Fin and micro-channel heat exchanger

Abstract

The present invention discloses a fin and a micro-channel heat exchanger. A retractable fin in a bending region of the micro-channel heat exchanger comprises a plurality of fin unit sections which are sequentially connected to form a corrugated structure, each fin unit section comprises a first straight section and an arc top section, and a retractable section which is deformed due to stretching/squeezing in a bending process of the micro-channel heat exchanger is provided between the first straight section and the arc top section. The retractable sections of the retractable fin are gradually straightened in the bending process of the micro-channel heat exchanger, included angles between the retractable sections and adjacent straight sections gradually become small, and this thereby ensures that the retractable fin in the bending region is not stretch-broken.

Claims

1. A fin used in a micro-channel heat exchanger comprising flat plate regions and a bending region which is bent between two adjacent flat plate regions, wherein the fin comprises a plurality of fin unit sections which are sequentially connected to form a corrugated structure, each fin unit section comprises a first straight section, an arc top section, a retractable section and a second straight section, the retractable section is provided between the first straight section and the arc top section, allowing to be stretched/squeezed in the process of bending the micro-channel heat exchanger, and the second straight section is provided between the arc top section and the retractable section, the fin unit section on an outer side of the bending region consists of the arc top section, the first straight section, the retractable section and the second straight section, and the fin unit section on the an inner side of the bending region consists of the arc top section and the first straight section.

2. The fin according to claim 1, wherein the retractable section is of an arc concave structure.

3. The fin according to claim 1, wherein along an extension direction of the fin, a minimum spacing between adjacent first straight sections is L, a maximum spacing between adjacent second straight sections is L1, and L is greater than L1.

4. The fin according to claim 1, wherein a length and an angle of the retractable section on the inner side of the bend are smaller than a length and an angle of the retractable section on the outer side of the bend.

5. The fin according to claim 4, wherein a width of the fin is greater than or equal to a width of a flat pipe.

6. The fin according to claim 4, wherein the first straight section is provided with a louver structure used for enhancing heat exchange.

7. A micro-channel heat exchanger, wherein the bending region is provided with the fin according to claim 1.

8. The micro-channel heat exchanger according to claim 7, wherein a fin provided in the flat plate region comprises straight sections and arc top sections which are connected with the straight sections, and the straight sections are provided with louver structures used for enhancing heat exchange.

Description

DESCRIPTION OF THE DRAWINGS

(1) The present invention will be further described below in combination with the drawings and the embodiments.

(2) FIG. 1 is an overall structural view of a micro-channel heat exchanger;

(3) FIG. 2 is a schematic view of fins in a flat plate region and arrangement;

(4) FIG. 3 is a partial view of fins and flat pipes in a flat plate region;

(5) FIG. 4 is a structural schematic view of a common fin;

(6) FIG. 5 is a schematic view of fins in a bending region and arrangement;

(7) FIG. 6 illustrates a partial view of fins and flat pipes in a bending region;

(8) FIG. 7 is a structural schematic view of a retractable fin;

(9) FIG. 8 is a comparison view of a retractable fin before and after bending;

(10) FIG. 9 is a structural view of a retractable fin in Embodiment 1; and

(11) FIG. 10 is a structural view of a retractable fin in Embodiment 2.

DESCRIPTION OF THE EMBODIMENTS

Embodiment 1

(12) as illustrated in FIG. 1, a micro-channel heat exchanger comprises header pipes 2, flat pipes 21 and fins, the flat pipes 21 are connected to the header pipes 2, the fins are installed between adjacent flat pipes, and end portions of the header pipes are connected with connecting pipes 22. The micro-channel heat exchanger is divided into a bending region 10 and flat plate regions 11 along a length direction of the header pipes 2, the bending region 10 is a region of the micro-channel heat exchanger for bending in a bending process, and the flat plate regions adopt common fins 110.

