KR0131452Y1 - The shroud for outdoor unit of airconditioner - Google Patents

Abstract

The present invention relates to an outdoor unit shroud structure of an air conditioner, and more particularly, to an asymmetric shroud of an air conditioner for increasing the flow rate by changing the shape of the shroud, which is formed asymmetrically according to the shape of the heat exchanger side. The shorter side shroud length of the side heat exchanger increases heat exchange performance and blowing efficiency.

Description

Outdoor unit shroud of air conditioner

1 is a schematic diagram of a typical outdoor unit equipped with a conventional shroud.

2 is a set of airflow experiment set according to the position of the fan and shroud.

3 is a shape of the shroud extended in length near the front heat exchanger side.

Figure 4 is a view showing a shrouded shape of the asymmetrical shape of the present invention.

Figure 5 (a) (b) (c) is a view showing an asymmetrical shape of the shroud is another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: outdoor unit 2,2 ': shroud

3: fan 4: front heat exchanger

5: side heat exchanger 6: discharge grill

The present invention relates to the outdoor unit shroud structure of the air conditioner, and more particularly to the asymmetric shroud of the air conditioner for increasing the flow rate by changing the shape of the shroud.

The shroud serves to collect the fluid sucked by the fan from the front of the fan toward the discharge grill in the shape of a bell mouse.

The conventional shroud (2) structure, which is applied to the outdoor unit (1) of the separate air conditioner and collects the fluid toward the discharge port, has a lower portion of the fan (3) that sucks the fluid in the front and side portions of the outdoor unit body as shown in FIG. Located at and located between the front heat exchanger 4 and the side heat exchanger 5, the fluid sucked by the fan 3 is discharged through the discharge grill 6.

In addition, the installation position of the shroud (2) is closely related to the amount of fluid to be sucked, so the flow rate increases as the position is determined to the upper side as close to the fan (3) as possible, but in the general horizontal and vertical heat exchanger Increasing the length of (2) increases the flow intake amount from the front heat exchanger 4 side, but decreases the flow rate by relatively blocking the fluid intake from the side heat exchanger 5.

In consideration of this, the shroud 2 is not inserted deeply into the fan 3 so that the end thereof is almost coincident with the side heat exchanger 5 so as not to interfere with the fluid suction in the side heat exchanger 5. will be.

In order to ideally increase the air volume of the fan 3, as shown in the fan test set of FIG. 2, the length of the shroud 2 is increased to maintain the shape of accommodating the fan 3. A large flow rate can be sucked through the heat exchanger 4.

The rough air flow experiment set of FIG. 2 comprises a motor 7 which is a rotation means for rotating the fan, a shaft 8 which is a rotational force transmission means, and an axial fan 3 to form a length (height) of the shroud 2. This is to test the air volume of the fan (3) according to the conversion. As the length (1) of the shroud (2) increases, the air volume of the fan (3) increases, the flow rate sucked increases, and then A section (about 50mm Is exceeded, the flow rate is rather reduced.

This results in the fan 3 rotating in the shroud 2, resulting in a decrease in airflow.

3 is a conventional embodiment in which the airflow is increased by ideally extending the length of the shroud 2, which can increase the amount of fluid suction through the front heat exchanger 4 in at least the vertical direction to satisfy the side heat exchanger 5. The side fluid suction amount is significantly lowered, and the overall flow rate is reduced.

According to the conventional outdoor unit shroud structure, the flow rate increases as the shroud is extended toward the fan, but when the length of the shroud increases in the vertical horizontal heat exchanger, the fluid intake from the side heat exchanger is blocked and the flow rate decreases. Blowing operation efficiency is lowered, there was an uneconomical problem.

An object of the present invention is to provide a shroud shape for simultaneously satisfying the fluid suction of the side heat exchanger of the outdoor unit and the fluid suction through the front heat exchanger.

The shroud structure of the present invention for achieving the above object forms asymmetrical shapes of the shroud according to the flow shape of the fluid flowing through the front and side heat exchangers, thereby improving the heat exchange ability of the air conditioner on the outdoor side. It improves and raises the blowing efficiency.

