This application claims the benefit of Korean Patent Application No. 10-2010-0106371, filed on Oct. 28, 2010 in the Korean Intellectual Property Office, the disclosure of which is incorporated herein by reference.
1. Field
Embodiments of the present disclosure relate to a heat exchanger with an improved heat exchange structure.
2. Description of the Related Art
A heat exchanger is mounted in devices operating based upon a refrigeration cycle, such as air conditioners or refrigerators. The heat exchanger includes a plurality of heat exchanger fins and a refrigerant pipe extending through the heat exchanger fins to guide a refrigerant. Contact area between the heat exchanger fins and external air introduced to the heat exchanger is increased to improve heat exchange efficiency between the refrigerant flowing in the refrigerant pipe and the external air.
When the contact area between the heat exchanger fins and external air contacting the heat exchanger fins is large or when resistance applied to air contacting the heat exchanger fins is small, heat exchange efficiency is increased. However, if the contact area between the heat exchanger fins and air is too large, large resistance is applied to air passing through the heat exchanger fins. On the other hand, if the contact area is reduced to lower resistance applied to air, heat exchange efficiency is lowered. For this reason, it may be necessary to provide fins having an optimal shape based on the heat exchanger employed.
For a heat exchanger used as an evaporator (that is, the refrigeration cycle performs a heating operation), if outdoor temperature is too low, the surface temperature of the heat exchanger is lowered to below zero Celsius, and moisture contained in outdoor air is attached to the surface of the cold heat exchanger in a frozen state, thereby reducing heat exchange efficiency of the heat exchanger.
It is an aspect of the present disclosure to provide a heat exchanger having a structure to effectively achieve heat exchange between air and heat exchanger fins.
It is another aspect of the present disclosure to provide a heat exchanger having a structure to restrain frost formation on the surfaces of heat exchanger fins.
Additional aspects of the disclosure will be set forth in part in the description which follows and, in part, will be apparent from the description, or may be learned by practice of the disclosure.
In accordance with one aspect of the present disclosure, a heat exchanger includes a refrigerant pipe in which a refrigerant flows and a heat exchanger fin coupled to the outer circumference of the refrigerant pipe, wherein the heat exchanger fin includes a plate, a protrusion protruding from the plate, slits disposed at opposite sides of the protrusion to guide air to the protrusion, and a louver unit provided at the protrusion to perform heat exchange with the air having passed through the slits.
The louver unit may include first cutouts provided at the protrusion and a plurality of guide plates provided in parallel to each other so that the guide plates are spaced apart from each other by the respective first cutouts, the first cutouts and the guide plates being alternately arranged.
Each of the guide plates may have a width of 0.5 mm to 3 mm.
The protrusion may include first inclined surfaces inclined relative to the plate, the guide plates may be provided at the first inclined surfaces, and the angle between the guide plates and the first inclined surfaces may be 10 to 60 degrees.
Each of the slits includes second inclined surfaces inclined relative to the plate, a top surface formed between the second inclined surfaces, and a second cutout provided at the rear of the top surface.
The top surface may have a width of 0.5 mm to 5 mm.
The first inclined surfaces may be disposed at the plate in a symmetrical fashion, the distance between a line formed at the position where the first inclined surfaces join each other and the plate may constitute a height of the protrusion, and the protrusion may have a height of 0.5 mm to 4 mm.
The first inclined surfaces may be disposed at the plate in a symmetrical fashion, the distance between a flat surface connected between the first inclined surfaces and the plate may constitute a height of the protrusion, and the protrusion may have a height of 0.5 mm to 4 mm.
The heat exchanger fin may include a plurality of plates stacked at an interval.
In accordance with another aspect of the present disclosure, a heat exchanger includes a tube to guide a fluid and a heat exchanger fin contacting the tub to perform heat exchange between the fluid and external air, wherein the heat exchanger fin includes location holes in which the tube is located in a supported state, a protrusion provided between the location holes, the protrusion protruding in the extension direction of the tube, a slit disposed at the periphery of the protrusion to accelerate air introduced to the protrusion, and a louver unit formed at the protrusion to perform heat exchange between the air having passed through the slit and the fluid.
