KR19990086341A - Indoor unit of separate air conditioner - Google Patents

Abstract

The present invention relates to an indoor unit of a separate air conditioner, and to optimize the ratio of the length of each part of the stabilizer and the rear guide to determine the diameter of the crossflow fan and the area of the discharge port to improve the blowing performance and minimize the discharge noise.

To this end, according to the present invention, as the cross flow fan 2 rotates in the main body 1, the air sucked through the inlet 3 of the main body 1 is cooled while passing through the heat exchanger 4, and then the stabilizer 5 ), And the diameter of the crossflow fan 2 is D, and the distance perpendicular to the rear guide at the inlet side of the stabilizer 5 is configured to discharge through the discharge port 7 between the rear guide 6 and the rear guide 6. Is A1, the distance perpendicular to the rear guide () at the exit side of the stabilizer 5 is A2, and when the total length of the stabilizer 5 is L, the ratio of A2-A1 to L is D. It is an indoor unit of a separate air conditioner of 18 to 36% of the.

Description

Indoor unit of separate air conditioner

The present invention relates to a separate air conditioner, and more particularly, to optimize the ratio of the length of each part of the stabilizer and the rear guide to determine the diameter of the crossflow fan and the area of the discharge port so that the blowing performance is improved and the discharge noise is reduced. It is.

In general, a separate air conditioner is an air conditioner in which an indoor unit installed indoors and an outdoor unit installed outdoors are separated, and the indoor unit and the outdoor unit are connected to a connection pipe to allow circulation of the refrigerant.

A general configuration of the indoor unit includes a main body 1 supported by a specific support, a cross flow fan 2 installed inside the main body and rotating under a driving force of a motor (not shown), and a front surface of the main body 1. A heat exchanger installed at the inlet port 3 to suck the indoor air during rotation of the cross flow fan 2, and installed immediately after the inlet port 3 in the main body 1 to convert the sucked hot air into cold air ( 4) and a discharge port 7 formed by a stabilizer 5 and a rear guide 6 in the lower part of the main body 1 to discharge the cold air heat-exchanged into the room.

Therefore, when the user selects the cooling mode while the indoor unit is installed with the main body 1 supported in place, the indoor unit operates together with the outdoor unit. In this case, the outdoor unit compresses the refrigerant and condenses it to the indoor unit. Therefore, as the refrigerant circulates the outdoor unit and the indoor unit, the indoor air is circulated by the operation of the indoor unit, and in this process, the indoor air is cooled as the hot air circulating the indoor unit is heat-exchanged with cold air.

The hot air circulating the indoor unit according to the user's selection of the cooling mode will be described below in more detail the process from cooling the room to the cycle while heat exchanged with cold air.

When the refrigerant compressed and condensed by the outdoor unit enters the heat exchanger 4 of the indoor unit and then enters the compressor of the outdoor unit again, the cross flow fan 2 in the indoor unit main body 1 drives the driving force of the motor (not shown). Since the air in the room is sucked into the main body 1 through the suction port 3 installed in the front of the main body 1, the sucked air is moved in accordance with the continuous rotation of the crossflow fan 2 while exchanging heat. Pass the flag (4).

As described above, when the air sucked into the main body 1 passes through the heat exchanger 4, the air in the room passing through the heat exchanger passes through the heat exchanger, considering that the refrigerant condensed by the outdoor unit passes. The cold air is exchanged into cold air, which is pressurized by passing the rotating crossflow fan (2), and then is converted into static pressure between the stabilizer (5) and the rear guide (6), and the stabilizer (5) and the rear guide (6) Since it is discharged into the room through the discharge hole 7 formed by the (), the room is dropped by a predetermined temperature or less, and eventually the room is cooled.

On the other hand, when the indoor unit assumes that the area of the suction port 3 is the same, the blowing performance is different depending on the diameter of the crossflow fan 2 and the area of the discharge port 7 formed by the stabilizer 5 and the rear guide 6. When the following, the blowing performance according to the diameter ratio of the cross flow fan (2) and the area of the discharge port 7 will be described.

When the diameter of the cross flow fan 2 is increased and the amount of air sucked through the inlet 3 increases, the discharge port 7 is not widened as the diameter of the cross flow fan 2 is increased. As the discharge amount according to the discharge area of the gas decreases as much as that of the suction amount, the blowing performance decreases eventually. If the area of the discharge port 7 is not narrowed as the diameter of (2) decreases, it is understood that the blowing performance of the cold air is lowered according to the area of the discharge port.

However, such a conventional indoor unit is assumed to have a constant diameter D of the cross flow fan 2, and thus the rear side of the stabilizer 5 is an element that determines the area of the discharge port 7 based on the diameter of the cross flow fan 2. The distance A1 perpendicular to the guide 6, the distance A2 perpendicular to the rear guide 6 at the exit side of the stabilizer 5, and the total length L of the stabilizer 5 are considered at all. Since it is not designed, there is a problem that the blowing performance is not improved, as well as the discharge noise is increased.

The present invention has been made in order to solve the above-mentioned problems, and by optimizing the ratio of the length of each part of the stabilizer and the rear guide to determine the diameter of the cross flow fan and the area of the discharge port, the blowing performance is improved and the discharge noise Its purpose is to drastically reduce this.

