KR20180113314A - Air direction changeable condenser radiating apparatus - Google Patents

Abstract

The present invention provides an air direction-changeable condenser radiating apparatus capable of increasing an air volume and a wind speed by pulling an airflow behind a space and capable of changing an air discharge direction. The air direction-changeable condenser radiating apparatus according to the present invention is a condenser radiating apparatus cooling steam for heat deprival, condensation, and change. The present invention includes a frame-shaped case in which a space is formed for the condenser to be accommodated, a pair of curved first guide members facing each other being disposed in the space, a first opening hole being formed between the first guide members, and an inflow hole being formed in the back surface of the case, a cover in which a pair of second guide members facing each other are disposed in the middle of the front of the case, a second opening hole communicating with the first opening hole being formed in the middle of the cover, discharge holes being formed on both sides of the second opening hole, and air being allowed to be discharged to the outside from the inside of the second opening hole through the discharge holes, a rotating unit discharging the heat that is heat-exchanged in the condenser to the discharge hole by suctioning outside air into the space through an inflow hole in the event of mutual reverse rotation by power means with facing rotating blades formed side by side in the space, and a grill provided in the cover and capable of changing the direction of the air discharged through the second opening hole and the discharge port.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a condenser heat-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a condenser heat dissipating device capable of air direction switching, and more particularly, to a condenser heat dissipating device capable of switching air direction that can dissipate heat of a condenser to cool it.

Generally, a condenser is a device that cools a steam to take heat and change its condensation. A refrigerator is a compressor that cools a refrigerant vapor that is compressed to a high pressure and a high temperature, and liquefies it by removing condensation heat. Cooling methods include water cooling, air cooling, evaporation, and the like, and there are condensers of various structures depending on the purpose of use.

Such a condenser is mainly used for a device using a refrigerant such as a refrigerator, a freezer, and an air conditioner. Typically, it includes an indoor unit and an outdoor unit of an air conditioner. The indoor unit of the air conditioner is usually provided with a heat exchanger and a blower unit for lowering the temperature of the room air sucked through the suction grille, and a control unit for adjusting the air volume and the set temperature is provided at the center of the front face.

In particular, a condenser is provided inside the outdoor unit. The outdoor unit includes a compressor for compressing the refrigerant at a high temperature and a high pressure, a condenser for receiving the high temperature and high pressure refrigerant from the compressor and radiating heat to make the refrigerant at a low temperature and a high pressure, An axial fan for lowering the temperature by blowing air to the condenser, and a housing for housing the compressor, the condenser, the expansion device, and the axial flow fan.

The heat discharged from the condenser is discharged to the outside through the blower.

As shown in Korean Utility Model Registration No. 20-0282107, a condenser installed in an outdoor unit of a room air conditioner is provided with condensate discharged from an indoor unit installed in the condenser, And a radiating means for radiating heat to the condenser by water-cooling by supplying the condensed water to the surface of the condenser.

However, the heat dissipating structure of the conventional condenser is disadvantageous in that it adopts a relatively high output motor because the discharge amount of wind is determined in relation to the number of revolutions of the rotary vane.

That is, the factor determining the wind strength is determined by the size of the rotor blade and the number of revolutions, but it is impossible to prevent the reduction of the input-output power of the energy used by the motor. There is an urgent need to propose a technology to double.

Generally, the heat dissipating device is disposed outdoors, but there is a disadvantage that it generates discomfort because hot air is discharged toward passengers passing near the heat dissipating device.

The object of the present invention is to provide a condenser heat dissipating device capable of switching the direction of the air to be able to discharge the heat inside the condenser to the outside due to a difference in air pressure in a space formed between two rotating blades, have.

In addition, the present invention is characterized in that the rotary vanes are installed so as to face each other in two rows, and then the rotary vanes are rotated in opposite directions, but the air pressure generated by the two rotary vanes causes the air pressure difference of the first opening formed between the two rotary vanes The present invention has another object to provide a condenser heat dissipating device capable of increasing the air flow rate and wind speed by pulling the air flow of the condenser.

The present invention also provides a condenser heat dissipation device capable of switching the air direction by doubling the wind velocity and the air flow rate by the airflow flowing along the second opening hole when the air volume delivered through the rotary vane is delivered to the outside through the exhaust hole. For example.

It is another object of the present invention to provide a condenser heat dissipating device capable of changing the direction of air so that the discharge direction of air can be adjusted.

