the drain pan side wall uppermost end is different in the longitudinal direction of the main body outlet and extends toward the main body outlet, the peeling suppression at the drain pan side wall, The flow can be finely controlled according to the wind speed distribution of the mainstream, and the draft resistance can be reduced and the noise can be reduced by expanding the effective wind path.

(3) The air guide blowing portion of the air guide is extended toward a position substantially parallel to the main body side plate at a position away from the drain pan blowing air passage side wall by a predetermined distance,
The air guide corner portion of the air guide is formed into a single arcuate curved surface or a plurality of arcuate curved surfaces that are convex toward the main body side plate.
Accordingly, since the air guide corner portion is smooth (for example, in an arc shape), the air guide can be smoothly guided to the air guide blowing portion while the flow from the inlet introduction portion is rectified on the drain pan side surface of the air guide, and the air guide On the outer wall surface of the air guide, the flow that has passed from the heat exchanger can be guided to the air guide outlet without being smoothly peeled off by the Counder effect.
Furthermore, the air guide outlet extends at a position away from the drain pan side wall near the drain pan side wall of the outlet air passage by a predetermined distance so as to be substantially parallel to the outer wall of the main body toward the main body outlet. The flow from the unit is further rectified in the gap with the drain pan side wall, and the distance between the air guide and the outer wall of the blowout air passage is constant, so that the area of the main blower outlet is reduced from the upper part of the air guide of the heat exchanger. The flow from above the heat exchanger is also rectified when flowing through the blowout air passage. That is, since the entire blowing flow is rectified and flows into the downstream panel outlet, it is possible to reduce noise without causing pressure fluctuations in the wind direction vanes disposed at the panel outlet.
Moreover, since the attachment part extended from the air guide is fixed to the drain pan side wall, the positional relationship between the drain pan and the air guide is maintained, and variations in the effects can be suppressed.
In other words, by disposing the air guide, it is possible to suppress separation of the entire blowing air passage and to expand the effective air passage, so that the pressure loss of the blowing air passage can be reduced and the wind speed can be reduced. Energy saving can be achieved by reduction. In addition, noise can be reduced, and fluctuations in the effect due to variations in assembly of the main body can be suppressed.
Therefore, an energy-saving, low-noise, high-quality ceiling-embedded air conditioner can be obtained.

(4) The distance (H1) between the inlet tip portion of the air guide inlet introduction portion and the upper end of the drain pan outlet air channel side wall is the distance between the air guide side surface of the drain pan outlet air channel side wall and the air guide outlet portion. Compared to the closest distance (L2) between the drain pan side surface and the closest distance (L3) between the air guide side surface of the drain pan outlet side wall and the drain pan side surface of the air guide corner portion It is formed so as to be wide (H1> L2 and H1> L3).
Accordingly, the distance between the air guide inlet introduction part and the drain pan side wall uppermost end is formed so as to be wider than the closest distance between the air guide side surface of the drain pan side wall and the air guide outlet part and the corner part. Therefore, since the side flow in the vicinity of the drain pan is gradually contracted, the turbulence can be attenuated efficiently, and the increase in ventilation resistance of the air path surrounded by the air guide and the drain pan side wall can be further suppressed. Therefore, the ceiling-embedded air conditioner having an energy saving effect can be obtained.

(5) The turbo fan rotates in the horizontal direction of the product width direction with respect to the heat exchanger,
The height of the air guide inlet introduction portion of the air guide is such that the upstream side in the rotational direction of the turbo fan is higher than the downstream side in the rotational direction with respect to the closest point of contact between the heat exchanger and the turbo fan. It is formed in these.
Therefore, the turbo fan rotates in the horizontal direction in the stacking direction with respect to the installed heat exchanger, and the height of the air guide inlet introduction portion disposed near the drain pan side wall of the blowout air channel is the height of the drain pan side wall top end. However, since the upstream side is higher than the downstream side in the turbo fan rotation direction with respect to the closest point of contact between the heat exchanger and the turbo fan, the flow blown out from the turbo fan and the heat exchanger fins The air flow through the heat exchanger is relatively large and the wind speed is relatively high and the separation at the drain pan side wall is large in the rotational direction upstream side, and the heat exchanger passage air volume is relatively small and the wind speed is low, and the drain pan side wall The height of the air guide inlet and the top end of the drain pan side wall at the downstream portion in the rotational direction is small at the upstream side in the rotational direction than the downstream side in the rotational direction. By changing the air volume passing through the air guide and suppressing the difference in wind speed between the main flow and the air guide internal flow, shear disturbance at the outlet of the air guide outlet is suppressed, and a low noise embedded ceiling air conditioner can get.

