CN208296664U - Pipe wing monomer and heat exchanger, air conditioner with it - Google Patents
Pipe wing monomer and heat exchanger, air conditioner with it Download PDFInfo
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- CN208296664U CN208296664U CN201820742519.0U CN201820742519U CN208296664U CN 208296664 U CN208296664 U CN 208296664U CN 201820742519 U CN201820742519 U CN 201820742519U CN 208296664 U CN208296664 U CN 208296664U
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Abstract
The utility model discloses a kind of pipe wing monomer and heat exchanger, air conditioner with it, the pipe wing monomer includes: multiple pipe wing ontologies, each pipe wing ontology includes being formed as the ontology of plate structure and setting on the body and along at least one channel part that the length direction of the ontology extends, the channel part and the ontology are one of the forming part, the thickness of the ontology is less than the thickness of the channel part, the runner of both ends open is limited in the channel part, multiple pipe wing ontologies are sequentially connected in the width direction of the ontology.Pipe wing monomer according to the present utility model enhances the heat transfer efficiency between channel part and ontology by the way that the part that is one of the forming is arranged in channel part and ontology.Moreover, can preferably meet practical application by being sequentially connected multiple pipe wing ontologies in the width direction of ontology.When pipe wing monomer applications are when heat exchanger, the heat exchange efficiency of heat exchanger can be improved.
Description
Technical field
The utility model relates to technical field of heat exchange, more particularly, to a kind of pipe wing monomer and heat exchanger, sky with it
Adjust device.
Background technique
In the related technology, the heat exchanger of volume production includes finned tube exchanger and micro-channel heat exchanger, finned tube exchanger
The flat tube of round tube or micro-channel heat exchanger is all made of the arrangement form of horizontal direction.Moreover, in order to obtain to leading on the outside of pipe
Heat area, the finless parts for expanding heat-conducting area use the arrangement of vertical direction.In addition, pipe and fin pass through tube expansion
Mode is combined together.
However, since caliber is larger, and using horizontal arrangement form, so that condensed water elimination is unsmooth, air side pressure
Loss is big.Moreover, because pipe and fin tube expansion be combined together, manage fin between thermal contact resistance it is larger, fin efficiency compared with
It is low.
Utility model content
The utility model aims to solve at least one of the technical problems existing in the prior art.For this purpose, the utility model mentions
A kind of pipe wing monomer out, the heat transfer efficiency between the channel part and ontology of the pipe wing monomer are high.
According to the pipe wing monomer of the utility model first aspect embodiment, comprising: multiple pipe wing ontologies, each pipe wing
Ontology includes being formed as the ontology of plate structure and setting on the body and extend at least along the length direction of the ontology
One channel part, the channel part and the ontology are one of the forming part, and the thickness of the ontology is less than the thickness of the channel part
Degree, limits the runner of both ends open in the channel part, multiple pipe wing ontologies in the width direction of the ontology according to
Secondary connection.
Increased according to the pipe wing monomer of the utility model embodiment by the way that the part that is one of the forming is arranged in channel part and ontology
Strong heat transfer efficiency between channel part and ontology.Moreover, by by multiple pipe wing ontologies in the width direction of ontology successively
Connection, can preferably meet practical application.When pipe wing monomer applications are when heat exchanger, the heat exchange that heat exchanger can be improved is imitated
Rate.
Some embodiments according to the present utility model are formed with the length direction extension along the ontology on the ontology
At least one strip seam.
Some embodiments according to the present utility model are formed with the thickness direction perforation along the ontology on the ontology
At least one first opening, first opening are equipped with connecting plate, and the both ends of the connecting plate are open with described first respectively
The two side walls on the length direction of the ontology be connected, and the connecting plate is upper in the thickness direction of the ontology
In the side of the ontology so that the side of the connecting plate is separated from each other with the corresponding wall surface of first opening to limit
The strip seam out.
Some embodiments according to the present utility model, the connecting plate include: the first plate section, the first plate section with it is described
The setting of ontology parallel interval;Two the second plate sections, one end of two the second plate sections both ends with the first plate section respectively
It is connected, two sides on the length direction of the ontology of the other end of two the second plate sections and first opening
Wall is connected.
Some embodiments according to the present utility model, the strip seam penetrate through described along the thickness direction of the ontology
Body.
Some embodiments according to the present utility model, strip seam be it is multiple, multiple strips are sewn on described
It is arranged in array on ontology.
Some embodiments according to the present utility model, the ontology are equipped with spaced multiple tilting structures, each
The tilting structure is located at the side on the thickness direction of the ontology.
