HEAT EXCHANGER WITH MICROCHANNEL, PARALLEL FLOW, ALL-ALUMINIUM FLAT TUBE WELDING STRUCTURE AND ITS APPLICATION

Abstract

The present invention discloses a heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure, wherein the heat exchange part of the heat exchanger is formed by flat tubes composed of extruded thin-wall aluminum profiles in parallel arrangement. Compared to existing technology, the present invention has the following advantages: 1. The heat exchange efficiency of refrigerant and the inner wall of flat tubes is increased by 40%, and the flow resistance of the refrigerant in the heat exchanger is reduced by 40%. 2. The heat exchange efficiency of fins on air side is increased by 40%, and the wind resistance of the heat exchanger on air side is reduced by 40%. 3. The heat exchange performance of the entire heat exchanger is improved by 40%. 4. The refrigerant covered is 40% less than that in the conventional technology. 5. All-aluminum structure features longer service life due to no copper-aluminum potential difference when comparing with copper-aluminum structure. The flat tubes adopted by the present invention are provided with the advantages of resistance to high pressure restricted by the existing refrigerant, compact product structure, light unit weight, short process flow, and high manufacturing reliability and relatively low cost. The present invention also discloses the application of the abovementioned heat exchanger.

Description

BACKGROUND OF THE INVENTION

1. Technical Field

The present invention relates to a heat exchanger and its application, and in particular, relates to a heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure and its application. The new series of heat exchangers all adopt aluminium as the main material: it is a recyclable material with stronger corrosion resistance than copper-tube aluminium-sheet heat exchanger; moreover, the microchannel flat tube design improves the efficiency on the refrigerant side of the heat exchanger, the advanced design of the parallel flow structure+fin greatly increases the air side efficiency of the heat exchanger, so as to substantially upgrade the overall efficiency of the heat exchanger. The new series of heat exchangers have the advantages of environmental protection, low consumption of refrigerant, resistance to pressure, high efficiency, high reliability, low cost for recovery, and no potential difference or primary cell effect.

2. Description of Related Art

The heat exchanger in the conventional heat exchanger system mainly adopts the copper-tube aluminium-sheet expansion tube form; as shown in FIG. 1, as for the outdoor unit in the conventional heat exchanger system, the heat exchanger part 10 uses the expansion tube structure combining copper tube 11 and aluminium sheet 12 as shown in FIG. 3 and FIG. 4; as for the indoor unit in conventional heat exchanger system as shown in FIG. 2, the heat exchanger 20 uses the expansion tube structure combining copper tube 21 and aluminium sheet 22 as shown in FIG. 5. The conventional heat exchanger system has the following problems:

1. Low heat exchange efficiency between the refrigerant on the refrigerant side and the inner wall of the copper tube, and strong flow resistance of refrigerant in the copper tube of the heat exchanger.

2. Low heat exchange efficiency of fin on air side and strong wind resistance.

3. High consumption of refrigerant and inconsistent with environmental protection requirements.

4. Existence of potential difference between aluminium sheet and copper tube, erodes easily, and short service life.

5. Thickness of the heat exchanger, heavy weight and high logistics cost.

6. High power of fan and compressor and high energy consumption.

The applicant invented an extruded thin-wall aluminium profile in 2006, and submitted it to the State Intellectual Property Office of the P.R.C for patent application of utility model. It has been granted the publication number for granting of CN201007423. The extruded thin-wall aluminium profile, formed by smelting and extruding aluminum ingot, is composed of at least one flat channel tube. The channel tubes are independent, parallel to each other and transversely connected through connectors, so as to form multi-channel parallel flow tubes with symmetrical structure or asymmetric structure. At least one cold-heat agent flow channel is set in the channel tube. And at least the section of one part of the cold-heat agent flow channel is in the shape of round or ellipse or polygon or undulation or any combination of the shapes, so as to fit for the requirements for the design of various products and the requirements for different cold-heat agents. Various cold-heat agent flow channels are parallel to each other to form double-flow-channel extruded thin-wall aluminium profile or multi-flow-channel extruded thin-wall aluminium profile. The cold-heat agent flow channels are separated by fins to replace conventional electrolytic copper tubes, effectively reducing energy consumption and environmental pollution, and improving the effective utilization of resources. The profile has the advantages of low cost for recovery, wide application in industries and so on.

