ITRM20070561A1 - HEAT EXCHANGER AND OUTDOOR UNIT WITH AIR CONDITIONER USING THE SAME. - Google Patents

Description

FIELD OF THE INVENTION

The present invention refers to a heat exchanger and to an outdoor unit of an air conditioner that uses the heat exchanger and, more particularly, refers to a heat exchanger in which the pressure loss of transfer tubes is reduced. of heat arranged in two rows in the direction of the air flow, and the width of the fins is optimized, and also refers to an outdoor unit of an air conditioner that uses the heat exchanger.

Related technique

Typically, in an air conditioner, taking cooling performance into consideration as an important issue, a refrigerant path is thus positioned in an outdoor unit heat exchanger at an opposite flow to the air flow at the instant of condensation. In this case, the refrigerant passing a localized heat transfer tube on the leeward side has a smaller specific volume when compared to a refrigerant passing a localized heat transfer tube on the leeward side, since it decreases the progression. condensation of the refrigerant and consequently, the loss of pressure. Thus, by reducing the diameter of the pipe on the windward side with respect to the diameter of the pipe located on the windward side, the performance of the heat transmission inside the pipe is greatly improved, as illustrated for example in the Japanese patent application exposed to the public No. . 11-257800 (Patent Publication 1) ·

However, in the heat exchanger mentioned in Patent Publication 1, the distance from the heat transfer tube towards the fin end increases as the diameter of the tube decreases, so that the difference in temperature between the end part of the fin fin and the surface of the heat transfer tube becomes large, thereby deteriorating the efficiency of the fin.

SUMMARY OF THE INVENTION

The present invention has been designed in consideration of the circumstances encountered in the above-mentioned prior art, and the purpose of the present invention is to provide a heat exchanger which can improve the heat transmission performance inside the tube by setting the outer diameter of the transfer tube. on the windward side so that it is smaller than the outer diameter of the heat transfer tube on the leeward side, and can prevent the fin output from decreasing even if the outer diameter of the heat transfer tube on the lee side windward decreases, thus ensuring a high heat transfer performance.

Another object of the present invention is to provide an outdoor unit of an air conditioner, which allows the amount of heat exchange to be increased, and provides improved radiation and condensation performance of the refrigerant.

The above and other objects can be achieved in accordance with the present invention by providing, in one aspect, a heat exchanger comprising: a plurality of heat transfer tubes arranged in two rows in the direction of the air flow; and a plurality of fins divided for each of the two rows of heat transfer tubes and arranged in parallel at a predetermined spacing so that heat exchange air flows along the spacing, wherein the relationship between the inner diameter D1 of the tube heat transfer pipe of the upwind side and the outer diameter D2 of the heat transfer pipe of the leeward side is set to 6 mm <Dl <D2 <10.5 mm, wherein the widths W1 and W2 of the fins are set so such that 0.9 <(Wl / Dl) / (W2 / D2) <1.11 where the width of the upwind side fin is W1 and the width of the leeward side fin is W2.

In this aspect, it may be desired that a refrigerant passage be set up such that a refrigerant flows from the upwind side heat transfer tube to the leeward side heat transfer tube when the heat exchanger acts as a condenser.

In another aspect of the present invention, an outdoor unit of an air conditioner is also provided, comprising: an outdoor unit body; a heat exchanger arranged in the body of the outdoor unit; a fan arranged in the body of the external unit and suitable for supplying air to the heat exchanger; and a compressor disposed in the body of the outdoor unit, wherein the heat exchanger includes a plurality of heat transfer tubes arranged in two rows in the direction of the air flow, and a plurality of fins divided for each of the two rows of the heat transfer and arranged in parallel at a predetermined spacing, such that heat exchange air flows along the spacing, wherein the relationship between the outer diameter Di of a windward side heat transfer tube and the outer diameter D2 of a leeward side heat transfer tube is set to 6 mm <Dl <D2 <10.5 mm, and where the fin widths W1 and W2 are set so that 0.9 <(Wl / Dl ) / (W2 / D2) <1.11 where the width of the windward side vane is W1 and the width of the leeward vane is W2.

According to the present invention, the heat exchanger can improve the heat transfer performance inside the heat transfer tube by decreasing the outer diameter of the heat transfer tube on the windward side relative to the outer diameter of the heat transfer tube on the leeward side and can also prevent the reduction of the fin efficiency even if the diameter of the heat transfer tube on the windward side is reduced so as to ensure a high heat transfer performance.

Also, according to the outdoor unit of the air conditioner, the heat exchange amount of the heat exchanger is increased so as to improve the performance of heat radiation and condensation of the refrigerant.

