JP2012052732A - Heat exchanger and air conditioning device for vehicle including the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat exchanger of small air pressure loss and large heat exchange rate.SOLUTION: The heat exchanger includes flat tubes having a plurality of refrigerant circulation holes inside thereof, and fins fixed to flat faces of the flat tubes, and the flat tubes and the fins are alternately stacked. (W-t1-t2)×Hp×Hf/N is 3.95-10.0, when an equivalent diameter of the plurality of refrigerant circulation holes is de, a width of the flat tube is W, a thickness at one end side corresponding to a distance between one end in the width direction of the flat tube and the refrigerant circulation hole closest thereto is t1, a thickness at the other end side corresponding to a distance between the other end in the width direction of the flat tube and the refrigerant circulation hole closest thereto is t2, a height in the stacking direction of the flat tube is Hp, a height in the stacking direction of the fin is Hf, and the number of refrigerant circulation holes is N, and further the equivalent diameter de is 0.5-0.8, and the width W of the flat tube is 12-16 mm.

Description

  The present invention relates to a heat exchanger and a vehicle air conditioner including the heat exchanger.

The vehicle air conditioner is provided with a condenser (heat exchanger) that condenses the refrigerant by heat exchange with air. As the condenser, a typical multi-flow type is often used in which flat tubes and corrugated fins are alternately stacked. A plurality of coolant circulation holes are formed inside the flat tube, and each convex portion of the corrugated fin is fixed to the flat surface of the flat tube so that air passes over the surface of the corrugated fin.
In order to improve the performance of this type of condenser, it is conceivable to close the fin pitch or to make the coolant circulation hole formed in the flat tube fine.
However, if the fin pitch is reduced, the pressure loss of the passing air increases, and the motor input of the CRFM (Condenser-Radiator Fan Module) increases. Further, when the refrigerant circulation hole is made fine, the refrigerant pressure loss increases, and the power of the compressor that compresses the refrigerant is increased.

  Patent Document 1 listed below discloses a multi-flow type refrigerant condenser aiming at obtaining the maximum heat radiation performance in consideration of both the ventilation resistance and the pressure loss in the pipe. Specifically, in Patent Document 1, the stacking direction height Th of the tubes, the stacking direction height Tr of the refrigerant passage in the tube, the tube outer peripheral wall thickness Td between the tube outer surface and the refrigerant passage, the flat tube stacking Using the direction pitch Tp as a parameter, the shape of the heat exchanger is defined by the relationship between the ventilation opening ratio Pr (= Th / Tp) and the tube outer peripheral thickness Td.

Japanese Patent No. 3922288 (Claim 1 etc.)

  However, in patent document 1, the dimension of the air flow direction (tube width direction) of the refrigerant condenser is not considered at all. That is, no strict examination has been made on changes in the state quantity caused by air passing through the fins (for example, air ventilation resistance and heat exchange in the air flow direction). Therefore, in the specification of the shape of the refrigerant condenser described in the document, the performance of the heat exchanger depending on the ventilation resistance cannot be strictly evaluated.

  This invention is made | formed in view of such a situation, Comprising: Air pressure loss (ventilation resistance) is small, and provides a heat exchanger with large heat exchange amount, and a vehicle air conditioner provided with the same. Objective.

In order to solve the above problems, the heat exchanger of the present invention and the vehicle air conditioner including the heat exchanger employ the following means.
That is, a heat exchanger according to the present invention includes a flat tube having a plurality of refrigerant flow holes formed therein, and a fin that is fixed to the flat surface of the flat tube and through which air passes. In the heat exchanger formed by alternately laminating the flat tubes and the fins, the equivalent diameter of the plurality of refrigerant circulation holes is de, the width of the flat tubes is W, and one end in the width direction of the flat tubes The wall thickness at one end corresponding to the distance from the nearest refrigerant circulation hole is t1, the wall thickness at the other end corresponding to the distance between the other end in the width direction of the flat tube and the refrigerant circulation hole closest to the other. The height of the flat tubes in the stacking direction is Hp, the height of the fins in the stacking direction is Hf, the number of the refrigerant circulation holes is N, and the equivalent diameter de is 0.5 to 0.8, and the flat tube width W is 12mm or more If it is a 6mm or less, (W-t1-t2) × Hp × Hf / N, characterized in that there is a 3.95 to 10.0.