The applicant also invented a cool-heat exchanger in 2006 according to the extruded thin-wall aluminium profile mentioned above, and submitted it to the State Intellectual Property Office of the P.R.C for patent application of utility model. It has been granted the publication number for granting of CN2932273. The heat exchanger is comprised of a first collecting tube and a second collecting tube with coupling holes, a plurality of flat tubes parallel to each other which are inserted into the coupling holes in the first, second collecting tubes and link the first, second collecting tubes, and outer fins between adjacent flat tubes, wherein each flat tube unit is composed of at least one flat channel tube, and a parallel connection part is provided between flat channel tubes. This cool-heat exchanger is applicable to the parallel-flow oil coolers for automobile automatic gearbox cooling oil, and parallel-flow water tank for automobile engine cooling water and parallel-flow heating air core for heating air for automobile air conditioners.

There is no related news for the application of the heat exchanger composed of the abovementioned extruded thin-wall aluminium profile in refrigerant-based heat exchange rooms through gas-liquid physical change via R12, R22, R410A, R407C, R123, HFC134A and so on, and in similar-purpose air conditioning systems, freezing and refrigeration systems, air conditioning systems for refrigeration and dehumidification, heat pump heating and water cooling/heating and air conditioning systems, computer cooling modules in the IT industry, cooling systems in equipment and other air heat exchange systems in other industries.

SUMMARY OF THE INVENTION

The technical problem to be solved by the present invention is, on one hand, to provide a heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure applicable to heat exchange for refrigerant and made of the abovementioned extruded thin-wall aluminium profiles and high effective fins through assembly.

The technical problem to be solved by the present invention is, on the other hand, to provide the application of the abovementioned heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure.

The heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure as in the first aspect is characterized in that the heat exchange part of the heat exchanger is formed by flat tubes composed of extruded thin-wall aluminium profile in parallel mode.

In the first preferred embodiment of the heat exchanger for the present invention, there is one flat tube which forms the heat exchange part of the heat exchanger by multiple reciprocated bending horizontally.

In the second preferred embodiment of the heat exchanger for the present invention, there is one flat tube which forms the heat exchange part of the heat exchanger by multiple reciprocated bending vertically.

In the third preferred embodiment of the heat exchanger for the present invention, there are two flat tubes which form the heat exchange part of the heat exchanger by multiple reciprocated bending horizontally or vertically.

In the abovementioned first, second and third preferred embodiments of the heat exchanger for the present invention, one end of the flat tube is the inlet of heat exchange medium, and the other end of the flat tube is the outlet of heat exchange medium.

In the fourth preferred embodiment of the heat exchanger for the present invention, there are over two flat tubes which are arranged in one row at horizontal interval in parallel mode; the heat exchanger in this embodiment further is comprised of a first collecting tube on one end of the over two flat tubes and a second collecting tube on the other end of the over two flat tubes.

In the fifth preferred embodiment of the heat exchanger for the present invention, there are over two flat tubes which are arranged in a row at vertical intervals in parallel mode; the heat exchanger in this embodiment further is comprised of a first collecting tube on one end of the over two flat tubes and a second collecting tube on the other end of the over two flat tubes.

In the sixth preferred embodiment of the heat exchanger for the present invention, there are over two flat tubes which are arranged in two rows at vertical intervals in parallel mode; the heat exchanger in this embodiment further is comprised of a first collecting tube connecting one end of the first row of the flat tubes, a second collecting tube connecting the other end of the first row of the flat tubes, a third collecting tube connecting one end of the second row of the flat tubes, and a fourth collecting tube connecting the other end of the second row of the flat tubes; wherein the first collecting tube and the third collecting tube are located in the same direction of two rows of the flat tubes, parallel to each other, and communicated according to the flow direction of heat exchange medium, the second collecting tube and the fourth collecting tube are located in the same direction of two rows of the flat tubes, parallel to each other, and communicated according to the flow direction of heat exchange medium.

