ES2566110T3 - Air conditioner - Google Patents

Abstract

Air conditioner (1), comprising: a heat exchanger (4); a flared mouth (13) arranged behind the heat exchanger (4) such that an opening (14) thereof through which air passes is oriented towards the heat exchanger (4); a housing (2) having a front panel (22) that covers the front side of the heat exchanger (4) and is provided with air inlets (8-11) and air outlets (6, 7); and a turbo fan (5) arranged behind the flared mouth (13) and configured to generate an air flow in which air is sucked from the air inlets (8-11), passes through the heat exchanger (4) and the opening (14) of the flared mouth (13), and is ejected from the air outlets (6, 7), in which the total suction area of the air inlets (8-11) is equal to or greater that 15% of the projected area of the heat exchanger (4) as observed from the front, characterized in that the air inlets (8 -11) are provided on the front panel (22) and / or around it, and they are located substantially outside the opening (14) of the flared mouth (13) as seen from the front.

Description

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DESCRIPTION

Air conditioner Technical field

The present invention relates to an air conditioner.

Prior art

Traditionally, an air conditioner is known in which a front panel of a housing, a heat exchanger and a flared mouth are arranged in this order from the front to the rear of the housing, and air inlets are provided around of the front panel. An air conditioner of this type is equipped with a one-step fan, which generates an air flow in which air is sucked

from the air inlets, it passes through the heat exchanger and a flared mouth opening, and it

ejected from the air vents (see patent document 1).

The second patent document discloses an air conditioner that can be mounted on a ceiling with a suction opening in a central part of a front panel and with air outlets arranged on all four sides of the suction opening and an outlet of additional air arranged in adjacent side walls and above the front panel.

<Patent document 1> Japanese Patent Application Publication No. 64-58965 (Figures 1 and 2)

<Patent Document 2> Japanese Patent Application Publication No. 2002-005500

Patent document EP-A-1512919 discloses an air conditioner according to the preamble of claim 1.

Disclosure of the invention

<TECHNICAL PROBLEM>

In the type of air conditioner described above, the air inlets are provided around the front panel, and therefore it is possible to improve the design of the front panel. However, the resistance to air suction increases compared to the case in which the air inlets are provided in the center of the front panel. This makes the one-step fan output insufficient, making it difficult to guarantee the necessary static pressure.

An object of the present invention is to provide an air conditioner that can guarantee the necessary static pressure even when the arrangement of air inlets is such that the resistance to suction tends to increase.

<PROBLEM SOLUTION>

An air conditioner according to claim 1 includes a heat exchanger, a flared mouth, a housing and a turbo fan. The flared mouth is arranged behind the heat exchanger so that an opening thereof through which air passes is oriented towards the heat exchanger. The housing has a front panel that covers the front side of the heat exchanger, and is equipped with air inlets and air outlets. The turbo fan is arranged behind the flared mouth and generates an air flow in which air is sucked from the air inlets, passes through the heat exchanger and the flared mouth opening, and is ejected from the air outlets . Additionally, the air inlets are provided on the front panel and / or around it, and are located substantially outside the flared mouth opening as seen from the front. In addition, the total suction area of the air inlets is equal to or greater than 15% of the projected area of the heat exchanger as observed from the front.

In this air conditioner, an air flow is generated by the turbo fan, so that it is possible to guarantee the necessary static pressure even when the arrangement of the air inlets is such that the suction resistance tends to increase. In addition, although the use of the turbo fan when the arrangement of the air inlets is such that the suction resistance tends to increase can increase the suction noise, the present invention can reduce the suction noise because the total suction area of the air inlets is equal to or greater than 15% of the projected area of the heat exchanger as observed from the front.

According to a preferred embodiment, the distance between the heat exchanger and the flared mouth is equal to or greater than 10% of the diameter of the flared mouth opening.