As shown in the above polynomial, a polynomial using the flat tube width W was used when evaluating the heat exchange performance of the heat exchanger. Thereby, the state change (for example, the ventilation resistance of air and the heat exchange of an air flow direction) by the air which passes a fin can also be considered, and heat exchange performance can be reflected more strictly.
Further, the shape of the heat exchanger is determined in consideration of not only the shape of the flat tube such as the flat tube width W and the flat tube height Hp but also the fin height Hf. Thereby, a pneumatic loss can be considered more strictly.
By using a polynomial divided by the number N of refrigerant circulation holes, the performance per refrigerant circulation hole can be evaluated.
It has been found that a heat exchanger having a small air pressure loss and a large amount of heat exchange can be realized by using the polynomial as described above and setting the value between 3.95 and 10.0.
The flat tube is preferably manufactured by extrusion.

  Furthermore, it is preferable that the equivalent diameter de is 0.55 or more and 0.76 or less.

  By setting the equivalent diameter de to 0.55 or more and 0.76 or less, the air pressure loss can be further reduced and the heat exchange amount can be increased.

  Furthermore, it is preferable that the said fin is made into the corrugated shape and the pitch shall be 1.6 mm or more and 2.0 mm or less.

  By setting the fin pitch to 1.6 mm or more and 2.0 mm or less, the air pressure loss can be further reduced and the heat exchange amount can be increased.

  Moreover, the vehicle air conditioner of the present invention includes any one of the above heat exchangers.

  By providing the above-described heat exchanger, it is possible to provide a vehicle air conditioner having high performance. The heat exchanger of the present invention is preferably used as a condenser for a vehicle air conditioner.

  ADVANTAGE OF THE INVENTION According to this invention, an air pressure loss is small and the amount of heat exchange can provide a heat exchanger and a vehicle air conditioner provided with the same.

It is the front view which showed the condenser of the vehicle air conditioner which is one Embodiment of this invention. It is a cross-sectional view of the flat tube of FIG. It is the front view which showed the corrugated fin of FIG. It is the graph which showed the simulation result of the condenser shown in FIG. 1 about the polynomial. It is the graph which showed the simulation result of the condenser shown in FIG. 1 about the equivalent diameter.

Embodiments according to the present invention will be described below with reference to the drawings.
FIG. 1 shows a front view of a condenser (heat exchanger) 1 according to the present embodiment. The condenser 1 cools and condenses the high-temperature and high-pressure superheated gas refrigerant discharged from the compressor (not shown) in the refrigeration cycle of the vehicle air conditioner. Moreover, the condenser 1 is arrange | positioned in the forefront part in a vehicle engine room as one component of CRFM (Condenser-Radiator Fan Module). Behind the condenser 1, an engine cooling radiator (not shown) and a cooling fan (not shown) are arranged in this order. The condenser 1 is cooled by cooling air (outside air) blown by a cooling fan.

  The condenser 1 includes a pair of a first header tank 11 and a second header tank 12 that are arranged at a predetermined interval. These header tanks 11 and 12 are formed in a cylindrical shape, and are arranged in a state where the longitudinal direction thereof is substantially in the vertical direction. Between these header tanks 11 and 12, a core portion 13 for exchanging heat between air and refrigerant is disposed.

  The condenser 1 is a multi-flow type in which the refrigerant flows through a plurality of parallel flow paths provided between the header tanks 11 and 12. The core portion 13 includes a flat tube 14 extending horizontally between the header tanks 11 and 12 and a corrugated fin 15 fixed to the flat surface of the flat tube 14. The flat tube 14 and the corrugated fin 15 are alternately stacked in the vertical direction, whereby the core portion 13 is formed.

FIG. 2 shows a cross section of the flat tube 14. As shown in the figure, a plurality of independent refrigerant flow holes 20 are formed in the longitudinal direction inside the flat tube 14. The flat tube 14 having the plurality of refrigerant flow holes 20 can be manufactured by extruding a material made of an aluminum alloy.
One end of the flat tube 14 in the longitudinal direction is connected to the first header tank 11, and the other end is connected to the second header tank 12. As a result, the refrigerant flows between the header tanks 11 and 12 through the plurality of refrigerant flow holes 20.

FIG. 3 shows a front view of the corrugated fin 15. As shown in the figure, the corrugated fin 15 has a wave shape. The corrugated fin 15 can be manufactured by pressing a plate material made of an aluminum alloy. The peaks 15 a and valleys 15 b of the corrugated fins 15 are joined to the flat surface of the flat tube 14 by brazing. Air flows on the surface of the corrugated fins 15 and heat exchange between the air and the refrigerant is promoted.
As shown in FIG. 3, the height of the corrugated fins 15 is Hf, and the fin pitch is Pf.

  As shown in FIG. 1, the inside of the first header tank 11 is divided into two chambers 17 and 18 by a separator 16, and the gas refrigerant from the compressor is introduced into the upper first chamber 17. . The gas refrigerant flows into the second header tank 12 via the upper flat tube 14 communicating with the first chamber 17, makes a U-turn in the second header tank 12, and then flattenes the remaining portion located below. It flows into the second chamber 18 below through the tube 14. The gas refrigerant is cooled by exchanging heat with air passing through the space between the flat tubes 14 and condensed, and the refrigerant becomes a gas-liquid two-phase flow in the refrigerant flow holes 20 of the flat tubes 14 as the refrigerant condenses. .