(6) In the air guide, air guide mounting portions for installing the air guide on the drain pan outlet side wall are provided at least at both ends in the longitudinal direction of the air guide,
The air guide mounting portion is horizontal and does not protrude toward the heat exchanger from the inlet tip of the air guide inlet introduction portion, and the air guide mounting portion, the air guide, and the drain pan blowing air An air passage surrounded by a road side wall is formed.
Therefore, the mounting portion for fixing to the drain pan side wall extending from the air guide disposed in the vicinity of the drain pan side wall of the blowout air path protrudes from the inlet side end portion of the air guide inlet introduction portion to the heat exchanger side. Since there is no heat transfer from the heat exchanger, condensation can be prevented. In addition, it has at least both ends in the longitudinal direction of the air guide and is formed so as to separate the air passage surrounded by the air guide and the drain pan side wall from the other air passages, so it is not affected by the flow flowing in from the side of the air guide. Therefore, the rectifying effect is stabilized and the low noise effect is obtained. In addition, even if there is a fixing error between the air guide and the drain pan side wall, the air guide mounting portion is in close contact with the drain pan side wall, so that it is difficult to drop off. Therefore, a ceiling-embedded air conditioner with high quality and low noise can be obtained.

(7) The air guide inlet introduction portion of the air guide has a flat shape in a horizontal direction from the inlet side end portion to a position corresponding to a position directly above the uppermost end portion of the drain pan outlet side wall. Accordingly, the air guide inlet introduction portion is flat from the inlet side end portion to a position corresponding to the uppermost end portion of the blowout air passage side wall of the drain pan flange in the horizontal direction, and therefore rises from the drain pan flange portion on the air passage side wall. When the flow and the flow that passes through the heat exchanger and flows into the air guide merge, it is not suddenly changed, and the flat part can be used as a run-up section and gradually rectified before flowing into the corner part and outlet part. Noise due to disturbance can be suppressed.
Further, when the drain pans are stacked and stored as parts, the air guides are in contact with the drain pans on a flat surface, so that the quality of the parts can be ensured without the air guides piercing the drain pans. Therefore, a high-quality and low-noise ceiling-embedded air conditioner can be obtained.

(8) The longitudinal end of the air guide is disposed so as to form a gap of a predetermined distance with respect to the longitudinal end of the blowing part of the drain pan.
Therefore, since both ends of the air guide in the longitudinal direction are formed at positions having a gap apart from the end side of the drain pan outlet by a predetermined distance, the flow flowing into the main body outlet from the end side is the longitudinal direction of the air guide. Disturbance is suppressed by turning and rectifying at the mounting portions provided at both ends. Therefore, a low-noise ceiling-embedded air conditioner can be obtained.

(9) With respect to the surface near the upper end of the drain pan outlet side wall facing the air guide outlet, the surface near the lower end of the drain pan outlet side wall not facing the air guide outlet is closer to the heat exchanger. Formed into
A substantially horizontal step is formed between the surface near the upper end and the surface near the lower end.
Therefore, in the height direction, there is a step in the direction in which the blower outlet short side dimension expands on the side of the air outlet side of the drain pan outlet side wall between the drain pan end and the air path side side wall uppermost end of the drain pan end, Since the outlet side end of the air guide outlet is formed so as to be substantially the same height as the step, a negative pressure is generated by the step immediately after exiting the air guide, so that the flow to the drain pan surface By being attracted, shear disturbance on the surface of the drain pan can be reduced, and noise can be reduced.

(10) The outer air passage wall forming the drain pan is formed to have substantially the same height as the air guide inlet introduction portion of the air guide attached to the drain pan outlet air passage side wall. It is characterized by becoming.
Accordingly, the height of the outer air channel wall of the drain pan is formed to be substantially the same height as the air guide attached to the drain pan side wall, so that the drain pan is stacked, stored and transported as a part with the air guide attached. When the adjacent drain pan comes into contact with the outer air channel wall on the wide surface of the flat air guide inlet introduction part and the stress is distributed compared to the contact with the air guide, the air guide and drain pan are damaged even if they are stacked a lot. High efficiency of loading and transporting a lot of trucks. Therefore, a ceiling-embedded air conditioner with high quality and energy saving effect can be obtained.