In the seventh embodiment of the heat exchanger for the present invention, there are over two flat tubes which are arranged in two rows at horizontal interval in parallel mode; the heat exchanger in this embodiment further is comprised of a first collecting tube connecting one end of the first row of the flat tubes, a second collecting tube connecting the other end of the first row of the flat tubes, a third collecting tube connecting one end of the second row of the flat tubes, and a fourth collecting tube connecting the other end of the second row of the flat tubes; wherein the first collecting tube and the third collecting tube are located in the same direction of two rows of the flat tubes, parallel to each other, and communicated according to the flow direction of heat exchange medium, the second collecting tube and the fourth collecting tube are located in the same direction of two rows of the flat tubes, parallel to each other, and communicated according to the flow direction of heat exchange medium.

In the eighth embodiment of the heat exchanger for the present invention, there are over two flat tubes which are arranged in two rows at horizontal or vertical intervals in parallel mode; the heat exchanger in this embodiment further is comprised of a first collecting tube connecting one end of the flat tubes, and a second collecting tube connecting the other end of the flat tubes.

In the abovementioned embodiment, the heat exchanger formed by arranging flat tubes at horizontal or vertical intervals in parallel mode is placed vertically or horizontally or at an included angle of 15°˜25° with the horizontal ground.

In the abovementioned embodiment, the flat tubes are twisted into spiral shapes with the helix angle less than 68.2°, namely thread pitch ≦2.5 times of flat tube width. The thickness of the flat tubes is 1.0 mm-2.5 mm, 1.3 mm-2.0 mm preferably.

In the ninth embodiment of the heat exchanger for the present invention, the flat tubes are over two U-shaped flat tubes, wherein various U-shaped flat tubes are arranged in one row at horizontal or vertical interval in parallel mode, the both ends of each U-shaped flat tube are connected by a first collecting tube and a second collecting tube respectively, the first and the second collecting tubes are parallel to each other and communicated according to the flow direction of heat exchange medium.

In the abovementioned ninth embodiment, the U-shaped flat tubes are twisted into spiral shapes with the helix angle less than 68.2°, namely thread pitch ≦2.5 times of flat tube width. The thickness of the flat tubes is 1.0 mm-2.5 mm, 1.3 mm-2.0 mm preferably.

In the abovementioned embodiment, the inlet and outlet of the heat exchange medium can be set on the ends of the collecting tubes; or in the wall of a collecting tube simultaneously. When the length of the connecting tube with the inlet or outlet for the heat exchange medium is no less than 300 mm, the inlet or outlet of the heat exchange medium is multiple, the distance between two adjacent inlets of heat exchange medium or two adjacent outlets of heat exchange medium is less than 150 mm and all inlets or outlets of the heat exchange medium are distributed at equal spacing.

In the abovementioned fourth and fifth embodiments, the heat exchanger can be an odd-loop single-row parallel-flow heat exchanger or an even-loop single-row parallel-flow heat exchanger. With regard to the odd-loop single-row parallel-flow heat exchanger, the inlet and outlet of heat exchange medium are set on the ends of the first collecting tube and the second collecting tube respectively in diagonal distribution, while in regard to the even-loop parallel-flow heat exchanger, the inlet and outlet are both set on the first collecting tube or the second collecting tube. In particular, when the fifth embodiment is an odd-loop single-row parallel-flow heat exchanger, it can functions as a condenser or an evaporator, wherein when it is used as an evaporator, the inlet of the heat exchange medium is set at the bottom of the heat exchanger; when it is used as a condenser, the inlet of the heat exchange medium is set on the top of the heat exchanger, and the outlet is set at the bottom of the heat exchanger. When the fifth embodiment is an even-loop single-row parallel-flow heat exchanger, regardless if it functions as a condenser or an evaporator, the inlet and outlet of the heat exchange medium are both located at the bottom of the heat exchanger.