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In this air conditioner, an air flow is generated by the turbo fan, so that it is possible to guarantee the necessary static pressure even when the arrangement of the air inlets is such that the suction resistance tends to increase. In addition, when an air flow is generated by the turbo fan behind the heat exchanger, the air tends to flow unevenly mainly through the center of the heat exchanger, which can reduce the heat exchange efficiency; However, the present invention can improve the efficiency of air conditioning because the distance between the heat exchanger and the flared mouth is equal to or greater than 10% of the diameter of the flared mouth opening, allowing the air Easily flow through a larger area of the heat exchanger.

<EFFECTS OF THE INVENTION>

In the air conditioner according to an embodiment of the present invention, an air flow is generated by the turbo fan, so that it is possible to guarantee the necessary static pressure even when the arrangement of the air inlets is such that the resistance to Suction tends to increase. In addition, it is possible to reduce the suction noise because the total suction area of the air inlets is equal to or greater than 15% of the projected area of the heat exchanger as observed from the front.

In addition, it is possible to improve the air conditioning efficiency, by choosing the distance between the heat exchanger and the flared mouth to be equal to or greater than 10% of the diameter of the flared mouth opening, which allows the air Easily flow through a larger area of the heat exchanger.

Brief description of the drawings

Figure 1 is a front view of an air conditioner.

Figure 2 is a side view of the air conditioner.

Figure 3 is a side cross-sectional view of the air conditioner.

Figure 4 is a schematic view showing the projected area of an indoor heat exchanger as seen from the front.

Figure 5 is a schematic view showing the distance between the indoor heat exchanger and a flared mouth, and the diameter of an flared mouth opening.

Figure 6 is a graph showing the relationship between the ratio of the total suction area to the heat exchange area and the suction noise.

Figure 7 is a graph showing the relationship between the air conditioning efficiency and the distance between the indoor heat exchanger and the flared mouth with respect to the diameter of the flared mouth opening.

Explanation of the reference symbols

1 air conditioner

2 Housing

4 Indoor heat exchanger (heat exchanger)

5 Air blowing device (turbo fan)

6 First air outlet (air outlet)

7 Second air outlet (air outlet)

8 First air inlet (air inlet)

9 Second air inlet (air inlet)

10 Third air inlet (air inlet)

11 Fourth air inlet (air inlet)

13 Flared mouth

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14 Opening 22 Front panel

Best way to carry out the invention

<STRUCTURE>

An air conditioner 1 according to an embodiment of the present invention is shown in Figures 1 to 3. Figure 1 is a front view of the air conditioner 1 and Figure 2 is a side view of the air conditioner 1. In addition, Figure 3 is a side cross-sectional view of the air conditioner 1. The air conditioner 1 is an indoor support unit on the floor and is provided with a housing 2, an indoor heat exchanger 4, a flared mouth 13 and an air blowing device 5. Note that the terms "up", "down", "Left" and "right" used in the description below, refer to the up, down, left and right sides of the air conditioner 1 as seen from the front.

<HOUSING 2>

The housing 2 comprises a hollow body made of synthetic resin and houses the indoor heat exchanger 4, the flared mouth 13 and the air blowing device 5 inside it. The housing 2 includes a housing main body 21 and a front panel 22 attached to a front surface of the housing main body 21.

The front surface of the main carcass body 21 has a large opening formed inside it. The main housing body 21 has the indoor heat exchanger 4, the flared mouth 13 and the air blowing device 5 arranged in this order from the front to the rear inside.

The front surface of the housing 2 has a first air outlet 6 and a second air outlet 7 provided therein. The first air outlet 6 is an opening that has a horizontally long shape that is arranged along the upper end of the front surface of the housing 2 and the air that is expelled into the room passes through it. The second air outlet 7 is an opening that has a horizontally long shape that is arranged along the lower end of the front surface of the housing 2 and the air that is expelled into the room passes through it. Note that the first air outlet 6 is provided with a first fin 61 that grinds the air expelled from the first air outlet 6 so that the first fin 61 can pivot freely and the first air outlet 6 can be opened and closed by the first flap 61. In addition, the second air outlet 7 is provided with a second flap 62 which grinds the air expelled from the second air outlet 7 so that the second flap 62 can pivot freely.