(11) The outer air passage wall forming the drain pan is formed to be higher than the air guide inlet introduction portion of the air guide attached to the drain pan outlet air passage side wall. To do.
Therefore, because the height of the outside air channel wall of the drain pan is formed so as to be higher than the air guide attached to the drain pan side wall, even if the air guide is very thin and lightweight and the stacking strength is low, Many are stacked and transport efficiency is high. Therefore, a ceiling-embedded air conditioner having an energy saving effect can be obtained.

(12) The four corners of the drain pan are formed so as to be equivalent to or higher than the air guide in a state attached to the drain pan outlet side wall,
And the outside air passage wall other than the four corners of the drain pan is formed to be lower than the air guide inlet introduction part,
The outer air passage wall forming the drain pan and the main body heat insulating material installed on the main body side plate are formed so as to mesh in an uneven shape.
Therefore, the height of the four corners of the drain pan is formed to be equal to or greater than that of the air guide attached to the drain pan side wall, and the outer air passage wall other than the drain pan corner is formed from the air guide inlet introduction portion. The outer air duct wall and the main body insulation are formed so as to engage in an uneven shape, so when storing and stacking drain pans as parts, the air guides do not contact with adjacent drain pans, so there is no further risk of damage. Positioning of the outer wall of the main unit and the drain pan can be performed, and the ceiling-embedded air conditioner with stable quality can be obtained by suppressing variation in energy saving and low noise between products.

(13) A groove is formed on at least a surface of the air guide on the main body side plate side from the air guide inlet introduction portion to the air guide blowing portion.
Therefore, since a groove extending from the air guide inlet introduction portion to the air guide blowout portion is formed on the surface of at least the blowout air passage side surface of the air guide disposed in the vicinity of the drain pan side wall of the blowout air passage. Since the velocity component in the longitudinal direction is suppressed on the guide surface, the flow into the wind direction vane on the downstream side is stable, and a ceiling embedded air conditioner with low noise can be obtained.

(14) A rectangular or substantially triangular notch is formed at an outlet side end of the blowing portion of the air guide.
Therefore, a rectangular or substantially triangular notch is formed at the outlet side end of the air guide outlet disposed near the drain pan side wall of the outlet air passage, so that the air guide inner flow and the air guide outer wall side surface When the air flows merge at the outlet, the speed difference can be buffered, so that shear turbulence can be suppressed, and a stable flow can be supplied to the downstream wind vane, resulting in a ceiling-embedded air conditioner that has a low noise effect. It is done.

(15) Two or more of the air guides are disposed along the longitudinal direction of the drain pan outlet side wall.
Accordingly, since at least two air guides are arranged in the longitudinal direction at one outlet, even if the wind speed distribution is different at the outlet, the shape can be made suitable for each, and noise can be further reduced.

(16) An inlet tip portion of the air guide inlet introduction portion is formed in a substantially arc shape in cross section in the longitudinal direction.
Accordingly, the inlet side end of the air guide inlet introduction portion disposed in the vicinity of the drain pan side wall of the blowout air passage is formed in a substantially arc shape in the longitudinal direction, so that the local pressure at the air guide inlet introduction portion is The fluctuation is alleviated and peeling is also suppressed. Moreover, when it forms in a column shape, damage can also be prevented by improving the intensity | strength of an air guide, and a low noise and a high quality air conditioner are obtained.
(17) The front end portion of the air guide inlet introduction portion is formed in a waveform in the height direction over the longitudinal direction.

  Since the present invention has the above-described configuration, it is possible to prevent condensation and to reduce noise and save energy by installing an air guide. Therefore, it can be widely used as various ceiling-embedded air conditioners. .

The external view at the time of the room installation of the ceiling-embedded air conditioner which concerns on Embodiment 1 of this invention. The horizontal sectional view of the ceiling-embedded air conditioner shown in FIG. The longitudinal cross-sectional view of the ceiling-embedded air conditioner shown in FIG. FIG. 4 is a partially enlarged view of a part (blowing wind path) of FIG. 3. FIG. 5 is a partially enlarged view of a part of FIG. 4 (near the air guide). The perspective view which looked at the air guide shown in FIG. 5 from the air guide inner wall surface. The perspective view which looked at the air guide shown in FIG. 5 from the air guide outer wall surface side. The longitudinal cross-sectional view which shows the part (drain pan) of the ceiling-embedded air conditioner shown in FIG. The external view at the time of room installation of the ceiling embedded type air conditioner concerning Embodiment 2 of this invention. FIG. 10 is a horizontal sectional view of the ceiling-embedded air conditioner shown in FIG. 9. The longitudinal cross-sectional view of the ceiling-embedded air conditioner shown in FIG. FIG. 11 is a partially enlarged view of a part (blowing wind path) of FIG. 10. The perspective view which looked at the air guide shown in FIG. 11 from the air guide inner wall surface. The perspective view which looked at the air guide shown in FIG. 11 from the air guide outer wall surface. The longitudinal cross-sectional view which shows the part (drain pan) of the ceiling-embedded air conditioner shown in FIG. The perspective view seen from the inner wall surface which shows the other Example of an air guide. The perspective view seen from the outer wall surface which shows the other Example of an air guide.

