CN211527191U - Fin and heat exchanger - Google Patents

Abstract

The utility model relates to a heat transfer technical field, in particular to fin and heat exchanger. The fin comprises a plurality of channels which are sequentially arranged along the conveying direction of the medium, and the extending direction of the channels is intersected with the conveying direction of the medium; a plurality of gaps are arranged on the channel at intervals along the extending direction of the channel, a side plate is formed between every two adjacent gaps, and any one gap on one channel of at least two channels which are partially arranged adjacently is partially overlapped with the adjacent gap on the other channel in the conveying direction of the medium. The fin with the structure can improve the uniformity of a flow field, thereby reducing the fluid resistance.

Description

Fin and heat exchanger

Technical Field

The utility model relates to a heat transfer technical field, in particular to fin and heat exchanger.

Background

The fins can increase the heat exchange area of the heat exchanger, so that the heat exchange efficiency is improved. A fin in the related technology is formed by a plurality of channels with cross sections in a shape like a Chinese character 'ji', the extending direction of the channels is intersected with the conveying direction of a medium, a plurality of notches are arranged on the channels at intervals along the extending direction of the channels, a side plate is formed between every two adjacent notches, the notch on the previous channel is completely opposite to the side plate on the next channel along the conveying direction of the medium, and the uniformity of a flow field formed by the medium flowing in the fin of the structure is poor, so that the fluid resistance of the medium is large.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a fin and heat exchanger to the medium among the solution prior art technical problem that the fluid resistance is big in the fin.

The utility model provides a fin, which comprises a plurality of channels which are arranged in sequence along the conveying direction of a medium, wherein the extending direction of the channels is intersected with the conveying direction of the medium; a plurality of gaps are arranged on the channel at intervals along the extending direction of the channel, a side plate is formed between every two adjacent gaps, and any one gap on one channel of at least two channels which are arranged partially adjacently is partially overlapped with the adjacent gap on the other channel in the conveying direction of the medium.

Further, in the two channels which are arranged adjacently at random along the conveying direction of the medium, any one notch on one channel is partially overlapped with the adjacent notch on the other channel in the conveying direction of the medium.

Further, along the conveying direction of the medium, a superposed surface is formed between one notch on the previous channel and an adjacent notch on the next channel, and the sizes of the superposed surfaces are at least partially different.

Further, along the conveying direction of the medium, a superposed surface is formed between the notch on the previous channel and the adjacent notch on the next channel, and the sizes of the superposed surfaces are the same.

Further, the width of the overlapping surface is half of the width of the notch.

Furthermore, the gaps on the odd-numbered channels in the plurality of channels are uniformly and oppositely arranged in the medium conveying direction.

Furthermore, the notches on the channels arranged in the even order in the plurality of channels are uniformly and oppositely arranged in the medium conveying direction.

The utility model provides a heat exchanger, including above-mentioned fin.

The utility model provides a fin, which comprises a plurality of channels which are sequentially arranged along the conveying direction of a medium, wherein the extending direction of the channels is vertical to the conveying direction of the medium; a plurality of gaps are arranged on the channel at intervals along the extending direction of the channel, a side plate is formed between every two adjacent gaps, and at least one gap on one channel of the two channels which are at least partially arranged adjacently is partially overlapped with the adjacent gap on the other channel in the conveying direction of the medium.

For convenience of description, the notch on one channel is defined as a first notch, the notch on the other channel is defined as a second notch, the side plate formed between the two first notches is a first side plate, and the side plate formed between the two second notches is defined as a second side plate. The notch on one channel of two adjacent channels that set up partially coincides with the notch that another channel is adjacent, namely first notch and second notch partly face to setting up, another part dislocation set, the part that faces to setting up coincides in the direction that the medium was carried, and the part that misplaces to set up is just to setting up with the part of curb plate, that is to say along the direction of transport of medium, a part and the second notch coincidence of first notch, another part and the second curb plate coincidence of adjacent second notch.

Use the utility model provides an in-process of fin, the medium is carried to back passageway by preceding passageway, can flow by first breach, directly gets into back passageway after the position of first breach and second breach coincidence in, analogizes in proper order to flow complete individual fin. One part of the first notch is coincided with the second notch, so that the medium can smoothly flow, the resistance is reduced, the other part of the first notch is coincided with the second side plate, the second side plate can enable the medium to realize turbulent flow, the uniform dispersion of the medium flowing is ensured, the heat exchange efficiency is improved, and the fin of the structure can improve the uniformity of a flow field and reduce the fluid resistance.

Drawings

The accompanying drawings, which form a part hereof, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention without undue limitation. In the drawings:

fig. 1 is a schematic structural view of a fin according to an embodiment of the present invention;

fig. 2 is another structural schematic view of the fin shown in fig. 1.