With regard to the odd-loop single-row parallel-flow heat exchanger and the even-loop single-row parallel-flow heat exchanger, when the loop number is over one, the volume of various loops shall be distributed according to appropriate proportion, for instance, as for double-loop single-row parallel-flow heat exchanger, the volume of the first loop is 80% of the total volume of loops, and that of the second loop is 20% of the total volume of loops. With regard to the three-loop single-row parallel-flow heat exchanger, the volume of the first loop is 55% of the total volume of loops, that of the second loop is 30% of the total volume of loops, and that of the third loop is 15% of the total volume of loops. With regard to the four-loop single-row parallel-flow heat exchanger, the volume of the first loop is 40% of the total volume of loops, that of the second loop is 27% of the total volume of loops, that of the third loop is 20% of the total volume of loops and that of the fourth loop is 13% of the total volume of loops. With regard to the five-loop single-row parallel-flow heat exchanger, the volume of the first loop is 34% of the total volume of loops, that of the second loop is 24% of the total volume of loops, that of the third loop is 18% of the total volume of loops, that of the fourth loop is 13% of the total volume of loops and that of the fifth loop is 13% of the total volume of loops. With regard to the six-loop single-row parallel-flow heat exchanger, the volume of the first loop is 30% of the total volume of loops, that of the second loop is 20% of the total volume of loops, that of the third loop is 17% of the total volume of loops, that of the fourth loop is 14% of the total volume of loops, that of the fifth loop is 10% of the total volume of loops and that of the sixth loop is 9% of the total volume of loops; the abovementioned loops are isolated by baffles set in the first collecting tube or the second collecting tube.

In the sixth embodiment, the length of heat exchange medium axially flowing in the first collecting tube and the third collecting tube is more than that of heat exchange medium axially flowing in the second collecting tube and the fourth collecting tube, and the axially flowing length in the first collecting tube and the third collecting tube is as long as possible, while the axially flowing length in he second collecting tube and the fourth collecting tube as short as possible. In particular, the length of heat exchange medium axially flowing in the first collecting tube and the third collecting tube take up over 70% of the length of heat exchange medium axially flowing in the first, second, third and fourth collecting tubes, while the length of the heat exchange medium axially flowing in the second collecting tube and the fourth collecting tube accounts for less than 30% of the length of heat exchange medium axially flowing in the first, second, third and fourth collecting tubes.

In the sixth embodiment, the first collecting tube and the third collecting tube are not directly interconnected, while the second collecting tube and the fourth collecting tube are directly interconnected via a part. In particular, in this embodiment, the axially flowing of heat exchange medium is completed in the first collecting tube and the third collecting tube, while the flowing of heat exchange medium between the first row of the flat tubes and the second row of the flat tubes is completed via the part (for example, a hole) interconnecting the second collecting tube and the fourth collecting tube; the heat exchanger is isolated into several loops through baffles in the collecting tubes, wherein these loops are interconnected in series. In particular, the volume of various loops along heat exchange medium flowing direction is increasing, but the volume of the last loop shall be no more than 2.5 times of the volume of the first loop. Preferably: the volume of the latter loop is 20-60% higher than that of the former loop; and more preferably: the volume of the latter loop is 40-50% higher than that of the former loop.

In the sixth embodiment, a feeder for supplementing the heat exchange medium to the last two loops is set on the two loops, wherein the feeder can be designed in any shape, quantity and location as long as the medium amount supplemented is incapable of substantially destroying the original medium flow rate; the heat exchange medium supplemented to the last loop can be 15-20% of the total weight of heat exchange medium.

In the sixth embodiment, the inlet and outlet of the heat exchange medium is set in the side walls of the first collecting tube or the third collecting tube.

In the abovementioned technical solution, several orifice plates are configured in the collecting tubes at certain interval, each orifice plate is provided with orifices to play a part of turbulence and spraying and realize gas-liquid separation. The spacing distance between the orifice plates is less than 80 mm, 50 mm preferably.

In the abovementioned technical solution, the thickness of the flat tubes is 1.0 mm-2.5 mm, preferably 1.0 mm-2.0 mm for cooling-only condenser, preferably 1.6 mm-2.5 mm for cooling-only evaporator; preferably 1.3 mm-2.0 mm for heat-pump indoor and outdoor heat exchangers. The section of single orifice in perforated microchannel inside flat tubes is 0.36 mm²-1.00 mm² preferably.