(13) In view of the fact that fins on an inner side of a bend are squeezed in a bending process of a traditional micro-channel heat exchanger, deformation such as inverted fins and distortion and the like occurs and the circulation of air is thereby obstructed; and that fins on an outer side of the bend are stretched and situations such as stretching deformation and even tearing and the like occur, the bending region 10 adopts specially designed retractable fins 100.

(14) Herein, the common fins 110 and the retractable fins 100 are all corrugated fins. Each of the common fins 110 and the retractable fins 100 comprises a plurality of fin unit sections which are sequentially connected to form a corrugated structure.

(15) As illustrated in FIG. 2 to FIG. 4, each common fin 110 provided in the flat plate region 11 comprises straight sections 111 and arc top sections 112 which are connected with the straight sections 111, and the straight sections 111 are provided with louver structures used for enhancing heat exchange.

(16) As illustrated in FIG. 5 to FIG. 7, in the retractable fins 100 provided in the bending region 10, the fin unit section comprises a first straight section 101 and an arc top section 104, and a retractable section 102 which is deformed due to stretching/squeezing in a bending process of the micro-channel heat exchanger is provided between the first straight section 101 and the arc top section 104. Further, a second straight section 103 between the arc top section and the retractable section is further provided.

(17) As illustrated in FIG. 8, in the structure of the retractable fin 100, a minimum spacing between adjacent first straight sections 101 is L, a maximum spacing between adjacent second straight sections 103 is L1, and as compared with an equal spacing of the common fin 110, the spacing L of the retractable fin 100 is far greater than the spacing L1. By comparing the retractable fin in the bending region before and after bending, when the micro-channel heat exchanger is bent, the bending region is stressed and bent from a flat plate state to a curved surface having a certain radian, at this moment an arc length of an outer side of the bending region is greater than an arc length of an inner side of the bending region, at this moment the outer side of the bending region is stressed and stretched, and the inner side of the bending region is squeezed. Consequently, the retractable fin at a position close to an outer side of the bend in the bending region is stretched and deformed, and the retractable fin at a position close to an inner side in the bending region is squeezed and deformed. Since transition between the first straight section 101 and the second straight section 103 of the retractable fin is realized through the retractable section 102, in the bending process of the micro-channel heat exchanger, the retractable sections of the retractable fin are gradually straightened, included angles between the retractable sections and the straight sections gradually become small, at this moment a difference between L1 and L continuously decreases, an arc top of the retractable fin close to the outer side of the bend is elongated a distance L2 after the bending of the micro-channel heat exchanger is completed, and this thereby ensures that the retractable fin in the bending region is not stretch-broken.

(18) Of course, as illustrated in FIG. 9, the structure of the second straight sections may not be provided, and only the retractable sections 102 are provided between the first straight sections 101 and the arc top sections 104.

(19) In addition, it needs to be noted that the length and angle of the retractable sections of the retractable fin 100 on the inner side of the bend and the outer side of the bend may be respectively different. The width of the retractable fin and the width of the flat pipe may be different. Preferably, the length and angle of the retractable section on the inner side of the bend are smaller than the length and angle of the retractable section on the outer side of the bend, because the retractable fin 100 on the outer side of the bend is a major deforming position. Besides, the width of the retractable fin 100 is greater than or equal to the width of the flat pipe 21.

Embodiment 2

(20) as illustrated in FIG. 10, an overall structure of a retractable fin 100 is divided into two parts, one part is an outer side of a bending region and the other part is an inner side of the bending region, wherein a fin unit section on the outer side of the bending region consists of three parts, i.e., an arc top section 104, a straight section 101 and a retractable section 102 between the arc top section 104 and the straight section 101, a fin unit section on the inner side of the bending region consists of two parts, i.e., the arc top section 104 and the straight section 101, and the straight section is provided with a louver structure used for enhancing heat exchange. The retractable section 102 is provided because the retractable fin 100 on the outer side of the bending region is a major deforming position.

(21) Moreover, a partition seam may be provided between the outer side of the bending region and the inner side of the bending region of the retractable fin 100, and seamless connection may also be adopted on the whole.