Some embodiments according to the present utility model are formed with the thickness direction perforation along the ontology on the ontology
Multiple second openings, the plurality of tilting structure are respectively provided at multiple second openings, each tilting structure
One end and it is corresponding it is described second opening side wall be connected, it is each it is described tilt structure the other end with the ontology described
Setting is spaced on the thickness direction of ontology.
Some embodiments according to the present utility model, each tilting structure includes: the first tilting section, and described first sticks up
It plays section and is formed as slab construction, described first tilts section and ontology parallel interval setting;Second tilts section, and described second sticks up
The one end for playing section is connected with the first tilting section, and described second tilts the other end and the side wall phase of second opening of section
Even.
Some embodiments according to the present utility model, each second opening is rectangular aperture, each tilting knot
Described one end of structure is connected with a side wall of second opening, and the length of described described one end for tilting structure is less than institute
State the length of a side wall of the second opening.
The structure of some embodiments according to the present utility model, multiple pipe wing ontologies is all the same.
Some embodiments according to the present utility model, each pipe wing ontology have a channel part.
Some embodiments according to the present utility model, the channel part are straight along the length direction of the corresponding pipe wing ontology
Line and/or curve extend.
According to the heat exchanger of the utility model second aspect embodiment, comprising: multiple pipe wing monomers, each pipe wing list
Body is the pipe wing monomer according to the above-mentioned first aspect embodiment of the utility model, and multiple pipe wing monomers are along the pipe wing monomer
Thickness direction set gradually.
Some embodiments according to the present utility model are equidistantly arranged between the ontology of multiple pipe wing monomers.
According to the air conditioner of the utility model third aspect embodiment, comprising: shell;Heat exchanger, the heat exchanger are root
According to the heat exchanger of the above-mentioned second aspect embodiment of the utility model, the heat exchanger is located in the shell, the heat exchanger
The channel part is arranged along the vertical direction, and the angle between the surface and vertical plane of the ontology of the heat exchanger is α, wherein
The α meets: 0 °≤α≤60 °.
Some embodiments according to the present utility model, the heat exchanger are arranged vertically in the shell.
The additional aspect and advantage of the utility model will be set forth in part in the description, partially will be from following description
In become obvious, or recognized by the practice of the utility model.
Detailed description of the invention
The above-mentioned and/or additional aspect and advantage of the utility model from the description of the embodiment in conjunction with the following figures will
Become obvious and be readily appreciated that, in which:
Fig. 1 is the schematic diagram according to the pipe wing ontology of the utility model embodiment;
Fig. 2 is the schematic diagram according to the pipe wing ontology of the utility model another embodiment;
Fig. 3 is the schematic diagram according to the pipe wing monomer of the utility model embodiment;
Fig. 4 is the perspective view according to the heat exchanger of the utility model embodiment;
Fig. 5 is the main view of heat exchanger shown in Fig. 4;
Fig. 6 is the side view of heat exchanger shown in Fig. 4;
Fig. 7 is the top view of heat exchanger shown in Fig. 4;
Fig. 8 is the perspective view according to the heat exchanger of the utility model another embodiment;
Fig. 9 is the main view of heat exchanger shown in fig. 8;
Figure 10 is the side view of heat exchanger shown in fig. 8;
Figure 11 is the perspective view according to the heat exchanger of the utility model further embodiment;
Figure 12 is the main view of heat exchanger shown in Figure 11;
Figure 13 is the sectional view of the line A-A along Figure 12;
Figure 14 is the left view of heat exchanger shown in Figure 12;
Figure 15 is the right view of heat exchanger shown in Figure 12;
Figure 16 is the top view according to the heat exchanger of the utility model another embodiment;
Figure 17 is the partial schematic diagram of heat exchanger shown in Figure 16;
Figure 18 is the heat exchanger and traditional finned tube exchanger and micro-channel heat exchanger according to the utility model embodiment
Wind speed and heat output graph of relation;
Figure 19 is the heat exchanger and traditional finned tube exchanger and micro-channel heat exchanger according to the utility model embodiment
Wind speed and the air side coefficient of heat transfer graph of relation;
Figure 20 is the heat exchanger and traditional finned tube exchanger and micro-channel heat exchanger according to the utility model embodiment
Wind speed and air wide pre. drop graph of relation.