Explanation of symbols

  1: turbo fan, 1a: fan outlet, 1b: fan outlet, 1ba: fan outlet lower end, 2: fan outlet, 3: fan side plate, 5: drain pan, 5a: drain pan collar, 5a1: drain pan Air outlet side wall, 5a3: drain pan side wall uppermost end, 5b: drain pan outlet, 5b1: drain pan outlet side wall surface, 5b2: drain pan outlet side surface, 5c: drain pan corner, 5d: step, 6: groove, 7 : Notch, 10: main body, 10a: main body top plate, 10b: main body side plate, 10c: main body suction port, 10d: main body air outlet, 10f: main body heat insulating material, 10f: blowout air passage, 10f1: outer air passage wall, 11: decorative panel, 11a: suction grille, 11b: panel outlet, 12: filter, 13: wind direction vane, 14: bell mouth, 15: fan motor, 16: heat exchanger, 6a: heat exchanger downstream surface, 16b: closest point between fan and heat exchanger, 16c: upstream side in turbo fan rotation direction A, 16d: downstream side in turbo fan rotation direction A, 16e: aluminum fin, 18: Air guide, 18a: Air guide inlet introduction part, 18a1: Inlet tip part, 18b: Air guide corner part, 18c: Air guide blowing part, 18c1: Air guide blowing part outlet side end part, 18d: Air guide mounting part, 18d1 18e: Air guide outer wall surface, 18g: Air guide inner wall surface, 18h: Air guide inner air path, 18j: Air outlet longitudinal direction of rotation upstream Side air guide, 18k: Air guide downstream in the longitudinal direction of the outlet, 90: Room, 91: Ceiling, 92 Ceiling, 100: Air conditioner (Embodiment 1), 200: Air conditioner (Embodiment 2), A: Direction of rotation, B1: Inner air path, B2: Outer air path, C1: Mainstream, C2: Side stream, C21: Part of side stream C2 that flows directly into the blowout air passage, C22: Part of side stream C2 that rises and accelerates through the drain pan ridge, D: Clearance, H: Body height, H1 : Height from drain pan side wall uppermost end 5a3 of drain pan flange 5a, L1: distance from heat exchanger downstream surface 16a of heat exchanger 16, L2: air guide outlet 18c and drain pan outlet side wall 5a1 Distance, L3: Distance between the air guide corner portion 18b and the drain pan outlet side wall 5a1, L4: Distance between the air guide longitudinal direction both ends 18e and the drain pan outlet portion side surface 5b2, M1: Installation of the air guide 18 M2: height of the drain pan corner 5c, M3: height other than the drain pan corner 5c.

Claims (17)