The nature and further characteristics of the present invention will be made more evident by the following descriptions made with reference to the annexed drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings:

Figure 1 is a schematic view of a heat exchanger according to an embodiment of the present invention;

Figures 2A-2D are diagrams showing a relationship between the ratio of the fin width and the amount of heat exchange;

Figure 3 is a schematic plan view of a section of an outdoor unit of an air conditioner according to an embodiment of the present invention;

Figure 4 is an illustration showing a condition of use of a heat exchanger according to an embodiment of the present invention; And

Figure 5 is a diagram showing a relationship between the fin temperature, the width ratio and the amount of heat exchange. DESCRIPTION OF THE PREFERRED EMBODIMENT

A heat exchanger according to an embodiment of the present invention will be described in detail hereinafter, with reference to the accompanying drawings.

As shown in Figure 1, a heat exchanger 1 of this embodiment is a fin tube type heat exchanger, and includes a windward side heat exchanger 1A, located on the windward side, and a heat exchanger 1B of the leeward side, located on the leeward side, however arranged separately in the vicinity of the heat exchanger 1A of the upwind side.

The windward side heat exchanger 1A includes small diameter heat transfer tubes 2 which are upwind side heat transfer tubes arranged in a single row in the direction of the air flow and a plurality of fins 3 of the windward side. small width are coupled to these small diameter heat cooling tubes 2 with a specified spacing to transfer heat, so that heat exchange air flows along these spacings.

The leeward side heat exchanger 1B includes large diameter heat transfer tubes 4 which are leeward side heat transfer tubes and arranged in a single row in the direction of the air flow and a multiplicity of fins 5 in width wide coupled to large diameter heat transfer tubes 4 with a specific spacing for transferring heat, so that heat exchange air flows along these spacings.

The outer diameter DI of the small diameter heat transfer tube 2 and the outer diameter D2 of the large diameter heat transfer tube 4 are set to establish the following relationship:

6 mm <Dl <D2 <10.5 mm.

The width W1 of the small width flap 3 and the width W2 of the large width flap 5 are set to establish the following relationship:

0.9 <(Wl / Dl) / (W2 / D2) <1.11.

When using a thin-width heat transfer tube on the windward side in the heat exchanger having such a structure, as regards a fin to be attached to this thin-width heat transfer tube, a small-wide fin 3 is used. Consequently, the fins on the windward side and the leeward side are formed with an optimum width relative to the outer diameter of the heat transfer tube, thereby optimizing the efficiency of the fin. Accordingly, the heat transfer performance of the heat exchanger can be improved when compared to a conventional heat exchanger having the same fin width on the windward side and the leeward side.

Figures 2A-2D show the relationship between the quantity Q of heat exchange, when the ratio between W1 and W2 is varied, and the value of (Wl / Dl) / (W2 / D2), when the ratio between W1 is varied. and W2, with the sum of the fin width W1, the small width fin 3 and the fin width W2, the large width fin 5 which is set to be constant.

In Figure 2A, when the value of (Wl / Dl) / (W2 / D2) is in the range from 0.9 to 1.11 where DI = 7 mm, D2 = 8 mm, W1 W2 = 36 mm, the amount of heat exchange Q is maximum, and the fin width ratio is optimized.

In Figure 2B, when the value of (Wl / Dl) / (W2 / D2) lies in the range from 0.9 to 1.11, where DI = 7 mm, D2 = 8 mm, W1 W2 = 46 mm, the amount of heat exchange is maximized, and the fin width ratio is optimized. In Figure 2C, when the value of (Wl / Dl) / (W2 / D2) lies in the range from 0.9 to 1.11, where DI = 7 mm, D2 = 8 mm, W1 W2 = 48 mm, the amount of heat exchange is maximum, and the width ratio of the fin is optimized.

In figure 2D, when the value of (Wl / Dl) / (W2 / D2) lies in the range from 0.9 to 1.11, where DI = 7 min, D2 = 8 mm, W1 W2 = 52 irai, the amount of color exchange is maximum and the flap width ratio is optimized.

As is evident from Figures 2A-2D, when the value of (Wl / Dl) / (W2 / D2) lies in the range from 0.9 to 1.1, regardless of the value of W1 + W2, the exchange quantity heat Q is maximum and the aspect ratio is optimized. If that value is outside the aforementioned range, the amount of heat exchange Q is extremely small.

Hereinafter, an example of use of the heat exchanger of the aforementioned embodiment will be described, in the use of an outdoor unit of an air conditioner.

According to the present invention, there is also provided an outdoor unit 11 of an air conditioner, as shown in Figure 3, which includes an outdoor unit body 12, including an intake port 12a, an exhaust port 12b and an inlet fitting. 12c, and this external unit body houses is a heat exchanger 1, such as an external heat exchanger, an electric fan 13 for supplying air to the heat exchanger, and a compressor 14 for compressing a refrigerant.

As shown in Figure 4, in the heat exchanger 1, a windward side heat exchange part 1A is arranged on the windward side, and a leeward side heat exchange part 1B is arranged on the leeward side.