Appended drawing reference:
100: pipe wing monomer;
1: pipe wing ontology;11: ontology;
111: the first openings;112: connecting plate;1121: the first plate sections;1122: the second plate sections;
113: strip seam;114: the second openings;
115: tilting structure;Tilt section at 1151: the first;Tilt section at 1152: the second;
12: channel part;121: runner;
200: heat exchanger.
Specific embodiment
The embodiments of the present invention are described below in detail, examples of the embodiments are shown in the accompanying drawings, wherein from beginning
Same or similar element or element with the same or similar functions are indicated to same or similar label eventually.Below by ginseng
The embodiment for examining attached drawing description is exemplary, and is only used for explaining the utility model, and should not be understood as to the utility model
Limitation.
In the description of the present invention, it should be understood that term " center ", " longitudinal direction ", " transverse direction ", " length ", " width
Degree ", " thickness ", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom" "inner", "outside", " suitable
The orientation or positional relationship of the instructions such as hour hands ", " counterclockwise ", " axial direction ", " radial direction ", " circumferential direction " is orientation based on the figure
Or positional relationship, be merely for convenience of describing the present invention and simplifying the description, rather than the device of indication or suggestion meaning or
Element must have a particular orientation, be constructed and operated in a specific orientation, therefore should not be understood as the limit to the utility model
System.In addition, defining " first ", the feature of " second " can explicitly or implicitly include one or more of the features.
In the description of the present invention, unless otherwise indicated, the meaning of " plurality " is two or more.
In the description of the present invention, it should be noted that unless otherwise clearly defined and limited, term " is pacified
Dress ", " connected ", " connection " shall be understood in a broad sense, for example, it may be being fixedly connected, may be a detachable connection, or integrally
Connection;It can be mechanical connection, be also possible to be electrically connected;Can be directly connected, can also indirectly connected through an intermediary,
It can be the connection inside two elements.For the ordinary skill in the art, above-mentioned art can be understood with concrete condition
The concrete meaning of language in the present invention.
Below with reference to Fig. 1-Figure 20 description according to the pipe wing monomer 100 of the utility model embodiment.
As shown in Figure 1-Figure 3, according to the pipe wing monomer 100 of the utility model first aspect embodiment, including multiple pipe wings
Ontology 1.
Referring to Figures 1 and 2, each pipe wing ontology 1 include be formed as plate structure ontology 11 and be located on ontology 11 and
Along at least one channel part 12 that the length direction of ontology 11 extends.A channel part 12 is shown in Fig. 1, is shown in Fig. 2
Two channel parts 12 for illustration purposes, but those of ordinary skill after having read following technical solution, it is aobvious
It is so understood that be applied to the program in the technical solution of three or more channel parts 12, this also falls into the utility model
Protection scope within.
Channel part 12 and ontology 11 are one of the forming part.Wherein, the form with 11 one of ontology is set by channel part 12,
For example, channel part 12 can be manufactured with 11 overall processing of ontology, channel part 12 is a part of ontology 11 at this time.Certainly, may be used
First to process ontology 11, then channel part 12 is processed on ontology 11.
The runner 121 of both ends open is limited in channel part 12.For example, as shown in Figure 4-Figure 6, runner 121 can with it is logical
The extending direction in road portion 12 is identical, and the both ends of runner 121 extend through the both ends on the length direction of channel part 12 at this time, that is, flows
The both ends in road 121 extend through the both ends of the length direction along ontology 11 of channel part 12.When pipe wing ontology 1 is applied to heat exchanger
When 200, refrigerant can flow in the runner 121 of channel part 12.
As a result, setting channel part 12 to use tube expansion with traditional pipe and fin with by way of 11 one of ontology
Combined mode is compared, and the thermal contact resistance between channel part 12 and ontology 11 is small, so as to enhance channel part 12 with
The channel for flowing through heat exchanger 200 can be improved when pipe wing ontology 1 is applied to heat exchanger 200 in heat transfer efficiency between ontology 11
The heat exchange efficiency of the 11 outer air-flow such as air of ontology of refrigerant and heat exchanger 200 in the runner 121 in portion 12 etc. promotes heat exchange
Effect.Moreover, channel part 12 is not easy leakage of refrigerant, reliably by the way that the part that is one of the forming is arranged in channel part 12 and ontology 11
Property is more secure, and makes the manufacture of pipe wing ontology 1 simpler.