The front panel 22 is mounted on the front surface of the main housing body 21 and has an external shape that is smaller than the front surface of the main housing body 21. The front panel 22 covers the front side of the indoor heat exchanger 4 and is arranged below the first air outlet 6 as seen from the front. In addition, a front surface of the front panel 22 is arranged at a slight distance in front of the front surface of the main housing body 21. The side surfaces 23 and 24 of the front panel 22 connecting the side end portions of the front surface of the front panel 22 with the front surface of the main housing body 21 are provided with a first air inlet 8 and a second air inlet 9, respectively. The first air inlet 8 is an opening that has a longitudinally long shape that is disposed on the right side surface 23 of the front panel 22 and the air sucked into the housing 2 from the room passes through it. The second air inlet 9 is an opening that has a longitudinally long shape that is disposed on the left side surface 24 of the front panel 22 and the air sucked into the housing 2 from the room passes through it.

In addition, an upper surface 25 of the front panel 22 connecting the upper end portion of the front surface of the front panel 22 with the front surface of the main housing body 21 is provided with a third air inlet 10. The third air inlet 10 is an opening that has a horizontally long shape that is arranged below the first air outlet 6 and the air sucked into the housing 2 from the room passes through it. In addition, a lower part of the front surface of the front panel 22 is provided with a fourth air inlet 11. The fourth air inlet 11 is an opening that has a horizontally long shape that is arranged above the second air outlet 7 and the air sucked into the housing 2 from the room passes through it. Note that a lower surface of the front panel 22 connecting the lower front end of the front panel 22 with the front surface of the main housing body 21 is closed. Also, a part between the third air inlet 10 and the fourth air inlet 11 of the front surface of the housing 2 is a flat panel part 20 in which an opening is not provided.

As described above, the housing 2 has the four air inlets from the first air inlet 8 to the fourth air inlet 11 provided in the front panel 22, one on each of the four sides (up, down, left and right) around the flat panel part 20 and air is sucked from all four sides (above,

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bottom, left and right) of the flat panel part 20. In addition, as shown in Figure 1, these air inlets 8 to 11 are located outside the opening 14 of the flared mouth 13 as seen from the front.

<INDOOR HEAT EXCHANGER 4>

The indoor heat exchanger 4 shown in Figure 3 constitutes a refrigerant circuit together with an outdoor heat exchanger disposed in the outdoor unit (not shown) and performs a heat exchange with the air passing through the exchanger indoor heat exchanger 4. The indoor heat exchanger 4 is arranged behind the front panel 22. The indoor heat exchanger 4 has an external shape as a thin plate and is arranged parallel to the flat panel portion 20. In addition, the indoor heat exchanger 4 has the same size as the front panel 22 as seen from the front, and the following expression is obtained: S / B> 0.15, where B is the projected area of the heat exchanger. indoor heat 4 as seen from the front, and S (not shown) is the total suction area of the air inlets 8 to 11 described above, as shown in Figure 4. In other words, the area Total suction S of the air inlets 8 to 11 is equal to or greater than 15% of the projected area B of the indoor heat exchanger 4 as observed from the front.

<STAMPED MOUTH 13>

The flared mouth 13 is arranged behind the indoor heat exchanger 4 and the flared mouth 13 includes a flat part 15 and a circular tube part 16. The flat part 15 has an external shape that is approximately the same size as that of the indoor heat exchanger 4 as seen from the front, and is arranged parallel to the indoor heat exchanger 4 so that it is oriented towards the rear surface of the indoor heat exchanger 4. The flat part 15 is connected to the edge at the inlet side of an opening 14 of the circular tube part 16. Note that the circular tube part 16 is curved so that the diameter of its front end side expands and the circular tube part 16 is loosely connected with the peripheral edge of the opening 14. In this case, it is obtained the following expression: a / d> 0.1, where “a” is the distance between the indoor heat exchanger 4 and the flared mouth 13, that is, the distance between the indoor heat exchanger 4 and the inlet of the opening 14 of the flared mouth 13, and "d" is the diameter of the aperture 14 of the flared mouth 13. In other words, the distance "a" between the indoor heat exchanger 4 and the flared mouth 13 is equal to or greater than the diameter "d" of the opening 14 of the flared mouth 13. Note that the rear end of the circular tube portion 16 enters into a fan cover 53 (described below) through an opening in a front surface of the vent cover 53 dor. In addition, the opening 14 of the flared mouth 13 has an external shape that is smaller than that of the indoor heat exchanger 4 as seen from the front.