The louver unit may include a plurality of guide plates provided in parallel to each other so that the guide plates are spaced apart from each other and a plurality of first cutouts alternating with the guide plates.
The protrusion may include first inclined surfaces disposed in a symmetrical fashion to form a ‘V’ shape, and the guide plates and the first cutouts may be provided at the first inclined surfaces.
The angle between the first inclined surfaces and the guide plates provided at the first inclined surfaces may be 10 to 60 degrees.
Each of the guide plates may have a width of 0.5 mm to 3 mm.
The slit may include second inclined surfaces protruding in the extension direction of the tube, a top surface formed between the second inclined surfaces, and a second cutout provided at the rear of the top surface.
The top surface may have a width of 0.5 mm to 5 mm.
The protrusion may include first inclined surfaces disposed in a symmetrical fashion and a flat surface connected between the first inclined surfaces, the guide plates and the first cutouts being provided at the first inclined surfaces or the flat surface.
These and/or other aspects of the disclosure will become apparent and more readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:
Reference will now be made in detail to the embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout.
As shown in
The refrigerant pipe 20 is configured in the shape of a hollow tube in which the refrigerant flows. The refrigerant pipe 20 is lengthened to increase heat exchange area between the refrigerant flowing in the refrigerant pipe 20 and external air. However, it may be difficult to extend the refrigerant pipe 20 in one direction due to spatial restrictions. Consequently, the refrigerant pipe 20 is repeatedly bent at opposite ends of the heat exchanger 10 in opposite directions to efficiently increase heat exchange area per unit volume.
The refrigerant flowing in the refrigerant pipe 20 is formed by mixing different Freon products exhibiting different properties. For example, R-134a and R410A may be used.
The refrigerant may be phase changed (compressed) from a gas state to a liquid state to perform heat exchange with external air. On the other hand, the refrigerant may be phase changed (expanded) from a liquid state to a gas state to perform heat exchange with external air. When the refrigerant is phase changed from a gas state to a liquid state, the heat exchanger 10 is used as a condenser. When the refrigerant is phase changed from a liquid state to a gas state, the heat exchanger 10 is used as an evaporator.
The refrigerant, flowing in the refrigerant pipe 20, is compressed or expanded to discharge heat to the surroundings or to absorb heat from the surroundings. The heat exchanger fins 30 are coupled to the refrigerant pipe 20 so that the refrigerant efficiently discharges or absorbs heat during compression or expansion.
The heat exchanger fins 30 are disposed at a predetermined interval in the direction in which the refrigerant pipe 20 extends.
The heat exchanger fins 30 may be made of various metal materials, such as aluminum, exhibiting high thermal conductivity. The heat exchanger fins 30 are coupled to the outer circumference of the refrigerant pipe 20 in a contact state to increase contact area between the refrigerant pipe 20 and external air.
The interval between the heat exchanger fins 30 may be reduced to increase the number of the heat exchanger fins 30. If the interval between the heat exchanger fins 30 is too small, however, the heat exchanger fins 30 may act as resistance to air F introduced to the heat exchanger 10, as shown in
As shown in
The plate 40 is made of an aluminum alloy. The plate 40 is thin. The plate 40 includes location holes 32, through which the refrigerant pipe 20 extends in a contact state.
Each of the location holes 32 contacts the outer circumference of the refrigerant pipe 20 to support the refrigerant pipe 20. Each of the location holes 32 is formed in a shape corresponding to the outer circumference of the refrigerant pipe 20 to surround the refrigerant pipe 20.
As shown in
The protrusion 70 protrudes frontward from the plate 40.
The protrusion 70 includes first inclined surfaces 72 disposed at a predetermined angle relative to the plate 40. The first inclined surfaces 72 are disposed on the plate 40 in a symmetrical fashion to form a ‘V’ shape.