The thickness of ontology 11 is less than the thickness of channel part 12.For example, in the example of fig. 1 and 2, ontology 11 is in upper and lower
Upward thickness is less than thickness of the channel part 12 in the up and down direction of ontology 11, and channel part 12 can protrude ontology 11 at this time
An at least side surface on thickness direction.As a result, by the way that the thickness of ontology 11 is configured relatively thin, ontology can be further improved
11 heat transfer efficiency.Pipe wing ontology 1 according to the present utility model avoids wing it is to be understood that being arranged on fin (i.e. ontology 11)
The channel part 12 with runner 121 of piece low efficiency, high fin efficiency available in this way.
Multiple pipe wing ontologies 1 are sequentially connected in the width direction of ontology 11.For example, as shown in figure 3, by multiple pipe wing sheets
Body 1 is sequentially connected along the width direction of ontology 11, obtains pipe wing monomer 100.Multiple ontologies 11 of multiple pipe wing ontologies 1 can at this time
To be located in same level.Optionally, multiple pipe wing ontologies 1 can be attached using modes such as welding, bondings.But it is unlimited
In this.Pipe wing monomer 100 is constituted by using multiple pipe wing ontologies 1 as a result, since pipe wing ontology 1 can be produced in batches, is constituted
The particular number of the pipe wing ontology 1 of pipe wing monomer 100 can determine according to actual needs, so as to preferably meet reality
Using.
When being applied to heat exchanger 200 according to the pipe wing monomer 100 of the utility model embodiment,
According to the theory of thermal conduction study:
Q=KA0·ΔT
ho=(Ap+ η Af)/Ao×ha
Wherein, Q is heat exchange amount, and K is overall heat-transfer coefficient, hoFor the air side coefficient of heat transfer,
AoFor air side heat-conducting area, Δ T is temperature difference,
ApFor 12 heat-conducting area of channel part, ApiFor refrigerant side heat-conducting area, hwFor refrigerant side pyroconductivity, hcFor this
The contact conductivity of body 11 and channel part 12, AcoFor the contact area of ontology 11 and channel part 12, η is 11 efficiency of ontology, AfFor
11 heat-conducting area of ontology, haFor 11 partial air side conductivity of ontology.
When wind speed is higher, as shown in figure 18, according to the heat exchanger with pipe wing monomer 100 of the utility model embodiment
200 heat output is greater than the heat output of traditional micro-channel heat exchanger, and the heat output of traditional micro-channel heat exchanger is greater than tradition
Finned tube exchanger heat output;As shown in figure 19, according to the heat exchange with pipe wing monomer 100 of the utility model embodiment
The air side coefficient of heat transfer of device 200 is greater than the air side coefficient of heat transfer of traditional micro-channel heat exchanger, traditional Thermal Performance of Micro Channels
The air side coefficient of heat transfer of device is greater than the air side coefficient of heat transfer of traditional finned tube exchanger.It can be seen from the above, in same item
Under part, according to the heat output and the air side coefficient of heat transfer of the heat exchanger 200 with pipe wing monomer 100 of the utility model embodiment
It is greater than traditional micro-channel heat exchanger and finned tube exchanger, shows that pipe wing monomer is had according to the utility model embodiment
100 heat exchanger 200 has more excellent exchange capability of heat.
As shown in figure 20, according to the air side pressure of the heat exchanger 200 with pipe wing monomer 100 of the utility model embodiment
Drop is between the air wide pre. drop of traditional micro-channel heat exchanger and the air wide pre. drop of traditional finned tube exchanger, and root
Air wide pre. drop according to the heat exchanger 200 with pipe wing monomer 100 of the utility model embodiment is slightly above traditional microchannel
The air wide pre. drop of heat exchanger.It follows that under equal conditions, it is practical according to this compared with traditional micro-channel heat exchanger
The air wide pre. drop of the heat exchanger 200 with pipe wing monomer 100 of new embodiment is although slightly higher, but is not much different;With tradition
Finned tube exchanger compare, according to the windage performance of the heat exchanger 200 with pipe wing monomer 100 of the utility model embodiment
With apparent advantage, air side pressure loss opposite can be reduced.
According to the pipe wing monomer 100 of the utility model embodiment, by the way that channel part 12 and the setting of ontology 11 are integrated into
Shape part enhances the heat transfer efficiency between channel part 12 and ontology 11.Moreover, by by multiple pipe wing ontologies 1 in ontology 11
It is sequentially connected in width direction, can preferably meet practical application.It, can be with when pipe wing monomer 100 is applied to heat exchanger 200
Improve the heat exchange efficiency of heat exchanger 200.
