KR20090085889A - Fan assembly - Google Patents

Abstract

A ventilation fan assembly is provided to stabilize airflow by using a second shroud and reduce the flickering of the shroud due to the airflow. A ventilation fan assembly comprises a ventilation fan(140), a first shroud, a second shroud, and a joint. The ventilation fan produces the air flow. The first shroud guides the air flowing from the ventilation fan to the outside. The second shroud is formed behind the first shroud. The outer circumference of the transverse section of the second shroud is curved to stabilize the airflow generated behind the ventilation fan. The outer circumference of the transverse section of the second shroud is formed with a circular shape. The joint is integrally formed with the first shroud and the second shroud. The joint couples the first shroud and the second shroud.

Description

Blower fan assembly

The present invention relates to a blower fan assembly, and more particularly to a blower fan assembly comprising a second shroud to stabilize the air flow.

When the blowing fan rotates, air flow is generated by the blades. Airflow is guided out through the shroud. When the air flow is guided to the shroud, the shroud of the shroud or noise caused by the air flow is generated. In addition, the rear portion of the blade is severely caused by the air flow, the shroud of the shroud or noise is increased. However, in the conventional blower fan assembly, the rear portion of the shroud is formed above the rear portion of the blade. Therefore, the shroud and noise of the shroud could not be solved, and there was a problem in that air flow could not be effectively guided to the outside.

It can reduce the noise caused by air flow generated from the blade of the blower fan.

The present invention provides a blower fan for generating a flow of air, a first shroud for guiding the air flowing from the blower fan to the outside, and a rear of the first shroud, which is generated at the rear of the blower fan. It provides a blower fan assembly comprising a second shroud is formed in a curved outer peripheral surface of the cross section to stabilize the air flow.

The blowing fan assembly according to the present invention includes a second shroud for stabilizing air flow. Therefore, the shroud of the shroud due to the air flow generated by the rear portion of the blade can be reduced. In addition, it is possible to solve the noise problem caused by the shroud of the shroud.

Blower fan assembly is applicable to a variety of devices. Hereinafter, as an embodiment, a blower fan assembly used for an outdoor unit of a multi-type air conditioner will be described.

1 is a perspective view showing an outdoor unit 100 including a blowing fan assembly 180 according to the present invention. FIG. 2 is a cross-sectional view taken along II-II of FIG. 1. 3 is an air flow diagram schematically showing the air flow of the outdoor unit 100 shown in FIG. 1.

1 and 2, the outdoor unit 100 includes a cabinet 120, air inlets (not shown) disposed in the cabinet 120 and configured to allow external air to flow therein, and the air. Heat exchangers 161 and 162 in which heat is exchanged between the external air introduced from the inlet and the internal refrigerant, a compressor 171 for supplying internal refrigerant heat exchanged with the external air to the heat exchangers 161 and 162, and heat exchangers Blowing fan assembly 180 for forming the air flow to induce forced flow of the heat-exchanged air in the (161,162) and to transmit the rotational force to the blowing fan 140 included in the blowing fan assembly 180 And a motor 150.

The cabinet 120 includes a front plate 122 forming a front surface, a base 123 disposed under the front plate 122 to support various devices, and a front plate 122 disposed above the base 123. And a cabinet body 124 coupled to the top plate, and a top plate 121 disposed on the cabinet body 124 and coupled thereto. The cabinet body 124 includes a right surface air inlet (not shown) formed to allow outside air to enter and exit, and a right surface grill 170 for removing foreign substances contained in air flowing in the right surface air inlet. . In addition, the cabinet body 124 may include a seat air inlet (not shown) formed to allow outside air to enter and exit, and a seat grill (not shown) for removing foreign matter contained in air flowing in the seat air inlet. It includes.

The blower fan assembly 180 receives the rotational force of the motor 150 to blow the air inside to the outside, and the shroud 140 to guide the air flowing by the blower fan 140 to the outside. ).

Referring to FIG. 3, when an indoor unit (not shown) of the multi-air conditioner operates, the outdoor unit 100 operates. When the outdoor unit 100 operates, a signal for operating the motor 150 is applied. The motor 150 receiving the signal rotates the blower fan 140, and the blower fan 140 rotates to discharge the internal air to the outside. When the air is discharged, outside air enters the cabinet 120 through the right surface air inlet and the left air inlet. The entered air is heat-exchanged with the internal refrigerant in the seat heat exchanger 161 disposed on the seat of the cabinet body 124. In addition, the air introduced through the right surface air inlet is exchanged with the refrigerant inside through the right surface heat exchanger 162 disposed on the right surface. The refrigerant inside the heat exchanger generates a refrigerant having a low temperature and high pressure through the compressor 171. The heat exchanged air flows inside the cabinet 120. The flowing air is discharged to the outside by the rotation of the blowing fan 140 rotated by the motor 150.