The configuration of the present invention is as follows.

The shroud structure of the present invention, which is installed in the outdoor unit of the air conditioner, is configured in an asymmetric shape according to the flow characteristics of the incoming fluid.

4 is a view showing an embodiment of the present invention shroud (2 ') is formed in an asymmetrical shape close to the front heat exchanger (4) side when the side heat exchanger (5) side is low and the opposite side is formed relatively high fan Rotation of (3) was configured to suck the fluid through the front and side heat exchanger (5).

(A) (b) (c) of FIG. 5 shows an asymmetric shape of the shroud 2 'which is another embodiment of the present invention,

(a) is the length gradually decreasing toward the side heat exchanger 5 side with respect to a center line, and after that, it is a shape which has a substantially horizontal length.

(b) is an asymmetrical shape of the shroud 2 'in which the length of the side heat exchanger 5 is lowered regardless of the center line,

(c) has a shape in which the length of the shroud 2 'is lowered toward the side heat exchanger 5 in a gentle curved shape around the center line.

The shroud structure of the present invention including the shroud shape of FIG. 4 is commonly formed in an asymmetrical shape having a low shape on the side of the side heat exchanger 5.

Effects of the present invention configured as described above are as follows.

The present invention increases the flow rate of the side heat exchanger (5) side and the front heat exchanger (4) side to increase the heat exchange capacity and the blowing efficiency in the outdoor air conditioner, thereby increasing the fluid flow force to collect in the shroud (2 ') To increase.

The shape, structure and volume of the heat exchanger affect the flow of the fluid, so that the fluid entering the blowing suction of the fan 3 exhibits asymmetrical flow direction.

The uniform shroud shape cannot guarantee sufficient air flow rate of the fan 3, so that the flow rate is reduced, the heat exchange capacity is lowered, and the blowing efficiency is lowered.

According to the fan airflow experiment shown in FIG.

Through this experiment, it can be seen that the length of the shroud is related to the air volume of the fan 3, but in order to ensure a good air flow, the length of the shroud body is appropriately close to the fan 3 side.

And, the air volume determines the somewhat of the fluid suction amount through the heat exchanger (4) (5).

In the related art, in consideration of fluid suction from the side heat exchanger 5 side, the length of the shroud was limited to be kept low and formed to enable side and front fluid inflows, but in terms of efficiency.

The shroud 2 'structure of the present invention increases the fluid suction amount regardless of the direction in the outdoor unit 1 of the air conditioner having side and front heat exchangers 4 and 5.

That is, the movement of the fluid shows asymmetry under the structural influence of the heat exchanger, but if the shroud shape is changed accordingly, the flow of the fluid can be maximized freely.

In particular, the closer the shroud 2 'to the fan 3 side is, the more the air volume can be increased, and the length thereof is extended to the front heat exchanger 4 side and the other side side heat exchanger 5 side is reduced. By zooming, the asymmetrical shape is shown by forming a shape in which the fluid can be sucked without blocking the fluid flow by the shroud 2 'body.

4 shows a typical asymmetric shroud 2 'of the present invention, which is short in the lateral direction and longer in the other, and (a) (b) (c) of FIG. In another embodiment, the shroud shape is modified to match the flow shape of the incoming fluid.

As such, the present invention changes the shroud shape according to the flow shape of the inflowing fluid to increase the flow rate, thereby improving the heat exchange capacity of the air conditioner outside, and using the same driving force for driving the fan as compared to the conventional shroud structure. It is possible to drive economically with better wind power.

Claims (2)

Located in the lower part of the fan that sucks the fluid of the front and side of the outdoor unit main body, located between the front heat exchanger and the side heat exchanger, the side heat exchange in installing the shroud to discharge the fluid sucked by the fan through the discharge grill, An outdoor unit shroud of an air conditioner, wherein the length of the shroud on the side of the flag and the length of the shroud on the opposite side are formed asymmetrically with respect to the center of the fan shaft. 2. The outdoor unit shroud of the air conditioner according to claim 1, wherein the side heat exchanger side shroud located at the side of the fan is shortened and asymmetrically formed.