Some embodiments according to the present utility model, the length direction being formed on ontology 11 along ontology 11 extend at least
One strip seam 113.As a result, by the way that the strip seam 113 extended along the length direction of ontology 11 is arranged on ontology 11, when
It, can be with breakdown speed side during air-flow such as air flows through ontology 11 when pipe wing monomer 100 is applied to heat exchanger 200
Interlayer, temperature boundary layer, play the role of enhanced heat exchange, to further enhance heat transfer effect.It is understood that strip
The specific size (for example, length, width etc.) of shape seam 113 can be specifically arranged according to actual requirement, preferably be strengthened with reaching
Heat transfer effect.
Some specific embodiments according to the present utility model referring to Fig. 8 and combine Fig. 9 and Figure 10, are formed on ontology 11
At least one first opening 111 penetrated through along the thickness direction of ontology 11, first is open at 111 equipped with connecting plate 112, connecting plate
112 both ends are connected with the two side walls on the length direction of ontology 11 of the first opening 111 respectively, and connecting plate 112
Positioned at the side of ontology 11 so that the corresponding wall of the side of connecting plate 112 and the first opening 111 on the thickness direction of ontology 11
Face is separated from each other to limit strip seam 113.Such as in the example of Fig. 8-Figure 10, the first opening 111 can be for along this
The oblong openings that the length direction of body 11 extends, both ends on the length direction of connecting plate 112 respectively with the first opening 111
Two side walls on length direction are connected, and the both ends in the width direction of connecting plate 112 are open in 111 width direction with first
Two side walls be staggered respectively on the thickness direction of ontology 11 to limit two strips seam 113.Strip seam 113 at this time
It can be formed by the way of punching press.Strip seam 113 is formed by using the form of above-mentioned connecting plate 112 as a result, is being strengthened
While heat exchange, can also be guaranteed by connecting plate 112 the two neighboring pipe wing monomer 100 of heat exchanger 200 ontology 11 that
This is spaced apart, so that air-flow such as air etc. can successfully flow through heat exchanger 200.
Further, as Figure 8-Figure 10, connecting plate 112 includes: the first plate section 1121 and two the second plate sections 1122,
First plate section 1121 is arranged with 11 parallel interval of ontology, and the length of the first plate section 1121 is less than the length of the first opening 111, and two
One end of a second plate section 1122 is connected with the both ends of the first plate section 1121 respectively, the other end and of two the second plate sections 1122
The two side walls on the length direction of ontology 11 of one opening 111 are connected.As a result, by using it is above-mentioned include the first plate section
1121 and two the second plate sections 1122 connecting plate 112, have the advantages of simple structure and easy realization.
Certainly, the utility model is without being limited thereto, other specific embodiments according to the present utility model, strip seam 113
Along the thickness direction perforation ontology 11 (not shown go out) of ontology 11.Strip seam 113 can be for along the thickness side of ontology 11 at this time
To the elongate holes of perforation.Enhanced heat exchange equally can be well realized as a result, and this kind of strip seam 113 is simple.
Optionally, strip seam 113 is multiple, and multiple strip seams 113 are arranged in array on ontology 11, such as Fig. 8-figure
Shown in 9.Certainly, multiple strip seams 113 can also be arranged in other ways on ontology 11, such as staggered etc..
Further embodiment according to the present utility model, as shown in Figure 11-Figure 15, ontology 11 is equipped with spaced more
A tilting structure 115, each tilting structure 115 are located at the side on the thickness direction of ontology 11.As a result, by the way that multiple stick up is arranged
Structure 115 is played, the two neighboring pipe wing monomer 100 of heat exchanger 200 can be spaced apart well, make air-flow such as air etc. can
Successfully to flow through heat exchanger 200 and exchange heat with the refrigerant in the channel part of heat exchanger 200 12.
Specifically, 1 and combining Figure 12 and Figure 13 referring to Fig.1, the thickness direction being formed on ontology 11 along ontology 11 is passed through
Logical multiple second openings 114, plurality of tilting structure 115 are respectively provided at multiple second openings 114, each tilting structure
115 one end (for example, left end in Figure 13) is connected with the side wall of corresponding second opening 114, each to tilt the another of structure 115
One end (for example, right end in Figure 13) and ontology 11 are spaced setting on the thickness direction of ontology 11.Each tilting structure at this time
The 115 above-mentioned other end is hanging.Each other end for tilting structure 115 is suitable for and another adjacent pipe wing monomer 100 as a result,
Surface contact, is separated two adjacent pipe wing monomers 100 with realizing.Moreover, the setting of the second opening 114, to a certain degree
On also can achieve the purpose of enhanced heat exchange.