Since the motor 150 rotates at a high speed, vibration or noise is generated, and the motor support structure 151 is disposed below the motor 150 to fix the motor 150. In addition, the condensed water generated from the left side heat exchanger 161 and the right side heat exchanger 162 is discharged laterally through the drain pan 163 formed long to the left and right.

4 is a perspective view showing an embodiment of the shroud 130 shown in FIG. FIG. 5 is a cross-sectional view taken along the line VV of FIG. 4.

4 and 5, the shroud 130 is formed at the rear of the first shroud 131 and the first shroud 131 for guiding the air flowing from the blowing fan 140 to the outside. And a second shroud 133 having a curved outer circumferential surface in a curved shape so as to stabilize the air flow generated from the rear of the blowing fan 140. In addition, the shroud 130 is fastened with the discharge grill 110 to prevent the foreign matter from contacting the blowing fan 140. When the blowing fan 140 rotates, the internal air of the outdoor unit 100 flows to the outside. The flowing air is guided outward by the first shroud 131. When the blowing fan 140 rotates, the flow of air in the rear portion of the blade 141 becomes unstable. The unstable air collides with the shroud 130 and the cabinet body 124 to generate vibration and noise. The second shroud 133 has a curved outer circumferential surface to stabilize the unstable air. Therefore, the unstable air is stabilized by the second shroud 133, and noise or vibration caused by the unstable air is reduced.

The second shroud 133 may have various outer circumferential surfaces thereof. The outer circumferential surface of the cross section of the second shroud 133 may be formed in a circular shape. In addition, the outer circumferential surface of the cross section of the second shroud 133 may be formed in an elliptical shape. When the second shroud 133 is formed in an elliptical or circular shape, the unstable air collides with the second shroud 133 to change the flow of air into a uniform shape. Therefore, the unstable air is stabilized and noise or vibration is reduced.

Meanwhile, the rearmost portion of the blade 141 may be disposed between the front end and the rear end of the second shroud 133. Air flowing through the shroud 130 collides with the rearmost portion of the blade 141 to hinder the flow of air. Thus, the flow of air in the rearmost portion of the blade 1410 becomes unstable. By arranging the rearmost portion of the blade 141 between the front and rear ends of the second shroud 133, the unstable air flow can be stabilized. That is, the flow of the unstable air formed in the rearmost portion of the blade 141 is formed in a narrow space between the second shroud 133 and the blade 141 to collide with the second shroud 133 quickly. . It is discharged to the outside with the air flowing from the bottom of the blowing fan 140 to the top. Therefore, the flow of air does not become unstable, and the flow of air is stabilized.

In addition, the shroud 130 is formed integrally with the first shroud 131 and the second shroud 133, the coupling portion for coupling the first shroud 131 and the second shroud 133. 132 may be further included. The coupling part 132 may be coupled to form a curved portion of each of the portions connected to the first shroud 131 and the second shroud 133 so as to smoothly flow the air. The air flow formed by the rotation of the blowing fan 140 is discharged from the second shroud 133 to the outside via the first shroud 131. Air stabilized in the second shroud 133 flows into the first shroud 131 and becomes unstable when the connection portion is not formed in a curve. The coupling part 132 is coupled to form a curve with the first shroud 131, and is coupled to form a curve with the second shroud 133. The coupling part 132 is coupled to form a curve with the first shroud 131 and the second shroud 133 so that the flow of air is discharged to the outside in a stabilized state. Therefore, by stabilizing the flow of air, it is possible to reduce the energy used by the motor 150. In addition, by stabilizing the flow of air, it is possible to smoothly flow the air and to efficiently discharge the heat exchanged to the outside of the outdoor unit (100).

6 is a perspective view showing another embodiment of the shroud 130 shown in FIG. FIG. 7 is a cross-sectional view taken along the line VIII-VIII of FIG. 6. The same reference numerals as those in the above-described embodiments represent the same members, and the following description will be mainly focused on points different from the above-described embodiments.

6 and 7, the blower fan assembly 280 may include heat exchangers 161 and 162 for exchanging heat from the cabinet 120 and the air outside the cabinet 120 and the refrigerant flowing therein, and the second shroud. It is formed extending from the 233, and further comprises a guide member 235 is formed to be coupled to the cabinet 120 and the second shroud 233. The guide member 235 may be formed in a curved portion where the guide member 235 and the second shroud 233 are coupled to each other so that the air exchanged in the heat exchangers 161 and 162 may be guided to the blowing fan 140. .

