KR0133375B1 - Cross flow fan - Google Patents

Abstract

The present invention relates to a crossflow blower, wherein when the H (discharge port size ratio of the rear guide) ≤ 40%, the outer circumferential angle of the crossflow fan is 25 ° to 30 °, and when the H40% is the outer circumferential angle of the crossflow fan If the rear guide and stabilizer are determined by the size and design of the indoor unit within 25 ° or less, the low noise and high wind flow characteristics of the crossflow fan are combined to ensure the optimal blowing performance according to the change of the flow path. will be.

Description

Cross Flow Blower

1 and 2 show a typical detachable air conditioner indoor unit,

1 is a side cross-sectional view.

2 is a perspective view.

3 is a partial cross-sectional view for explaining the design parameters of a general detachable air conditioner indoor unit.

4 to 6 show the cross-flow fan characteristic curve according to the outer circumferential angle of the cross-flow blower according to the present invention,

4 is a static pressure-airflow curve when H is 33%.

5 is a static pressure-air flow curve when H is 37%.

6 is the static pressure-airflow curve when H is 42%.

7 is a noise characteristic table according to the outer circumference according to the H range of the cross flow blower according to the present invention. (1000RPM)

The present invention relates to, for example, a cross-flow blower applied to a separate air conditioner indoor unit or other blower, in particular, if the rear guide and stabilizer is determined by the size and design of the indoor unit, The present invention relates to a crossflow blower that combines a crossflow fan to ensure an optimal blowing performance according to a change of a flow path.

A typical embodiment of a detachable air conditioner indoor unit to which a cross-flow blower according to the prior art is applied will now be described with reference to the accompanying drawings.

As shown in FIG. 1 and FIG. 2, the lateral flow fan 1 which generates vortex flow and rotates clockwise, and generates dynamic pressure, and generates a static pressure And a rear guide (2) for determining suction and discharge flow, a heat exchanger (3) for exchanging intake air, and a stabilizer (4) for separating intake and discharge areas. It is.

The indoor unit of the separate type air conditioner sucks air by using the suction pressure caused by the rotation of the cross flow fan 1, and passes the air-conditioned airflow at the discharge port 2a through the cooled or heated heat exchanger 3. Discharged.

On the other hand, Figure 3 shows the main design parameters (parameters) of the general detachable air conditioner indoor unit, α is the angle of the center line of the cross-flow fan (1) the outer periphery angle with the tangent of the outer diameter of the cross-flow fan (1). This outer circumferential angle is a factor that directly affects the magnitude of dynamic pressure generated by the crossflow fan 1.

Further, H is the discharge port 2a size ratio of the rear guide 2, and when a straight line is drawn from the center of the cross flow fan 1 to the rear guide 2, the length and the outer diameter between the outer diameter and the rear guide 2 are determined. It means rain. This H affects that the rear guide 2 converts the dynamic pressure generated by the cross flow fan 1 into the static pressure.

In the case of designing an air conditioner indoor unit according to the prior art, generally, the outer circumferential angle of the crossflow fan 1 is selected from the range of 20 ° to 30 °, and then the rear guide 2 determined by the size and design of the product. H value was used.

However, the problem of the prior art as described above is that the best performance is not obtained by empirically selecting α and H values, or by using the values determined by the size and design of the indoor unit set as they are without verification of performance.

In general, the greatest feature of the crossflow blower is that the flow path structure of the crossflow fan 1, the rear guide 2, and the stabilizer 4 is very complex, so that the crossflow fan 1 If the correlation between the outer circumferential angle and the size of the discharge port 2a of the rear guide 2 is not verified, a problem such as high noise and low air volume may be deteriorated in some cases.

An object of the present invention, when the rear guide and stabilizer is determined according to the size and design of the indoor unit, by combining the low noise and high air flow characteristics of the cross flow fan according to the cross-flow to ensure the optimal blowing performance according to the change of the flow path In providing a blower.