In the figure: 10-channel; 20-notch; 30-side plate; 21-a first notch; 22-a second notch; 31-a first side panel; 32-second side panel.

Detailed Description

It should be noted that, in the present invention, the embodiments and features of the embodiments may be combined with each other without conflict. The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

As shown in fig. 1 and 2, the present invention provides a fin, which includes a plurality of channels 10 sequentially arranged along a conveying direction of a medium, wherein an extending direction of the channels 10 intersects with the conveying direction of the medium; a plurality of notches 20 are arranged at intervals along the extending direction of the channels 10, a side plate 30 is formed between two adjacent notches 20, and at least one notch 20 on one channel 10 of two channels 10 which are at least partially arranged adjacently is partially overlapped with the adjacent notch 20 on the other channel 10 in the conveying direction of the medium.

In the present embodiment, for convenience of description, the notch 20 of one channel 10 is defined as a first notch 21, the notch 20 of the other channel 10 is defined as a second notch 22, the side plate 30 formed between the two first notches 21 is defined as a first side plate 31, and the side plate 30 formed between the two second notches 22 is defined as a second side plate 32. The notch 20 on one channel 10 of the two adjacent channels 10 is partially overlapped with the other channel 10 towards the adjacent notch 20, that is, the first notch 21 is arranged opposite to one part of the adjacent second notch 22, the other part is arranged in a staggered way, the part arranged in the opposite way is overlapped in the medium conveying direction, the part arranged in the staggered way is arranged opposite to the part of the side plate 30, that is, along the medium conveying direction, one part of the first notch 21 is overlapped with the second notch 22 adjacent to the first notch, and the other part is overlapped with the second side plate 32 adjacent to the first notch.

It should be noted that the plurality of notches and the plurality of side plates on the channels are alternately arranged, and the first notch on the previous channel and the second notch and the second side plate (which are easy to understand, or as can be seen from fig. 1 and fig. 2, the second notch and the second side plate are adjacent) on the next channel are both partially arranged in an opposite way, that is, the first notch on the previous channel is located between the second notch and the second side plate on the next channel. Two second gaps can exist on the latter channel and are adjacent to the corresponding first gaps on the former channel, and any one of the two second gaps is opposite to the first gap.

In the process of using the fin provided by this embodiment, the medium is transported from the previous channel 10 to the next channel 10, and can flow out from the first notch 21, and directly enter the next channel 10 through the position where the first notch 21 and the second notch 22 coincide, and so on, thereby flowing a complete fin. One part of the first notch 21 is overlapped with the second notch 22, so that the medium flows smoothly and the resistance is small, the other part of the first notch 21 is overlapped with the second side plate 32, so that the second side plate 32 can enable the medium to realize turbulent flow, the heat exchange efficiency is improved, and the fin with the structure can improve the uniformity of a flow field on the whole, so that the fluid resistance is reduced.

It should be noted that the fins are capable of conveying and flowing the medium, and then the channels 10 and the notches 20 of the fins are communicated with each other. The structural form of the channel 10 can be various, and a plurality of channels 10 can be arranged at intervals, or can be arranged partially closely and partially at intervals. For example, as shown in the fin of fig. 1, three same channels are adjacently arranged, two of the three same channels are arranged without interval, and the middle channel 10 is arranged with interval with the third channel 10. The cross-section of each channel 10 is arranged in a zigzag shape.

It should be noted that, along the conveying direction of the medium, it is understood that the heat exchanger is necessarily provided with an inlet for the medium to enter, a channel for the medium to flow through, and an outlet for the medium to flow out, the medium needs to pass through the inlet, flow through the channel, and then flow out of the outlet, and the fins are installed in the channel to improve the heat exchange efficiency, and the medium needs to flow from one end of the pipe to the other end of the pipe in the channel to complete the circulation. It is possible that the direction of flow of the medium in the channels is not certain, but the direction of transport of the medium as a whole is determined in one channel from one end of the channel to the other in order to complete the circulation. Taking the orientation shown in fig. 1 and 2 as an example, the left-right direction is the direction of conveyance of the medium, and the up-down direction is the direction of extension of the channel.

Here, at least one notch 20 on one channel 10 of two channels 10 that are at least partially adjacently disposed partially overlaps with an adjacent notch 20 on the other channel 10 in the conveying direction of the medium, which means that two channels 10 that are adjacently disposed may be one, or a plurality of two channels 10 that are adjacently disposed may be two channels 10 that are adjacently disposed, three two channels 10 that are adjacently disposed, or the like.

As an alternative, in any two channels 10 adjacently disposed in the conveying direction of the medium, any one notch 20 on one channel 10 is partially overlapped with the adjacent notch 20 on the other channel 10 in the conveying direction of the medium.