Optionally, each tilting structure 115 includes: that the first tilting section 1151 and second tilts section 1152, and first tilts section
1151 are formed as slab construction, and first tilts section 1151 and the setting of 11 parallel interval of ontology, another adjacent to support well
Pipe wing monomer 100, one end (for example, right end in Figure 13) of the second tilting section 1152 tilts section 1151 with first and is connected, the
The other end (for example, left end in Figure 13) of two tilting sections 1152 is connected with the side wall of the second opening 114.For example, referring to Figure 10-
Figure 13, each second opening 114 can be formed as rectangular aperture, and first tilts section 1151 and 114 faces of corresponding second opening
Arrangement, the second tilting section 1152 are connected between the first tilting section 1151 and a side wall of the second opening 114.Pass through as a result,
Using it is above-mentioned include that the first tilting section 1151 and second tilt the tilting structure 115 of section 1152, facilitate pipe wing ontology 1 plus
Work reduces costs.Wherein, the first tilting section 1151 and the second tilting section 1152 can be along perpendicular to air-flow such as air etc.
Flow direction extend, with realize well two neighboring pipe wing monomer 100 is separated on the basis of, allow air-flow successfully
It flows through, reduces windage.
Optionally, each second opening 114 is rectangular aperture, each above-mentioned one end for tilting structure 115 and the second opening
114 side wall is connected, and the length of above-mentioned one end of tilting structure 115 is less than the said one side wall of the second opening 114
Length.For example, tilting two sides and pair of the second opening 114 of above-mentioned one end of structure 115 as shown in Figure 11-Figure 15
It answers side to be separated from each other, the feelings of stress concentration can occur in this way to avoid the junction for tilting structure 115 and the second opening 114
Condition improves the bonding strength for tilting structure 115 and ontology 11.
The structure of some embodiments according to the present utility model, multiple pipe wing ontologies 1 is all the same.For example, as shown in Figure 1,
Each pipe wing ontology 1 has a channel part 12, and in the width direction of ontology 11, ontology 11 from two sides of channel part 12 to
The length of outer extension is certain.Each pipe wing ontology 1 can be manufactured by one set of die at this time.Multiple mutually isostructural pipe wing sheets
Body 1 together constitutes pipe wing monomer 100.
Certainly, the utility model is without being limited thereto, other embodiments according to the present utility model, in multiple pipe wing ontologies 1
At least two structure it is different.For example, at least one of multiple pipe wing ontologies 1 can be to have one shown in Fig. 1
The pipe wing ontology 1 of channel part 12 can also be the pipe wing ontology 1 of channel part 12 there are two tools shown in Fig. 2, at this time pipe wing list
Body 100 can be collectively formed by the pipe wing ontology 1 of above two different structure.
Optionally, channel part 12 extends along the length direction straight line and/or curve of corresponding pipe wing ontology 1.For example, as schemed
4, shown in Fig. 5, Fig. 8-Fig. 9 and Figure 11, channel part 12 is along the length direction linear extension of pipe wing ontology 1, and the processing is simple as a result,
It is at low cost.Certainly, channel part 12 can also extend (not shown go out) along the length direction curve of pipe wing ontology 1, for example, wave
Line, camber line etc. further improve heat exchange efficiency thus, it is possible to extend the development length of runner 121.Alternatively, channel part 12 is also
It S-shaped can extend (not shown go out), channel part 12 is collectively formed by straight line and curve at this time.It is understood that channel part
12 specific extension shape can be specifically arranged according to actual requirement, preferably to meet practical application.
For example, the cross-sectional shape of runner 121 is circle, the exhausted big portion of circular flow channel 121 in the example of Fig. 1-Fig. 3
Point protrude from the side surface on the thickness direction of ontology 11, the sub-fraction of circular flow channel 121 is towards the thickness side of ontology 11
Upward another side surface is recessed.In the example of Figure 14 and Figure 15, the cross-sectional shape of runner 121 be it is trapezoidal, it is trapezoidal at this time
The long side of runner 121 can be with the side flush on the thickness direction of ontology 11, and the short side of trapezoidal runner 121 is from ontology 11
Thickness direction on an above-mentioned side surface outwardly protrude, to enhance heat transfer effect.Certainly, the cross-sectional shape of runner 121 is also
It can be other shapes, for example, ellipse, oblong, other polygons except trapezoidal etc..