That is, the small diameter heat transfer tube 2 and the small width fin 3 coupled to the small diameter heat transfer tube 2, in a heat transfer mode, are located on the windward side, while the tube Large diameter heat transfer 4 and large width fin 5 coupled to large diameter heat transfer tube 4, in a heat transfer manner, are located on the leeward side. In contrast with the air flow, the refrigerant flows from the large diameter heat transfer tube 4 on the leeward side to the heat transfer tube 3 on the windward side, so that the air flow and the flow of refrigerant constitute opposing flows.

The refrigerant compressed by the compressor 14 at a high temperature is branched from a branch duct 15, and flows into the large diameter heat transfer tubes 4 having end portions connected through a U-shaped connecting duct. The refrigerant is then cooled by heat radiation action of the large diameter heat transfer tube 4, and flows into the small diameter heat transfer tubes 2 through two passages. The refrigerant is cooled and liquefied by the heat radiation action of the small-wide fin 3, and sent to an internal unit through a converging duct 16 and then to an external expansion unit.

At this instant, T2> T1 is present, where the temperature of the small diameter heat transfer tube 2 is assumed to be Ti and the temperature of the large diameter heat transfer tube 4 is T2.

Figure 5 shows the relationship between the ratio between the fin width W1 of the small width fin 3 and the fin width W2 of the large width fin 5 and the amount Qt of heat exchange when the sum (W1 + W2 ) is constant, under conditions in which the relationship between the outer diameter DI of the small diameter heat transfer tube 2, which is the heat transfer tube of the upwind side, and the outer diameter D2 of the heat transfer tube 4 of large diameter heat, which is the lee side heat transfer tube, is 6 mm <DI <D2 <10.5 mm, and the relationship between the temperature TI of the small diameter heat transfer tube and the temperature Large diameter heat transfer T2 is TI = T2 (the air flow and the refrigerant flow do not form opposing flows), or TI <T2 (the air flow and the refrigerant flow constitute opposite flows).

In the case of TI = T2, if the fin width is any of the cases of W1 <W2, W1 = W2 and W1> W2, the amount of heat exchange T is substantially the same. On the other hand, in the case of T1 <T2, if the fin width is W1 <W2 the amount of heat exchange T is large. That is, in the case of Tl <T2, the temperature difference between the surface temperature of the small diameter heat transfer tube 2 on the windward side and the air flow temperature is smaller in the case of Tl = T2. Consequently, the amount of heat exchange of the whole heat exchanger can be set larger in the case of W1 <W2, so that the amount of heat exchange on the lee side is increased by relatively reducing the amount of heat exchange. warmth on the windward side.

In the outdoor unit of the air conditioner including the heat exchanger of the above-mentioned structures, the heat exchange amount of the heat exchanger is increased, thereby improving the performance of heat radiation and condensation of the refrigerant.

Meanwhile, the heat exchanger of the above-mentioned embodiment can be effectively applied to an indoor unit of the air conditioner.

Claims (3)

CLAIMS 1. Heat exchanger comprising: a plurality of heat transfer tubes arranged in two rows in the direction of the air flow; And a plurality of fins divided for each of the two rows of heat transfer tubes and arranged in parallel at a predetermined spacing, so that heat exchange air flows along the spacings, wherein the relationship between the outer diameter DI of the tube upwind side heat transfer tube and leeward side heat transfer tube OD are set to 6mm <ID <D2 <10.5mm, where the widths W1 and W2 of the fins are set so that 0.9 <(Wl / Dl) / (W2 / D2) <1.11, where the width of the windward side fin Wl, and the width leeward side fin is W2. The heat exchanger according to claim 1, wherein a refrigerant passage is positioned such that a refrigerant flows from the upwind side heat transfer tube to the leeward side heat transfer tube, when the exchanger of heat acts as a condenser. 3. Outdoor unit of an air conditioner, comprising: an external unit body; a heat exchanger arranged in the body of the outdoor unit; a fan arranged in the body of the external unit and adapted to supply air to the heat exchanger; And a compressor arranged in the body of an outdoor unit, wherein the heat exchanger includes a plurality of heat transfer tubes arranged in two rows in the direction of the air flow, and a plurality of fins divided for each of the two rows of the heat transfer tubes, and arranged in parallel to a predetermined spacing, such that heat exchange air flows along the spacing, wherein the relationship between the outer diameter DI of a windward side heat transfer tube and the outer diameter D2 of a heat transfer tube of the leeward side is set to 6 mm <DI <D2 <10,5 mild, and in which the widths W1 and W2 of the fins are set in such a way 0.9 <(Wl / Dl) / (W2 / W2) ≤ 1, 11, where the width of the windward side vane is W1 and the width of the leeward side vane is W2. p.p. Toshiba Carrier Corporation