<AIR BLOWING DEVICE 5>

The air blowing device 5 is disposed behind the flared mouth 13 and generates an air flow in which air is sucked from each of the air inlets 8 to 11, passes through the indoor heat exchanger 4 and the opening 14 of the flared mouth 13, and is ejected from each of the air outlets 6 and 7. The air blowing device 5 is a turbo fan that sucks air from the front and causes the wind to be ejected in a cnfuga address. The air blowing device 5 includes a fan rotor 51, a fan motor 52 and the fan cover 53.

The fan rotor 51 is arranged so that an axis of rotation AX thereof is horizontal. The fan rotor 51 includes a plurality of blades arranged so that they form a spiral that moves away from the axis of rotation AX.

The fan motor 52 is a driving source for rotationally driving the fan rotor 51 and is arranged behind the fan rotor 51.

The fan cover 53 is an element that is arranged in front of the fan rotor 51. An opening through which the air that is admitted in the fan cover 53 passes is disposed on the front surface of the fan cover 53. Air that passes through the opening on the front surface of the fan cover 53 branches up and down as a result of being ejected in a centrifugal direction by the fan rotor 51 and is expelled into the room from the first outlet of air 6 and the second air outlet 7.

<CARACTERFSTICAS>

(one)

In the air conditioner 1, the front panel 22 is provided with the air inlets 8 to 11 on the upper surface 25, the right side surface 23, the left side surface 24 and the lower part of the surface

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front, respectively, and has the flat panel portion 20 with a smooth shape in the center. Therefore, it is possible to improve the external appearance of the air conditioner 1 as observed from the front, thus allowing an improvement of the aesthetic appearance.

In addition, the air inlets 8 to 11 are arranged outside the opening 14 of the flared mouth 13 as seen from the front. Therefore, it is possible to allow the air that is sucked from the air inlets 8 to 11 to pass through a larger area of the indoor heat exchanger 4, thereby allowing an improvement in the air conditioning efficiency.

Furthermore, because the fourth air inlet 11 is provided at the bottom of the front surface of the front panel 22, it is possible to increase the suction area while eliminating an increase in the size of the other inlets 8 to 10 of air. Therefore, it is possible to eliminate an increase in the thickness of the front panel 22 caused by the increase in size of the other air inlets 8 to 10, thereby allowing the external shape of the air conditioner 1 to be thinner.

(2)

Although the arrangement of the air inlets 8 to 11 as described above increases the resistance to suction, in this air conditioner 1 it is possible to sufficiently guarantee the necessary static pressure because an air flow is generated by the air blowing device 5 which is a turbo fan.

Also, in the air conditioner 1 according to the present invention, a necessary air flow can be generated by a turbo fan, unlike the case in which a single-pass fan is provided at each of the upper and lower air outlets as in the conventional air conditioner. Therefore, it is possible to reduce the manufacturing cost.

(3)

Although the use of the turbo fan when the arrangement of the air inlets 8 to 11 is as described above can increase the suction noise, the air conditioner 1 can reduce the suction noise because the total suction area S of the air inlets 8 to 11 is equal to or greater than 15% of the projected area B of the indoor heat exchanger 4 as observed from the front. In other words, as shown in Figure 6, a sufficient effect of reduction of suction noise in the range in which S / B> 15% can be obtained. Note that, because an increase in the value of S / B leads to an increase in the total suction area, it is better if the value of S / B is lower in terms of reducing the size of the air conditioner 1. Considering This is more preferable than 0.15 <SB <0.35, for example, S / B = 0.2.