The first inclined surfaces 72 guide air, passing through the slits 50, to the louver unit 60. That is, air, accelerated while passing through the slits 50, naturally flows along the first inclined surfaces 72 so that speed of the air is not reduced. The air flowing along the first inclined surfaces 72 contacts the louver unit 60 to perform heat exchange with the refrigerant flowing in the refrigerant pipe 20, thereby increasing heat transfer efficiency.
As previously described, the first inclined surfaces 72 are disposed on the plate 40 in a symmetrical fashion to form a ‘V’ shape. A contact line 74 is formed vertically at a position where the first inclined surfaces 72 join each other. The distance between the contact line 74 and the plate 40 constitutes a height H of the protrusion 70.
If the height H of the protrusion 70 is increased, the area of the first inclined surfaces 72 increases, thereby increasing the contact area between the first inclined surfaces 72 and external air. If the height H of the protrusion 70 is excessively increased, however, the first inclined surfaces 72 act as resistance to external air. As a result, the speed of air is reduced and pressure of the air is reduced (pressure loss), thereby reducing heat transfer efficiency. The height H of the protrusion 70 is 0.5 mm to 4.0 mm.
Meanwhile, the first inclined surfaces 72 may be disposed on the plate in a non-symmetrical fashion, which will be described in detail below in connection with a heat exchanger fin 300 according to another embodiment of the present disclosure.
The slits 50 are disposed at opposite sides of the protrusion 70.
The slits 50 prevent moisture contained in external air from being attached to the surface of the heat exchanger fin 30. Also, the slits accelerate external air introduced to the heat exchanger 10 and guide the external air to the protrusion 70 and the louver unit 60. Each of the slits 50 includes second inclined surfaces 52 inclined relative to the plate 40, a top surface 54 provided between the second inclined surfaces 52, and a second cutout 56 provided at the rear of the top surface 54.
The second inclined surfaces 52 protrude from the plate 40 so that the second inclined surfaces 52 are disposed at a predetermined angle relative to the plate 40 to define a space, in which external air flows, between the plate 40 and the top surface 54.
The top surface 54 is formed in an approximately trapezoidal shape. The top surface 54 is disposed between the second inclined surfaces 52. Air, passing through each of the slits 50, is divided by the top surface 54 and flows along the front and rear of the top surface 54, resulting in turbulent flow. As a result, the air is further accelerated.
The top surface 54 may be formed in other shapes. For example, the top surface 54 may be formed in the shape of a triangle, a semicircle, an arc or a quadrangle. Even if the top surface 54 is formed in any one of the above-specified shapes, the same effect in that air, passing through each of the slits 50, is divided by the top surface 54 is achieved.
An edge 58 is formed between top surface 54 and each of the second inclined surfaces 52. The edge 58 prevents frost formation. Frost formation is a phenomenon in which moisture contained in external air is attached to the surface of the heat exchanger fin 30 in a frozen state. Frost is formed at a flat surface on which more than a predetermined amount of moisture is easily collected. More than a predetermined amount of moisture is prevented from being collected by the provision of the edge 58, thereby preventing or retarding frost formation.
The second cutout 56 is provided at the rear of the top surface 54 to guide external air, introduced to the heat exchanger 10, to the louver unit 60 and to minimize resistance applied to the air flowing along the top surface 54.
When the heat exchanger 10 is used as an evaporator to heat a room, the refrigerant, flowing in the refrigerant pipe 20, is expanded from a liquid state to a gas state to absorb heat from the surroundings. As a result, the surface temperature of the refrigerant pipe 20 is generally lowered to below zero degrees Celsius. The second cutout 56 retards heat exchange between the refrigerant pipe 20 and the corresponding slit 50, thereby preventing frost formation.
The width D of the top surface 54 may be 0.5 to 5.0 mm in consideration of resistance applied to air passing through the corresponding slit 50.
The slits 50 are disposed at opposite sides of the protrusion 70. At least two slits 50 may be disposed in the vertical direction of the plate 40 so that the slits 50 are spaced apart from each other.
When the slits are disposed in the vertical direction of the plate 40 so that the slits 50 are spaced apart from each other, the strength of the slits 50 and the plate 40 is higher than when the slits are disposed without separation.
The louver unit 60 is provided at the protrusion 70.