In the abovementioned technical solution, fins are set between the flat tubes, wherein the window angle of fins at the wind speed of 1.5M/s-2M/s is 22°-45°, preferably 27°-33°. The pitch of fins at the wind speed of 1.5 M/s-2 M/s is 2.0 mm-5.0 mm, 2.2 mm-2.8 mm in preferred solution of high-efficiency heat exchanger, 2.6 mm-3.0 mm in the preferred solution stressing both high-efficiency heat exchange and dehumidification; 3.6 mm-5.0 mm in preferred solution in freezing & refrigeration or dehumidification-only or sand-dust regions. When the abovementioned heat exchanger with flat-tube fins and bent tubes is applied in heat exchange systems without air blowers, windowless design is adopted, wherein the pitch of fins is equal to the height of fins.

In the abovementioned heat exchanger, the condensate water discharge problem is addressed by using the design of flat tube length perpendicular to the ground, gas-liquid separation problem is solved by utilizing the turbulence and spraying of orifice plates, and heat exchange efficiency is improved by means of changing loop volume.

In the abovementioned heat exchanger, the gas-liquid separation problem caused by gravity can be solved by utilizing the design of horizontal placement of the parallel-flow heat exchanger, and condensate water discharge problem can be addressed by means of hydrophilic treatment of fins of the parallel-flow heat exchanger fin+gravity action.

In the abovementioned heat exchanger, at least one microchannel extensible along the flat tube length direction is mounted in the flat tubes.

In the abovementioned heat exchanger, the section of the collecting tubes is D-shaped to further reduce the loss of heat exchange medium in collecting tubes.

To increase the intensity of the collecting tubes, reinforcing ribs are configured on the three sides of tube walls of the D-shaped collecting tubes without connecting the flat tubes along collecting tube length direction, with the interval of two adjacent reinforcing ribs being 25.4 mm.

In the abovementioned embodiment, the flat tubes are Zinc-coated with the thickness of zinc coating of 12˜18 g/m².

The abovementioned heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure can be applied in air conditioners for housing and commercial use, and many other specialized heat exchange systems, and in particular, in rooms and similar-purpose air conditioning systems, freezing and refrigeration systems, air conditioning systems for refrigeration and dehumidification, heat pump heating and water cooling/heating and air conditioning systems, computer cooling modules in IT industry and cooling systems in equipment.

The present invention is designed to adopt microchannel flat tubes to form effective heat exchange flow channels and heat exchange areas through tube bending, and assemble high-efficiency fins between adjacent two flat tubes after flat tube bending, and then form all-aluminium heat exchanger. The heat exchanger with this design has the advantages of resistance to pressure to a maximum degree, compact product structure, light unit weight, short process flow, high manufacturing reliability and relatively low cost. The special design allows the product to exert better heat exchange effect when the frontal area is less than 0.2 m² and obtain a performance 20% higher than the conventional copper tube+aluminium sheet structure.

Comparing with the existing technology, the present invention has the following advantages due to the adoption of the abovementioned technical solutions:

1. The heat exchange efficiency of refrigerant and the inner wall of flat tubes is increased by 40%, and the flow resistance of the refrigerant in the heat exchanger is reduced by 40%.

2. The heat exchange efficiency of fins on air side is increased by 40%, and the wind resistance of the heat exchanger on air side is reduced by 40%.

3. The heat exchange performance of the whole heat exchanger is improved by 40%.

4. The refrigerant covered is 30% less than that in the conventional technology.

5. All-aluminium structure features longer service life due to no copper-aluminium potential difference when compared to copper-aluminium structure.

The flat tubes adopted by the present invention are provided with the advantages of resistance to high pressure, compact product structure, light unit weight, short process flow, high manufacturing reliability and relatively low cost.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is further explained in combination with the drawings and embodiments.

FIG. 1 is the schematic view of the outdoor unit structure in the conventional heat exchanger system.

FIG. 2 is the schematic view of the indoor unit structure in the conventional heat exchanger system.

FIG. 3 is the schematic view of the structure of the heat exchanger adopting copper-tube aluminium-sheet expansion tubes for the outdoor unit in the conventional heat exchanger system.

FIG. 4 is the left view of FIG. 3.

FIG. 5 is the schematic view of the structure of the heat exchanger adopting copper-tube aluminium-sheet expansion tubes for the indoor unit in the conventional heat exchanger system.

FIG. 6 is the schematic view of embodiment 1 of the heat exchanger for the present invention.

FIG. 7 is the schematic view of embodiment 2 of the heat exchanger for the present invention.