As shown in Fig. 4-Figure 17, according to the heat exchanger 200 of the utility model second aspect embodiment, including multiple pipe wing lists
Body 100.Each pipe wing monomer 100 is the pipe wing monomer 100 according to the above-mentioned first aspect embodiment of the utility model.
Specifically, multiple pipe wing monomers 100 are set gradually along the thickness direction of pipe wing monomer 100.Two neighboring pipe wing
11 part of at least ontology of monomer 100 is separated from each other, so that air-flow such as air etc. can pass through two neighboring pipe wing monomer
Space between 100, sufficiently to carry out heat exchange with the refrigerant in the runner 121 of pipe wing monomer 100, as shown in Figure 7.
It can by using above-mentioned pipe wing monomer 100 according to the heat exchanger 200 of the utility model second aspect embodiment
To improve the heat exchange efficiency of heat exchanger 200, to promote the overall performance of heat exchanger 200.
Some embodiments according to the present utility model, referring to Fig. 4-Figure 15, between the ontology 11 of multiple pipe wing monomers 100 etc.
Spacing arrangement.The assembly between multiple pipe wing monomers 100 is facilitated as a result, and it is more uniform to exchange heat.
According to the air conditioner of the utility model third aspect embodiment, including shell and heat exchanger 200.Heat exchanger 200 is
According to the heat exchanger 200 of the above-mentioned second aspect embodiment of the utility model.
Specifically, heat exchanger 200 is located in shell, and the channel part 12 of heat exchanger 200 is arranged along the vertical direction, heat exchanger
Angle between the surface and vertical plane of 200 ontology 11 is α, and wherein α meets: 0 °≤α≤60 °.Heat exchanger 200 can be used as
Evaporator uses.Certainly, heat exchanger 200 is also used as condenser use.As a result, the runner 121 in channel part 12 can more than
Lower placement, as evaporator in use, the drainage performance of condensed water is excellent.
Sky is improved by using above-mentioned heat exchanger 200 according to the air conditioner of the utility model third aspect embodiment
Adjust the overall performance of device.
Some embodiments according to the present utility model, heat exchanger 200 are arranged vertically in shell.At this point, heat exchanger 200
Angle α=0 ° between the surface of ontology 11 and above-mentioned vertical plane.The condensed water generated in heat transfer process as a result, can be more suitable
Freely it is discharged.
It is constituted and is operated general for this field according to other of the heat exchanger 200 of the utility model embodiment and air conditioner
All be for logical technical staff it is known, be not detailed herein.
In the description of this specification, reference term " one embodiment ", " some embodiments ", " illustrative examples ",
The description of " example ", " specific example " or " some examples " etc. means specific features described in conjunction with this embodiment or example, knot
Structure, material or feature are contained at least one embodiment or example of the utility model.In the present specification, to above-mentioned art
The schematic representation of language may not refer to the same embodiment or example.Moreover, description specific features, structure, material or
Person's feature can be combined in any suitable manner in any one or more of the embodiments or examples.
While there has been shown and described that the embodiments of the present invention, it will be understood by those skilled in the art that:
These embodiments can be carried out with a variety of variations, modification, replacement in the case where not departing from the principles of the present invention and objective
And modification, the scope of the utility model are defined by the claims and their equivalents.
Claims (17)
1. a kind of pipe wing monomer characterized by comprising
Multiple pipe wing ontologies, each pipe wing ontology include being formed as the ontology of plate structure and setting on the body and edge
At least one channel part that the length direction of the ontology extends, the channel part and the ontology are one of the forming part, described
The thickness of ontology is less than the thickness of the channel part, and the runner of both ends open, multiple pipe wings are limited in the channel part
Ontology is sequentially connected in the width direction of the ontology.
2. pipe wing monomer according to claim 1, which is characterized in that be formed with the length along the ontology on the ontology
At least one strip seam that direction extends.
3. pipe wing monomer according to claim 2, which is characterized in that be formed with the thickness along the ontology on the ontology
Direction perforation at least one first opening, first opening be equipped with connecting plate, the both ends of the connecting plate respectively with institute
The two side walls on the length direction of the ontology for stating the first opening are connected, and the connecting plate is in the thickness of the ontology
Spend direction on be located at the ontology side so that the side of the connecting plate with it is described first be open corresponding wall surface to each other
It separates to limit the strip seam.
4. pipe wing monomer according to claim 3, which is characterized in that the connecting plate includes:
First plate section, the first plate section and the ontology parallel interval are arranged;
Two the second plate sections, one end of two the second plate sections is connected with the both ends of the first plate section respectively, described in two
The other end of second plate section is connected with the two side walls on the length direction of the ontology of first opening.