In order to achieve the above object of the present invention, when the H ≤ 40%, the outer circumferential angle range of the crossflow fan is 25 ° ~ 30 °, when the H40%, characterized in that the outer circumferential angle range of the cross flow fan is 25 ° or less A cross flow blower is provided.

Hereinafter, the cross-flow blower according to the present invention will be described in more detail.

The present invention is based on a study on the characteristics of the cross flow fan and the flow flow fan and the flow path structure closely and influence each other.

That is, the present invention is based on the static pressure-air volume curve and the noise characteristics, which were tested by changing the circumferential fan outer circumferential angle at H having various values.

The cross flow blower according to the present invention is characterized in that, in the case of H40%, the outer circumferential angle range of the crossflow fan is 25 ° to 30 °, and in the case of H40%, the outer circumferential angle range of the crossflow fan is 25 ° or less.

(However, H is the discharge port size ratio of the rear guide)

4 shows the crossflow fan static pressure-wind flow curve according to the crossflow fan outer circumferential angle when H = 33%. The outer circumferential angle shows the lowest performance at 23 °, and the static pressure in the order of 21 °, 25 °, and 27 °. -It can be seen that the airflow curve performance is improved. The higher the static pressure-airflow curve, the higher the pressure and the higher the airflow at the same fan speed.

In particular, the area indicated by the dotted line is an operating point when the heat exchanger is mounted in actual operation. When the static pressure-airflow curve characteristic is good in this area, the air volume and noise performance of the entire indoor unit set are also good.

In addition, FIG. 5 shows the crossflow fan static pressure-flow rate curve according to the crossflow fan outer circumferential angle when H = 37%. In this case, the same result as in the case of H = 33% is shown.

That is, the outer circumferential angle 23 ° shows the lowest performance, and the static pressure-airflow curve performance improves in the order of 21 °, 25 °, and 27 °. It can be seen that the difference is significantly reduced compared to H = 33%.

FIG. 6 shows the crossflow fan static pressure-airflow curve according to the crossflow fan outer circumference when H = 42%. In this case, the characteristics are different from those when H = 33% and H = 37%. That is, although the outer circumferential angle 23 ° shows the lowest performance, it can be seen that the static pressure-airflow curve characteristics are improved in the order of the outer circumferential angles 27 °, 25 °, and 21 ° in the driving point region.

As a result, when the H value changes from 37% to 42%, the selection of the circumferential fan outer circumferential angle must be different.

Table 1 shows the noise characteristics at the operating point when the circumferential fan outer periphery angles were varied for each H value range.

According to Table 1, in the case of the outer circumference angles 21 ° and 23 °, the noise level is not large as the H value increases, but when the outer angle is 25 ° or 27 °, the noise increases rapidly as the H value increases. . In addition, when H is 30 to 35%, the change in noise according to the outer circumference is small, but when H is 35% or more, the outer circumferences 21 ° and 23 ° have no difference in noise, but the outer circumferences 25 ° and 27 In the case of °, the noise rises sharply.

As a result, the following can be concluded.

In other words, when the H value is 40% or less, the circumferential fan outer circumferential angle should be 25 ° or 27, so that the performance of the static pressure-airflow curve is advantageous and the noise is low.

In addition, when the H value is 40% or more, the circumferential fan outer circumferential angle must be used at 21 °, so the performance of the static pressure-airflow curve is advantageous and the noise is small.

As described above, the crossflow blower according to the present invention sets the outer circumferential angle of the crossflow fan to 25 ° to 30 ° when H≤40%, and the outer circumferential angle of the crossflow fan to 25% when H40%. When the rear guide and the stabilizer are determined by the size and design of the indoor unit to be less than or equal to °, there is an effect of ensuring the optimum blowing performance according to the change of the flow path by combining the cross-flow fan of the low noise and high air flow characteristics accordingly.

Claims (1)

When H≤40%, the outer circumferential angle range of the crossflow fan is 25 ° ~ 30 °, and when H> 40%, the outer circumferential angle range of the crossflow fan is 25 ° or less. (However, H is the discharge port size ratio of the rear guide)