Next, the result of examining the heat exchange performance of the condenser 1 having the above-described configuration through simulation by numerical calculation will be described.
In this embodiment, Q / Fa / ΔPa corresponding to the heat exchange amount Q [W] with respect to the front area Fa [m ² ] and the air pressure loss ΔPa [Pa] is adopted as an index of the heat exchange performance. By adopting this heat exchange performance index, the pressure loss of the air passing through the condenser 1 (specifically, the corrugated fins 15) is taken into consideration. That is, the larger the heat exchange amount Q and the smaller the air pressure loss ΔPa, the larger the value.

The heat exchange amount Q and the air pressure loss ΔPa were determined by the following relational expression.
ΔPa = A × Pf ^ B
Q = C × exp (−D × Pf)
Here, Pf is the fin pitch (see FIG. 3), and A, B, C, and D are constants.

  In the simulation, the pressure loss of the refrigerant flowing through the refrigerant passage hole 20 of the flat tube 14 is also taken into consideration. Specifically, the refrigerant pressure loss is calculated based on the pipe friction coefficient of the refrigerant flow hole 20, the physical properties of the gas refrigerant and the liquid refrigerant, and the like. When the refrigerant pressure loss is large, the change in state quantity of the refrigerant p (pressure)-h (enthalpy) diagram during heat exchange (during refrigerant condensation) changes from ideal horizontal (ie, constant pressure and constant temperature) to the left. The refrigerant moves down and the average temperature CTm of the refrigerant at the time of condensation decreases. When the average temperature CTm decreases, the heat exchange amount Q proportional to the difference (CTm−Tai) between the average temperature CTm and the air temperature Tai decreases. Therefore, the lower the refrigerant pressure loss, the larger the heat exchange amount Q, and the above heat exchange performance index takes a larger value.

In the simulation, the following conditions were used.
Inlet air temperature Tai = 35 ° C
Inlet refrigerant pressure Pri = 1.744 MPa
Front wind speed of air Fvi = 4.5m / s
Refrigerant inlet superheat degree SH = 20K
Refrigerant outlet supercooling degree SC = 10K
Fin pitch Pf = 1.6 mm to 2.0 mm

The following polynomial was used as a parameter for defining the shape of the condenser 1.
(W−t1−t2) × Hp × Hf / N
As shown in FIG. 2, the variables of the polynomial are as follows.
W; width t1 of the flat tube 14; one end side wall thickness t2 corresponding to the distance between the one end (left end in FIG. 2) in the width direction of the flat tube 14 and the closest refrigerant flow hole 20; other in the width direction of the flat tube 14 Thickness Hp on the other end side corresponding to the distance between the end (right end in FIG. 3) and the nearest refrigerant circulation hole 20 Hp: stacking direction (vertical direction) height of flat tube 14 Hf: stacking direction (vertical direction) of corrugated fin 15 ) Height N: Number of refrigerant circulation holes 20

In the above polynomial, the one end side wall thickness t1 and the other end side wall thickness t2 are subtracted from the flat tube width W because heat exchange is not substantially performed in the range of these wall thicknesses t2 and t2. is there.
The reason why the stacking direction height Hp of the flat tube 14 and the stacking direction height Hf of the corrugated fin 15 are made into a product form together with the flat tube width W is that these parameters are proportional to the heat exchange amount.
The reason for dividing by the number N of refrigerant circulation holes is to evaluate the performance per one refrigerant circulation hole 20.

FIG. 4 shows the simulation result. In the figure, the vertical axis represents the heat exchange performance index Q / Fa / ΔPa described above, and the horizontal axis represents a polynomial (W−t1−t2) × Hp × Hf / N.
In the same figure, the cases where the flat tube width is 12 mm, 14 mm, 15 mm and 16 mm are shown. As can be seen from the figure, when the polynomial is 3.95 or more and 10 or less, the maximum points of all the curves are included. Therefore, if the polynomial is selected to be 3.95 or more and 10 or less, a high-performance condenser 1 can be obtained.