A box-shaped main body formed from a main body top plate and a main body side plate, which is embedded in the back of the ceiling, and whose bottom is open;
A turbofan housed in the main body and fixed to the center of the main body top plate;
A heat exchanger housed in the main body and installed to surround the turbofan;
A bowl-shaped drain pan that is housed in the main body and into which the lower end of the heat exchanger has entered,
An air guide that covers the upper side of the drain pan outlet side wall and the main body side plate side of the drain pan near the main body side plate with a predetermined interval;
A decorative panel that covers a lower portion of the main body and includes a panel suction port formed in the center and a panel outlet formed near the periphery,
Have
The air guide includes a flat air guide inlet introduction part, a curved air guide corner part continuous with the air guide inlet introduction part, and a flat air guide outlet part continuous with the air guide corner part. And
The air guide inlet introduction part is located between the lower end of the blower outlet of the turbofan and the upper end of the drain pan outlet side wall, and the front end of the inlet of the air guide inlet introduction part is horizontal. In the direction, located near the downstream surface of the heat exchanger,
The ceiling-embedded air conditioner characterized in that the lower end of the air guide outlet is in the height direction and is located below the upper end of the drain pan outlet side wall.   The ceiling-embedded air conditioner according to claim 1, wherein the height of the air guide inlet introduction portion of the air guide is different in the longitudinal direction of the drain pan. The air guide blowing part of the air guide is extended toward the lower side substantially parallel to the main body side plate at a position away from the drain pan blowing air passage side wall by a predetermined distance,
3. The ceiling-embedded type according to claim 1, wherein an air guide corner portion of the air guide is formed into a single arc-shaped curved surface or a plurality of arc-shaped curved surfaces that are convex toward the main body side plate. Air conditioner.   The distance (H1) between the inlet front end of the air guide inlet introduction part and the upper end of the drain pan outlet side wall is the air guide side surface of the drain pan outlet side wall and the drain pan side of the air guide outlet. And the closest distance (L3) between the air guide side surface of the drain pan outlet side wall and the closest surface distance (L3) of the air guide corner portion to the drain pan side surface. The ceiling-embedded air conditioner according to any one of claims 1 to 3, wherein (H1> L2 and H1> L3) are formed. The turbofan rotates in the horizontal direction of the product width direction with respect to the heat exchanger,
The height of the air guide inlet introduction portion of the air guide is such that the upstream side in the rotational direction of the turbo fan is higher than the downstream side in the rotational direction with respect to the closest point of contact between the heat exchanger and the turbo fan. The ceiling-embedded air conditioner according to any one of claims 1 to 4, wherein the air conditioner is embedded in a ceiling. In the air guide, air guide mounting portions for installing the air guide on the drain pan outlet side wall are provided at least at both ends in the longitudinal direction of the air guide,
The air guide mounting portion is horizontal and does not protrude toward the heat exchanger from the inlet tip of the air guide inlet introduction portion, and the air guide mounting portion, the air guide, and the drain pan blowing air 6. The ceiling-embedded air conditioner according to claim 1, wherein an air passage surrounded by a road side wall is formed.   The air guide inlet introduction portion of the air guide has a flat shape in a horizontal direction from the inlet side end portion to a position corresponding to a position directly above the uppermost end portion of the drain pan outlet side wall. 6. The ceiling-embedded air conditioner according to any one of 6 above.   8. The air guide according to claim 1, wherein an end of the air guide in the longitudinal direction is disposed so as to form a gap of a predetermined distance with respect to an end of the blowout portion of the drain pan in the longitudinal direction. The ceiling-embedded air conditioner according to any one of the above. A surface closer to the lower end not facing the air guide blowing portion of the drain pan blowing air passage side wall is formed closer to the heat exchanger than a surface near the upper end facing the air guide blowing portion of the drain pan blowing air passage side wall. ,
The ceiling-embedded air conditioner according to any one of claims 1 to 8, wherein a substantially horizontal step is formed between the surface near the upper end and the surface near the lower end.   The outer air passage wall forming the drain pan is formed to have a height substantially equal to the air guide inlet introduction portion of the air guide attached to the drain pan outlet air passage side wall. The ceiling-embedded air conditioner according to any one of claims 1 to 9.   The outer air passage wall forming the drain pan is formed to be higher than the air guide inlet introduction portion of the air guide attached to the drain pan outlet air passage side wall. The ceiling-embedded air conditioner according to any one of 1 to 9. The four corners of the drain pan are formed to be equal in height or higher than the air guide attached to the drain pan outlet side wall,
And the outside air passage wall other than the four corners of the drain pan is formed to be lower than the air guide inlet introduction part,
12. The outer air passage wall forming the drain pan and the main body heat insulating material installed on the main body side plate are formed so as to engage with each other in an uneven shape. Embedded ceiling air conditioner.   The ceiling filling according to any one of claims 1 to 12, wherein a groove is formed on at least a surface of the air guide on the main body side plate side from the air guide inlet introduction portion to the air guide blowout portion. Built-in air conditioner.   14. A ceiling-embedded air conditioner according to any one of claims 1 to 13, wherein a rectangular or substantially triangular notch is formed at an outlet side end of the air guide outlet of the air guide. Machine.   The ceiling-embedded air conditioner according to any one of claims 1 to 14, wherein two or more air guides are arranged along a longitudinal direction of the drain pan outlet side wall.   16. The ceiling-embedded air conditioner according to any one of claims 1 to 15, wherein an inlet tip portion of the air guide inlet introduction portion is formed in a substantially arc shape in cross section along the longitudinal direction.   16. The ceiling-embedded air conditioner according to claim 1, wherein an inlet front end portion of the air guide inlet introduction portion is formed in a waveform in the height direction over the longitudinal direction.

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