A condenser heat dissipating device according to the present invention is a condenser heat dissipating device that cools and condensates heat by cooling the steam. The condenser heat dissipating device includes a space in which the condenser is accommodated and curved Shaped case in which a pair of first guide members are arranged so that a first opening is formed between the first guide members and an inflow hole is formed in the back side, and a pair of second guide members facing the front center of the case A cover having a second opening communicating with the first opening at the center of the cover and having a discharge hole formed on both sides of the second opening so that air is discharged from the second opening to the outside through the discharge hole; In the space, the rotating blades are formed so as to face each other side by side. When the rotating blades are rotated in opposite directions by the power means, the outside air is sucked into the space by the inflow hole, And the rotation part standing exhaust ball discharging the heat exchange column, is provided on the cover, it can be configured as the outlet port and the second opening to draw to change the direction of the air discharged through the ball.

Preferably, the grill includes a plurality of narrow and long plate-like grill fins; And a grill shaft each of which is provided on the grill pin and is rotatably coupled to the cover.

Preferably, the grill pins are connected to each other and can rotate together.

The condenser heat dissipating device capable of switching the air direction of the present invention can discharge the heat inside the condenser to the outside due to a difference in atmospheric pressure of the space and attract airflow behind the space to increase airflow and wind speed, There is an effect that direction can be adjusted.

1 is a cross-sectional view illustrating a condenser heat dissipating device capable of air direction switching according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the particular embodiments, It is to be understood that the invention includes all modifications, equivalents, and alternatives falling within the scope. It should also be understood that various equivalents and modifications may be substituted for those at the time of the present application.

1 is a cross-sectional view illustrating a condenser heat dissipating device capable of air direction switching according to an embodiment of the present invention.

1, a condenser heat radiating apparatus 100 according to the present invention includes a case 110, a cover 120, and a cover 120. The condenser radiator 100 includes a case 110, a cover 120, And a rotation unit 130.

First, the case 110 is formed in the form of a polygonal frame, and the case 110 has at least one line segment constituting a polygon.

Alternatively, in the present invention, a case 110 having a rectangular shape with two line segments or four line segments is described, but the shape is not limited.

That is, in the embodiment of the present invention, each of the case 110 is provided so as to be installed in two rows so as to face the two rotating parts 130.

Specifically, a streamlined case 110 is provided, and a space 111 is formed in the case 110 so that the rotating blades 132 are vertically installed in two rows facing each other. The condenser 130 is accommodated in the space 111.

Here, the body of the polygonal case 110 is referred to as a frame.

In addition, an inflow hole 112 is formed on the back surface of the frame. The inlet bores 112 are preferably, but not limited to, a plurality of lengths or grids.

In addition, a first opening 114 is formed in the center of the case 110.

Particularly, the first opening hole 114 arranges a pair of first guide members 116 having a shape curved to face each other inside the space 111. The first opening 114 is formed through the first guide member 116. [

Further, the cover 120 is installed to face the front of the case 110. Particularly, the cover 120 is provided with a second opening 121 and an exhaust hole 123 communicating with the first opening 114 opened frontward. Air is exhausted from the inside of the second opening hole 121 to the outside through the exhaust hole 123.

In particular, the second opening 121 is provided with a pair of second guide members 125 facing the center of the cover 120 to form a second opening 121 at the center of the cover 120, 123 are formed.

This is because the air discharged through the one or more discharge holes 123 is partially merged while moving toward the second aperture 121 side through the first aperture 114, so that the flow velocity of the air advances rapidly.

That is, on the side of the second opening hole 121 of the case 110 having a high air velocity, the air pressure is lowered and the air pressure on the first opening hole 114 is relatively higher. As a result, since the force of the air acts as a low pressure in the high pressure, the air having a high speed passing through the case 110 passes the outside air together to form a constant and strong airflow, thereby generating wind.

Further, the rotating part 130 is housed in the space 111 of the case 110.

The rotary part 130 is formed so as to face the rotary blades 132 having a plurality of blades 132a on the outer periphery side by side and is rotated in opposite directions by the power means 133. [ In this way, outside air is sucked into the space 111 through the pair of rotating blades 132 by the inflow hole 112, and the heat-exchanged heat is discharged to the discharge hole 123 by the condenser 130.