FIG. 8 is the schematic view of embodiment 3 of the heat exchanger for the present invention.

FIG. 9 is the thermogram of embodiment 3 during performance testing for the present invention.

FIG. 10 is the schematic view of embodiment 4 of the heat exchanger for the present invention.

FIG. 11 is the schematic view of the structure of embodiment 5 of the heat exchanger for the present invention.

FIG. 12 is the bottom view of FIG. 11.

FIG. 13 is the left view of FIG. 11.

FIG. 14 shows the connection relations between flat tubes and fins in embodiment 5.

FIG. 15 is the view from A of FIG. 14.

FIG. 16 is the schematic view of the structure of embodiment 6 of the heat exchanger for the present invention.

FIG. 17 is the schematic view of the structure of embodiment 7 of the heat exchanger for the present invention.

FIG. 18 is the schematic view of the structure of embodiment 8 of the heat exchanger for the present invention.

FIG. 19 is the schematic view of the structure of embodiment 9 of the heat exchanger for the present invention.

FIG. 20 is the bottom view of FIG. 19.

FIG. 21 is the left view of FIG. 19.

FIG. 22 is the schematic view of the structure of embodiment 10 of heat exchanger for the present invention.

FIG. 23 is the schematic view of the structure of embodiment 11 of heat exchanger for the present invention.

FIG. 24 is the top view of FIG. 23.

FIG. 25 is the left view of FIG. 23.

FIG. 26 is the schematic view of the structure of embodiment 12 of heat exchanger for the present invention.

FIG. 27 is the schematic view of the structure of embodiment 13 of heat exchanger for the present invention.

FIG. 28 is the bottom view of FIG. 27.

FIG. 29 is the left view of FIG. 27.

FIG. 30 is the schematic view of the structure of embodiment 14 of heat exchanger for the present invention.

FIG. 31 is the schematic view of the structure of embodiment 15 of heat exchanger for the present invention.

FIG. 32 is the top view of FIG. 31.

FIG. 33 is the left view of FIG. 31.

FIG. 34 is the schematic view of embodiment 15 of the heat exchanger during refrigeration for the present invention.

FIG. 35 is the schematic view of FIG. 34 enlarged from I.

FIG. 36 is the thermogram of embodiment 15 during refrigeration operation.

FIG. 37 is the schematic view of embodiment 15 of the heat exchanger during heating for the present invention.

FIG. 38 is the schematic view of FIG. 37 enlarged from I.

FIG. 39 is the thermogram of embodiment 15 during heating operation.

FIG. 40 is the schematic view of the structure of embodiment 16 of the heat exchanger for the present invention.

FIG. 41 is the top view of FIG. 40.

FIG. 42 is the left view of FIG. 40.

FIG. 43 is the schematic view of the structure of embodiment 17 of the heat exchanger for the present invention.

FIG. 44 is the top view of FIG. 43.

FIG. 45 is the left view of FIG. 43.

FIG. 46 is the schematic view of embodiment 18 of the heat exchanger for the present invention.

FIG. 47 is the schematic view of embodiment 19 of the heat exchanger for the present invention.

FIG. 48 is the schematic view of embodiment 20 of the heat exchanger for the present invention.

FIG. 49 is the schematic view of embodiment 21 of the heat exchanger for the present invention.

FIG. 50 is the schematic view of the connection relations between round collecting tubes and flat tubes in the conventional structure.

FIG. 51 is the schematic view of flow resistance in round collecting tubes of the conventional structure.

FIG. 52 is the schematic view of the connection relations between D-shaped collecting tubes and flat tubes for the present invention.

FIG. 53 is the schematic view of flow resistance in D-shaped collecting tubes for the present invention.

FIG. 54 is the schematic view of the structure of the D-shaped collecting tube for the present invention.

FIG. 55 is the schematic view of the structure of the reinforcing ribs in the D-shaped collecting tube for the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is further explained in combination with embodiments in order to make the technical means, invention features, purposes and functions of the present invention easily understood.