The louver unit 60 includes guide plates 62 provided at the first inclined surfaces 72 and first cutout 64 alternating with the guide plates 62.
The guide plates 62 are disposed at a predetermined angle relative to the first inclined surfaces 72. The guide plates 62 are arranged in parallel to each other so that the guide plates 62 are spaced apart from each other.
External air, accelerated after having passed through the slits 50, flows along the first inclined surfaces 72 and contacts the guide plates 62 to perform heat exchange with the guide plates 62. The guide plates 62 increase contact area between the heat exchanger fin 30 and external air to increase heat exchange efficiency.
When the pitch (width) P of each of the guide plates 62 is small or when the inclination angle a between each of the guide plates 62 and the first inclined angle 72 is small, contact area between the heat exchanger fin 30 and external air increases. If the pitch P is too small or the inclination angle a is too large, however, speed of air passing through the louver unit 60 is reduced by the guide plates 62, resulting in pressure loss. As a result, overall heat exchange efficiency is lowered. Consequently, the pitch P and the inclination angle a are properly adjusted. For example, the pitch P may be 0.5 mm to 3.0 mm and the inclination angle a may be 10 degrees to 60 degrees.
Also, the edge of each of the guide plates 62 prevents or retards frost formation, as previously described.
The first cutouts 64 are provided at the first inclined surfaces 72 so that the first cutouts 64 and the guide plates 62 are alternately disposed. The first cutouts 64 guide external air, accelerated after having passed through the slits 50, to flow along one side of each of the guide plates 62, thereby effectively achieving heat transfer between the guide plates 62 and external air.
As shown in
The air, accelerated by the slits 50, flows to the louver unit 60 without reduction of air speed. As previously described, the slits 50 accelerate air introduced into the slits 50 and guide the introduced air to the louver unit 60.
The air flows on the surfaces of the guide plates 62 and between the guide plates 62, i.e. at the first cutouts 64, at high speed to perform heat exchange with the guide plates 62.
As shown in
In the table of
As the result of a comparison of heat transfer efficiency between the conventional fins and the inventive fins having the same pitch (1.5 mm), the inventive fins have approximately 7.4% to 8.2% higher heat transfer efficiency in all wind speed sections than the conventional fins.
Also, even when the pitch of the inventive fins is increased from 1.5 mm to 1.7 mm, the inventive fins have higher heat transfer efficiency than the conventional fins having a pitch of 1.5 mm. This means that higher heat transfer efficiency is achieved using a smaller number of inventive fins, thereby reducing material costs.
An inclination angle β between the first inclined surface 372a and the front of a plate 40 is larger than an inclination angle β′ between the first inclined surface 372b and the front of the plate 40. Consequently, the area of the first inclined surface 372a is smaller than that of the first inclined surface 372b. Also, a contact line 374 at which the first inclined surfaces 372a and 372b join each other deviates from the middle of the plate 40.
That is, the guide plates 462 may be provided at first inclined surfaces 72 so that the guide plates 462 are at different inclination angles relative to the first inclined surfaces 72.
In this case, the slits 50 are disposed at an external air introduction side.
The flat surface 676 is provided between first inclined surfaces 672. The first inclined surfaces 672 may be symmetric with respect to the flat surface 676. The distance between the flat surface 676 and a plate 40 constitutes the height of the protrusion 670. The height of the protrusion 670 is 0.5 mm to 4.0 mm.
Guide plates 62 may be selectively provided at the first inclined surfaces 672 or the flat surface 676. Alternatively, the guide plates 62 may be provided at both the first inclined surfaces 672 and the flat surface 676.
At least two of the previous embodiments may be combined. For example, when the embodiment of
As is apparent from the above description, heat exchange between air and the heat exchanger fins of the embodiments of the present disclosure is effectively achieved, thereby improving heat exchange efficiency.
Also, frost formation is restrained on the surfaces of the heat exchanger fins, thereby improving heat exchange efficiency.
Although a few embodiments of the present disclosure have been shown and described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.
Number | Date | Country | Kind |
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10-2010-0106371 | Oct 2010 | KR | national |