5. pipe wing monomer according to claim 2, which is characterized in that thickness direction of the strip seam along the ontology
Penetrate through the ontology.
6. pipe wing monomer according to claim 2, which is characterized in that the strip seam is multiple, multiple strips
Shape seam is arranged in array on the body.
7. pipe wing monomer according to claim 1 to 6, which is characterized in that the ontology is equipped with interval setting
Multiple tilting structures, each tilting structure is located at the side on the thickness direction of the ontology.
8. pipe wing monomer according to claim 7, which is characterized in that be formed with the thickness along the ontology on the ontology
Multiple second openings of direction perforation, the plurality of tilting structure are respectively provided at multiple second openings, Mei Gesuo
State tilt structure one end with it is corresponding it is described second opening side wall be connected, it is each it is described tilting structure the other end with it is described
Ontology is spaced setting on the thickness direction of the ontology.
9. pipe wing monomer according to claim 8, which is characterized in that each tilting structure includes:
First tilts section, and the first tilting section is formed as slab construction, and described first tilts section and the ontology parallel interval
Setting;
Second tilts section, and one end of the second tilting section is connected with the first tilting section, and described second tilts the another of section
It holds and is connected with the side wall of second opening.
10. pipe wing monomer according to claim 8, which is characterized in that each second opening is rectangular aperture, each
Described described one end for tilting structure is connected with a side wall of second opening, and described described one end for tilting structure
Length is less than the length of a side wall of second opening.
11. pipe wing monomer according to claim 1, which is characterized in that the structure of multiple pipe wing ontologies is all the same.
12. pipe wing monomer according to claim 1, which is characterized in that each pipe wing ontology is described logical with one
Road portion.
13. pipe wing monomer according to claim 1, which is characterized in that the channel part is along the corresponding pipe wing ontology
Length direction straight line and/or curve extend.
14. a kind of heat exchanger characterized by comprising
Multiple pipe wing monomers, each pipe wing monomer be according to pipe wing monomer of any of claims 1-13, it is more
A pipe wing monomer is set gradually along the thickness direction of the pipe wing monomer.
15. heat exchanger according to claim 14, which is characterized in that between the ontology of multiple pipe wing monomers etc.
Spacing arrangement.
16. a kind of air conditioner characterized by comprising
Shell;
Heat exchanger, the heat exchanger be according to right want 14 or 15 described in heat exchanger, the heat exchanger is located in the shell,
The channel part of the heat exchanger is arranged along the vertical direction, between the surface and vertical plane of the ontology of the heat exchanger
Angle is α, wherein the α meets: 0 °≤α≤60 °.
17. air conditioner according to claim 16, which is characterized in that the heat exchanger is arranged vertically in the shell.
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CN201820742519.0U CN208296664U (en) | 2018-05-17 | 2018-05-17 | Pipe wing monomer and heat exchanger, air conditioner with it |
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CN201820742519.0U CN208296664U (en) | 2018-05-17 | 2018-05-17 | Pipe wing monomer and heat exchanger, air conditioner with it |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108662938A (en) * | 2018-05-17 | 2018-10-16 | 广东美的制冷设备有限公司 | Pipe wing monomer and heat exchanger, air conditioner with it |
JPWO2021009889A1 (en) * | 2019-07-18 | 2021-11-25 | 三菱電機株式会社 | Heat transfer tube and heat exchanger using it |
JPWO2021001953A1 (en) * | 2019-07-03 | 2021-11-25 | 三菱電機株式会社 | Heat exchanger and refrigeration cycle equipment |
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2018
- 2018-05-17 CN CN201820742519.0U patent/CN208296664U/en active Active
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108662938A (en) * | 2018-05-17 | 2018-10-16 | 广东美的制冷设备有限公司 | Pipe wing monomer and heat exchanger, air conditioner with it |
JPWO2021001953A1 (en) * | 2019-07-03 | 2021-11-25 | 三菱電機株式会社 | Heat exchanger and refrigeration cycle equipment |
JP7166458B2 (en) | 2019-07-03 | 2022-11-07 | 三菱電機株式会社 | Heat exchanger and refrigeration cycle equipment |
JPWO2021009889A1 (en) * | 2019-07-18 | 2021-11-25 | 三菱電機株式会社 | Heat transfer tube and heat exchanger using it |
JP7262586B2 (en) | 2019-07-18 | 2023-04-21 | 三菱電機株式会社 | Heat transfer tube and heat exchanger using the same |
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