As a comparison with FIG. 4, the polynomial of the present embodiment was calculated for the condenser specified in Patent Document 1. The specifications of the condenser of Patent Document 1 include the values described in [0021] (tube height th = 1.7 mm, fin height Fh = 7.8 mm, tube outer wall thickness Td = 0.35 mm) and The number (14) of refrigerant circulation holes that can be read from FIG.
The diameter of the coolant circulation hole is 1 mm (= 1.7-2 × 0.35).
Since the flat tube width W is not defined in Patent Document 1, 16 mm is used as a provisional numerical value so that it can be compared with the present embodiment. The one-end-side wall thickness t1 and the other-end-side wall thickness t2 are 0.133 mm, respectively, calculated from the flat tube width of 16 mm, the 14 refrigerant circulation holes, and the refrigerant circulation hole diameter of 1 mm. The polynomial values obtained from the above numerical values are as follows.
(W−t1−t2) × Hp × Hf / N
= (16-0.133-0.133) x 1.7 x 7.8 / 14
= 14.9
Thus, it can be seen that the condenser disclosed in Patent Document 1 is outside the range of 3.95 or more and 10 or less, which is the range of the polynomial defined in the present embodiment.

FIG. 5 shows the simulation result. In the figure, the vertical axis represents the heat exchange performance index Q / Fa / ΔPa described above, and the horizontal axis represents the equivalent diameter de of the plurality of refrigerant flow holes 20 formed in the flat tube 14. Here, the equivalent diameter de means a diameter when a plurality of refrigerant flow holes 20 formed in one flat tube 14 are converted into one equivalent circular pipe.
In the same figure, the cases where the flat tube width is 12 mm, 14 mm, 15 mm and 16 mm are shown. As can be seen from the figure, when the equivalent diameter de is 0.5 or more and 0.8 or less, preferably 0.55 or more and 0.76, the maximum points of all curves are included. Therefore, if the equivalent diameter de is selected as described above, a high-performance condenser 1 can be obtained.

According to this embodiment, there exist the following effects.
When evaluating the heat exchange performance of the condenser 1, a polynomial using the flat tube width W was used. Thereby, the state change (for example, the ventilation resistance of air and the heat exchange of an air flow direction) by the air which passes the corrugated fin 15 can also be considered, and heat exchange performance can be reflected more strictly.
The shape of the heat exchanger is determined in consideration of not only the shape of the flat tube such as the flat tube width W and the flat tube height Hp but also the fin height Hf. Thereby, a pneumatic loss can be considered more strictly.
By using a polynomial divided by the number N of refrigerant circulation holes, the performance per refrigerant circulation hole can be evaluated.

The heat exchange amount Q with respect to the front area Fa and air pressure loss ΔPa was used as a heat exchange performance index, and the above polynomial was used for evaluation. Thus, by evaluating the heat exchange amount Q divided by the air pressure loss ΔPa, the air pressure loss was sufficiently taken into consideration. Thereby, the performance close to the actual use state can be evaluated.
Further, since the heat exchange amount Q is calculated by considering the refrigerant pressure loss in the simulation, the performance closer to the actual use state can be evaluated.

  The above polynomial is evaluated as a parameter, and when the value of the polynomial is 3.95 or more and 10.0 or less, the above heat exchange performance index is large (the air pressure loss is small and the heat exchange amount is large). It was. Thus, by defining the shape of the high-performance condenser with a polynomial, a high-performance condenser can be obtained with good reproducibility.

1 Condenser (heat exchanger)
13 Core part 14 Flat tube 15 Corrugated fin W Flat tube width t1 One end side wall thickness t2 Other end side wall thickness Hp Flat tube stacking height Hf Corrugated fin stacking height Pf Corrugated fin fin pitch N Refrigerant flow hole Number of

Claims (4)

A flat tube having a plurality of refrigerant flow holes formed therein, and a fin that is fixed to the flat surface of the flat tube and through which air passes,
In the heat exchanger formed by alternately laminating the flat tubes and the fins,
The equivalent diameter of the plurality of refrigerant flow holes is de, the width of the flat tube is W, the thickness on one end side corresponding to the distance between one end in the width direction of the flat tube and the nearest refrigerant flow hole is t1, the flat The thickness on the other end side corresponding to the distance between the other end in the width direction of the tube and the nearest refrigerant flow hole is t2, the height in the stacking direction of the flat tube is Hp, the height in the stacking direction of the fin is Hf The number of refrigerant circulation holes is N, and
When the equivalent diameter de is 0.5 to 0.8 and the flat tube width W is 12 mm to 16 mm,
(W-t1-t2) * Hp * Hf / N is 3.95 or more and 10.0 or less, The heat exchanger characterized by the above-mentioned.   The heat exchanger according to claim 1, wherein the equivalent diameter de is 0.55 or more and 0.76 or less.   The heat exchanger according to claim 1 or 2, wherein the fin has a corrugated shape, and a pitch thereof is 1.6 mm or more and 2.0 mm or less.   A vehicle air conditioner comprising the heat exchanger according to any one of claims 1 to 3.

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