According to the aspect of the present invention for achieving the above object, the air sucked through the inlet port 3 of the main body 1 passes through the heat exchanger 4 as the cross flow fan 2 rotates in the main body 1. While being cooled and then discharged through the discharge port 7 between the stabilizer 5 and the rear guide 6, the diameter of the crossflow fan 2 is referred to as D, and the rear of the stabilizer 5 is located at the inlet side. The distance perpendicular to the guide 6 is A1, the distance perpendicular to the rear guide 6 at the exit side of the stabilizer 5 is A2, and the total length of the stabilizer 5 is L. An indoor unit of a separate air conditioner is provided in which the ratio of A2-A1 to D is 18 to 36% of D.

1 is a longitudinal sectional view for explaining the indoor unit of the present invention;

Figure 2 is a graph showing the blowing performance and the discharge noise in accordance with the present invention

Explanation of symbols for main parts of the drawings

1. Body 2. Cross flow fan

3. Intake 4. Heat Exchanger

5. Stabilizer 6. Rear Guide

7. Discharge port

L. Stabilizer Length

A1. Distance perpendicular to the rise guide from the entrance side of the stabilizer

A2. Distance perpendicular to the rise guide from the exit side of the stabilizer

D. Diameter of Crossflow Fan

Hereinafter, with reference to the accompanying Figures 1 to 2 showing the present invention as an embodiment in more detail as follows.

1 is a longitudinal cross-sectional view for explaining the indoor unit of the present invention, Figure 2 is a graph showing the blowing performance and the discharge noise according to the present invention, the present invention is a cross-flow fan (2) is rotated within the body (1) The air sucked through the inlet 3 of the main body 1 is cooled to pass through the heat exchanger 4 and then discharged through the outlet 7 between the stabilizer 5 and the rear guide 6. In this regard, the diameter of the crossflow fan 2 is referred to as D, the distance perpendicular to the rear guide 6 at the inlet side of the stabilizer 5 is referred to as A1, and the rear guide 6 at the outlet side of the stabilizer 5. Let A2 be a vertical distance, and let the ratio of A2-A1 to L be 18 to 36% of D when the entire length of the stabilizer 5 is L.

According to the present invention configured as described above, the hot air of the room sucked into the main body 1 through the suction port 3 as the cross flow fan 2 rotates with cold air while passing through the heat exchanger 4 and then the cross flow fan. Pressurized by (2), the pressurized cold air is changed to the static pressure passing between the stabilizer (5) and the rear guide (6), and then the discharge port (7) formed by the stabilizer (5) and the rear guide (6) It is discharged to the room through, in this case to the rear guide (6) at the outlet side of the stabilizer (5) for the entire length (L) of the stabilizer (5) based on the diameter (D) of the crossflow fan (2) Vertical distance A2-As the ratio of the distance A1 perpendicular to the rear guide 6 at the inlet side of the stabilizer 5 is 18 to 36% of the diameter of the cross flow fan 2, Surface of the discharge port 7 in a state where the air sucked by the rotation is discharged smoothly at a considerable pressure Since the air is optimized, the blowing performance is improved and the discharge noise is greatly reduced.

Meanwhile, as shown in FIG. 2, the experiment was performed while adjusting the ratio of A2-A1 to L with the diameter D of the crossflow fan 2 in the same state, and the ratio of A2-A1 to L was 18. When it was ˜36%, it was found that the inhaled air was discharged the most at the highest pressure, and the noise at this time was also greatly reduced.

Therefore, the distance A2 perpendicular to the rear guide 6 at the exit side of the stabilizer 5 with respect to the length L of the stabilizer 5 as in the present invention-the rear guide at the inlet side of the stabilizer 5 When the ratio of the distance A1 perpendicular to 6) is 18 to 36% of the diameter D of the cross flow fan 2, the cross flow fan 2 for rotating the cross flow fan 2 is based on the same air volume and noise as before. It is understood that even if the motor has a lower capacity than the conventional one, when the motor is replaced with the low capacity motor, the power consumption rate is reduced and the manufacturing cost of the device is also reduced.

Therefore, the present invention provides a rear guide at the inlet side of the stabilizer 5, which is an element that determines the area of the discharge port 7 based on the diameter of the cross flow fan 2 which simultaneously provides the suction force for sucking air and the discharged earth output. The distance A1 perpendicular to 6), the distance A2 perpendicular to the rear guide 6 at the exit side of the stabilizer 5, and the total length L of the stabilizer 5 are designed in a proper state. As a result, the blowing performance is improved, and the discharge noise is greatly reduced.

Claims (1)

As the cross flow fan rotates in the main body, the air sucked through the intake port of the main body is cooled through the heat exchanger and then discharged through the discharge port between the stabilizer and the rear guide, and the diameter of the cross flow fan is referred to as D. The distance perpendicular to the rear guide at the inlet side of the stabilizer is called A1, and the distance perpendicular to the rear guide at the outlet side of the stabilizer is referred to as A2, and when the total length of the stabilizer is referred to as L2- The indoor unit of a separate air conditioner, wherein the ratio of A1 is 18 to 36% of D.