In addition, the guide member 235 may be formed in a quadrangle to be coupled to the cabinet 120. When the guide member 235 is formed in a square, each corner may be rounded to remove noise and vibration due to air flow. The guide member 235 is formed in a quadrangular shape and can be easily coupled to the cabinet 120. Air formed while the blowing fan 140 rotates is discharged to the outside of the cabinet 120 through the heat exchangers 161 and 162. The air passes through the heat exchangers 161 and 162 and then flows to the guide member 235. Air guided to the guide member 235 is guided to the first shroud 231 through the second shroud 233. Therefore, the air flowing therein through the guide member 235 may effectively guide the shroud 130.

8 is a cross-sectional view showing another embodiment of the shroud 130 shown in FIG. The same reference numerals as those in the above-described embodiments represent the same members, and the following description will be mainly focused on points different from the above-described embodiments.

Referring to FIG. 8, the shroud 330 may further include an air storage member 336. The air storage member 336 is disposed on the second shroud 333 and is formed below the blade 341. In addition, the outer circumferential surface of the cross section spaced apart from the second shroud 333 is formed substantially the same as the second shroud 333. Since the air storage member 336 is disposed to be spaced apart from the second shroud 333, the air storage member 337 is formed. When the blowing fan 340 rotates, air flows behind the blade 341. In addition, the air flow becomes unstable by the flow of air generated in the rear of the blade 341, the unstable air flow vibrates the shroud 330 to generate noise.

On the other hand, the unstable air flow is extinguished or stabilized by the air storage member 336. In addition, when the unstable air flow exceeds the air storage member 336, the unstable air flow is stored by the air storage unit 337. The unstable air flow is stabilized by being stored in the air storage unit 337. Therefore, it is possible to effectively reduce the vibration or noise caused by the unstable air flow.

1 is a perspective view showing an outdoor unit including a blower fan assembly according to the present invention.

FIG. 2 is a cross-sectional view taken along II-II of FIG. 1.

3 is an air flow diagram schematically showing the air flow of the outdoor unit shown in FIG.

4 is a perspective view showing an embodiment of the shroud shown in FIG. 1.

FIG. 5 is a cross-sectional view taken along the line VV of FIG. 4.

6 is a perspective view showing another embodiment of the shroud shown in FIG. 1.

FIG. 7 is a cross-sectional view taken along the line VIII-VIII of FIG. 6.

8 is a cross-sectional view showing another embodiment of the shroud shown in FIG.

<Brief description of symbols for the main parts of the drawings>

100: outdoor unit 133,233,333: second shroud

110: discharge grill 140,240,340: blowing fan

120: cabinet 150: motor

130,230,330: Shroud 171: Compressor

131,231,331: first shroud 180,280,380: blower fan assembly

132: coupling part

Claims (8)

A blowing fan to generate a flow of air, A first shroud for guiding the air flowing from the blowing fan to the outside; And a second shroud formed at the rear of the first shroud and having a curved outer circumferential surface of the cross section to stabilize the air flow generated at the rear of the blower fan. The method according to claim 1, Blowing fan assembly of the outer peripheral surface of the cross section of the second shroud is formed in a circular shape. The method according to claim 1, And a coupling part integrally formed with the first shroud and the second shroud to couple the first shroud and the second shroud. The coupling part is a blower fan coupling unit for coupling a portion connected to the first shroud and the second shroud to form a curve so that the flow of air smoothly. The method according to claim 1, And the rearmost portion of the blade is disposed between the front and rear ends of the second shroud. The method according to claim 1, It is disposed to be spaced apart from the inner circumferential surface of the second shroud to correspond to the lower portion of the blade, the outer circumferential surface of the cross section is formed to substantially correspond to the cross section of the second shroud and the inner circumferential surface of the second shroud Blower fan assembly comprising an air storage member for storing air therebetween. The method according to claim 1, The blowing fan assembly, Cabinets, A heat exchanger configured to exchange heat between the air outside the cabinet and the refrigerant flowing inside the cabinet; A guide member extending from the second shroud and configured to couple the cabinet and the second shroud to each other; The guide member is a blower fan assembly having a curved portion of the coupling portion between the guide member and the second shroud so that the air heat exchanged in the heat exchanger can be guided to the blowing fan. The method according to claim 6, Blowing fan assembly is coupled to the cabinet, the guide member is formed in a square. The method according to claim 7, The guide member is a blower fan assembly is formed round each corner so that the noise and vibration caused by the air flow generated in the blade.

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