In this embodiment, in all the channels 10, a part of any first notch 21 on the previous channel 10 is overlapped with the second notch 22 on the next channel 10, and the other part is overlapped with the second side plate 32, that is, the notches 20 on all the channels 10, and the notch 20 on the previous channel 10 and the notch 20 on the next channel 10 form a staggered tooth. Therefore, the flow field can be more uniform, and the fluid resistance can be reduced.

In addition to the above embodiments, further, a coincidence surface is formed between one notch 20 on the previous channel 10 and an adjacent notch 20 on the subsequent channel 10 in the conveying direction of the medium. That is, along the conveying direction of the medium, a portion where one first notch 21 on the previous channel 10 and one second notch 22 on the subsequent channel 10 coincide forms a coincidence plane, and if the plurality of channels 10 include a plurality of notches 20, the coincidence plane is also a plurality.

In this embodiment, the sizes of the multiple superposed surfaces may be all different, or some of the superposed surfaces may be the same, and another part may be different. The flow field can be set according to specific conditions, and the sizes of the superposed surfaces are different, so that the flow field can be set according to specific actual requirements, the uniformity of the flow field is better, and the fluid resistance is less.

And the sizes of the multiple superposed surfaces are the same, so that the flow field is uniform, the processing and the manufacturing are convenient, and the production cost is low.

On the basis of the above embodiment, further, the width of the notch 20 and the width of the side plate 30 may be different, and optionally, the width of the notch 20 and the width of the side plate 30 are the same, so that the processing and manufacturing of the fin are facilitated.

The width of the portions of the first notch 21 and the second notch 22 that overlap each other in the conveyance direction of the medium, that is, the width of the overlapping surface may be one-fourth, one-third, and so on of the notch 20.

Alternatively, as shown in fig. 1 and 2, the width of the overlapping surface is half of the width of the side plate 30, and this structure makes the structure of the fin regular and facilitates the manufacturing process.

As shown in fig. 1 and fig. 2, in addition to the above embodiment, further, the notches 20 of the channels 10 arranged in the odd number in sequence are uniformly and oppositely arranged in the medium conveying direction. In this embodiment, the odd-numbered channels 10 are identical in structure, and the notches 20 are arranged opposite to each other, so that the processing and manufacturing are facilitated.

As shown in fig. 1, in addition to the above embodiment, further, the notches 20 of the plurality of lanes 10, which are located on the even-numbered lanes 10, are aligned and directly face each other in the media conveying direction. In this embodiment, the odd-numbered channels 10 are identical in structure, and the notches 20 are arranged opposite to each other, thereby further facilitating the manufacturing process.

The utility model relates to a heat exchanger, including above-mentioned fin. The heat exchanger provided by the embodiment has the advantages that the uniformity of a flow field formed by flowing of a medium in the fins is good, the fluid resistance of the medium is low, the heat exchange efficiency of the heat exchanger provided by the embodiment is high, and the heat exchange performance is good.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Furthermore, those skilled in the art will appreciate that while some of the embodiments described above include some features included in other embodiments, rather than others, combinations of features of different embodiments are meant to be within the scope of the application and form different embodiments. For example, any of the claimed embodiments may be used in any combination. Additionally, the information disclosed in this background section is only for enhancement of understanding of the general background of the application and should not be taken as an acknowledgement or any form of suggestion that this information forms the prior art already known to a person skilled in the art.

Claims (8)

1. A fin comprises a plurality of channels which are sequentially arranged along the conveying direction of a medium, wherein the extending direction of the channels is intersected with the conveying direction of the medium; the side plate is characterized in that at least one notch on one channel of two adjacent channels is partially overlapped with the adjacent notch on the other channel in the conveying direction of the medium.

2. The fin according to claim 1, wherein, in two passages disposed adjacently at random in the conveying direction of the medium, any one of the notches in one of the passages is disposed partially overlapping with an adjacent one of the notches in the other of the passages in the conveying direction of the medium.

3. The fin of claim 2, wherein a coincident surface is formed between one of said notches in a preceding one of said channels and an adjacent one of said notches in a succeeding one of said channels in a direction of conveyance of the medium, the size of the plurality of said coincident surfaces being at least partially different.

4. The fin according to claim 2, wherein the gap in the previous channel and the adjacent gap in the subsequent channel form a coincidence surface in the conveying direction of the medium, and the coincidence surfaces are all the same in size.

5. The fin of claim 4, wherein the width of the coincident face is half the width of the notch.

6. The fin of claim 2, wherein the notches in an odd-numbered sequential row of the channels in a plurality of the channels are aligned in a media transport direction.

7. The fin of claim 2, wherein the notches in an even number of the channels in the plurality of channels are aligned in a media transport direction.

8. A heat exchanger, comprising: the fin of any one of claims 1 to 7.

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