In particular, the rotary vane 132 has a plurality of vanes 132b radially formed on the outer periphery of a shaft 132a having a length.

The power unit 133 is installed in each of the rotating blades 132 so that the rotating shaft 132a of the motor and the shaft 132a of the rotating blades 132 are connected to each other by a direct power method so that the rotating blades 132 can be rotated by the rotating force generated by the power unit 133.

As a result, in the condenser heat radiating apparatus 100 capable of changing the direction of air, the casing 110 having the frame shape and the cover 120 are coupled to each other. Then, the rotating portion 130 is installed in the inner space 111, When the inner pressure is increased and the air having a high flow velocity is discharged to the discharge hole 123, the air pressure is lowered on the side of the second opening hole 121 and the air pressure on the side of the first opening hole 114 is relatively increased. As a result, air having a high velocity discharged through the discharge hole 123 generates a difference in air pressure between the first opening 114 and the second opening 121, thereby discharging air from the second opening 121. That is, the ambient air of the cover 120 may generate airflow while passing through the cover 120, and the airflow rate may be increased by the difference in air pressure to discharge the heat to the outside, thereby releasing the heat discharged from the condenser to the outside.

In other words, the case 110 having the frame shape and the cover 120 are coupled to each other, and then the rotating blades 132 are installed in two rows on opposite sides of the inner space 111 so that the rotating blades 132 rotate in mutually opposite directions to increase the lift of the airflow It is possible to increase the effective blowing distance.

In addition, by rotating the two rows of rotating blades 132 opposed to each other in opposite directions and by the air pressure generated by the two rotating blades 132, by the air pressure difference of the first opening 114 formed between the two rotating blades 132 It is possible to increase the air flow rate and wind speed by pulling backward airflow.

That is, when the inner pressure of the first opening hole 114 of the case 110 is increased and the air having a high flow rate is discharged to the discharge hole while being discharged to the outside, the air flow and the air flow rate are further doubled by the airflow flowing along the second opening hole 121 There is.

In addition, the delivery amount of the plurality of rotary blades 132 can be determined or doubled.

In addition, if the number of revolutions of the rotary blades 132 installed in two rows is rotated differently, the blowing direction can be adjusted through the pressure difference.

1, the cover 120 has a grille on the side of the second opening 121 and the discharge hole 123, and the grille includes a grille pin 210 and a grille shaft 211. Each grille pin 210 is supported by a grille shaft 211 And is rotatably coupled to the cover 120. The grill pins 210 are manually rotated in the left and right direction. According to an embodiment of the present invention, the grill pins 210 are connected to each other. When one grill pin 210 rotates, the other grill pins 210 are interlocked can do. According to another embodiment of the present invention, the grill pins 210 are not connected to each other and can rotate independently.

Since the grill pin 210 can be rotated in the left and right direction, the discharge direction can be adjusted so that the discharged air is not directed to the passenger.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Various modifications and variations are possible within the scope of the appended claims.

100: condenser radiator 110: case
111: space 112: inflow hole
114: first aperture hole 116: first guide member
120: cover 121: second opening hole
123: discharge hole 125: second guide member
130: rotating part 132: rotating blade
132a: shaft 132b: wing
133: power means 210: grill pin
211: Grill shaft

Claims (3)

1. A condenser heat dissipating device for cooling a steam to remove heat and change the condensation,
A space in which the condenser is housed is formed in the space, and a pair of first guide members having a curved shape facing each other are disposed in the space, a first aperture is formed between the first guide members, and a frame shape And
A pair of second guide members facing the center of the front of the case are disposed so that a second opening is formed in the center of the cover so as to communicate with the first opening and a discharge hole is formed on both sides of the second opening, A cover for allowing air to be discharged from the inside of the two apertures,
A rotary part formed in the space so as to face the rotary vanes so as to face each other and to discharge the heat exchanged in the condenser to the discharge hole by sucking the outside air into the space by the inflow hole when the reciprocal rotation is made by the power means,
And a grill that is provided on the cover and is capable of changing a direction of air discharged through the discharge port and the second aperture.
The grill of claim 1,
A plurality of narrow and long plate-like grill pins; And
A grill shaft provided on each of the grill fins and rotatably coupled to the cover,
Wherein the condenser heat exchanger is capable of changing the air direction.
3. The method of claim 2,
And the grill pins are connected to each other to rotate together.

Images