Also, when an air flow is generated by a turbo fan arranged behind the indoor heat exchanger 4, the air tends to flow unevenly mainly through the center of the indoor heat exchanger 4, which can reduce efficiency heat exchange; however, the air conditioner 1 can further improve the air conditioning efficiency because the distance "a" between the indoor heat exchanger 4 and the flared mouth 13 is equal to or greater than 10% of the diameter "d "Of the opening 14 of the flared mouth 13, allowing air to flow easily through a larger area of the indoor heat exchanger 4. In other words, as shown in Figure 7, a sufficient effect of an increase can be obtained in the air conditioning efficiency in the range in which a / d> 10%. Also, because an increase in the value of a / d entails an increase in the distance between the indoor heat exchanger 4 and the flared mouth 13, it is better if the value of a / d is smaller in terms of the reduction of air conditioner thickness 1. Considering this, it is more preferable that 0.1 <a / d <0.25, for example, a / d = 0.15.

<ANOTHER MODE OF REALIZATION>

(one)

In the embodiment described above, all the air inlets 8 to 11 are arranged in the front panel 22. However, one, some or all of the air inlets 8 to 11 may be arranged in the main housing body 21, specifically in a part or parts located around the front panel 22.

(2)

In the embodiment described above, the air conditioner 1 is the floor support air conditioner. However, the present invention can be applied to a wall-mounted air conditioner and a ceiling-integrated air conditioner.

In the embodiment described above, the air inlets 8 to 11 are located outside the opening 14 of the flared mouth 13 as seen from the front. However, they may be located in a certain way within the opening 14 of the flared mouth 13. For example, the air inlets 8 to 11 may be located within the opening 14 of the flared mouth 13 provided that the air inlets 8 to 11 are not located within a peripheral boundary that is concentric with and 80% of the inside diameter of the opening 14 of the flared mouth 13. In other words, any modification of this type can be made provided that the air inlets 8 to 11 are located outside a peripheral boundary that is concentric with and 80% of the inside diameter of the opening 14 of the flared mouth 13 as seen from the front.

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Industrial applicability

The present invention has the effect of guaranteeing the necessary static pressure even when the arrangement of air inlets is such that the resistance to suction tends to increase and the present invention is useful as an air conditioner.

Claims (1)

5 10 fifteen twenty 25 30 35 Air conditioner (1), comprising: a heat exchanger (4); a flared mouth (13) arranged behind the heat exchanger (4) so that an opening (14) thereof through which air passes is oriented towards the heat exchanger (4); a housing (2) having a front panel (22) that covers the front side of the heat exchanger (4) and is provided with air inlets (8-11) and air outlets (6, 7); Y a turbo fan (5) arranged behind the flared mouth (13) and configured to generate an air flow in which air is sucked from the air inlets (8-11), passes through the heat exchanger (4) and the opening (14) of the flared mouth (13), and is ejected from the air outlets (6, 7), in which The total suction area of the air inlets (8-11) is equal to or greater than 15% of the projected area of the heat exchanger (4) as observed from the front, characterized in that the air inlets (8 -11) are provided on the front panel (22) and / or around it, and are located substantially outside the opening (14) of the flared mouth (13) as seen from the front . Air conditioner (1) according to claim 1, characterized in that The distance between the heat exchanger (4) and the flared mouth (13) is equal to or greater than 10% of the diameter of the opening (14) of the flared mouth (13). Air conditioner (1) according to claim 1 or 2, characterized in that: the central part of the front panel (22) has a flat panel part (20), in which no opening is provided, and the air inlets (8-11) are provided around the flat panel part (20) . Air conditioner (1) according to any one of claims 1-3, characterized in that: The flat panel part (20) is arranged so that it overlaps with the opening (14) of the flared mouth (13) as seen from the front and is located in front of the heat exchanger (4).