Embodiment 1

The heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure in this embodiment is a double-loop single-row parallel-flow heat exchanger, and used for heating as a heat pump type indoor heat exchanger. As shown in FIG. 6, the heat exchanger is comprised of a first collecting tube 100, a second collecting tube 200 and several flat tubes 300 linking the first collecting tube 100 and the second collecting tube 200, wherein the flat tubes 300 are composed of extruded thin-wall aluminium profiles with the thickness of the flat tubes 300 from 1.3 mm to 2.0 mm.

In this embodiment, several flat tubes 300 are arranged in one row at vertical intervals in parallel mode; the first collecting tube 100 is located on top of the whole heat exchanger, the second collecting tube 200 is at the bottom of the heat exchanger; the inlet 400 of heat exchange medium is located on the left end of the first collecting tube 100, the outlet 500 is located on the right end of the second collecting tube 200. Baffles 110, 210 which (110, 210) isolate the whole heat exchanger into the first loop 610 and the second loop 620 are set in the first collecting tube 100 and the second collecting tube 200 respectively. The volume of the first loop 610 takes up 80% of the total volume of loops, and the volume of the second loop 620 covers 20% of the total volume of loops. Three orifice plates 700 are configured in the second collecting tube 200 at certain interval. Each orifice plate 700 is provided with orifices 710 to play a part of turbulence and spraying. The spacing distance between the orifice plates 700 is less than 80 mm, 50 mm optimally. The working principles of the embodiment: heat exchange medium such as refrigerant enters from the inlet 400 on the left end of the first collecting tube 100, flows downwards vertically to the side of the second collecting tube 200 with orifice plates 700 installed through the flat tubes of the first loop 610, and then flows to the side of the second collecting tube 200 without orifice plates 700 after throttling, afterwards, flows upwards into the first collecting tube 100 vertically through the flat tubes of the second loop 620, and then flows out from the outlet 500.

Embodiment 2

The heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure in this embodiment is a double-loop single-row parallel-flow heat exchanger, and used for refrigeration as a heat pump type indoor heat exchanger. As shown in FIG. 7, the structure is the same as embodiment 1, but the inlet 400 and outlet 500 of heat exchange medium are in different locations. In this embodiment, the inlet 400 of heat exchange medium is located on the right end of the first collecting tube 100, and the outlet 500 is on the left end of the first collecting tube 100.

The working principles of the embodiment: heat exchange medium such as heating agent enters from the inlet 400 on the right end of the first collecting tube 100, flows downwards vertically to the side of the second collecting tube 200 without orifice plates 700 through the flat tubes of the second loop 620, and then flows to the side of the second collecting tube 200 with orifice plates 700 installed; after throttling by orifice plates 700, flows upwards into the first collecting tube 100 vertically through the flat tubes of the first loop 610, and then flows out from the outlet 500.

Embodiment 3

The heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure in this embodiment is a three-loop single-row parallel-flow heat exchanger, and its refrigerant flow direction is designed for heating use as a heat pump type indoor heat exchanger. As shown in FIG. 8, the heat exchanger is comprised of first collecting tube 100, a second collecting tube 200 and several flat tubes 300 linking the first collecting tube 100 and the second collecting tube 200, wherein the flat tubes 300 are composed of extruded thin-wall aluminium profiles with the thickness of the flat tubes 300 from 1.3 mm to 2.0 mm.

In this embodiment, several flat tubes 300 are arranged in one row at vertical intervals in parallel mode; the first collecting tube 100 is located on the top of the whole heat exchanger, the second collecting tube 200 is at the bottom of the whole heat exchanger; the inlet 400 of heat exchange medium is located on the left end of the first collecting tube 100, the outlet 500 is located on the right end of the first collecting tube 100, the inlet 400 and outlet 500 are diagonally distributed. Baffles 110, 120, 210, 220 which (110, 120, 210, 220) isolate the whole heat exchanger into the first loop 610, the second loop 620 and the third loop 630 are set in the first collecting tube 100 and the second collecting tube 200 respectively. The volume of the first loop 610 takes up 55% of the total volume of loops, the volume of the second loop 620 covers 30% of the total volume of loops and the volume of the third loop 630 accounts for 15% of the total volume of loops. Three orifice plates 700 are configured in the second collecting tube 200 at certain interval. Each orifice plate 700 is provided with orifices 710 to play a part of turbulence and spraying. The spacing distance between the orifice plates 700 is less than 80 mm, 50 mm preferably. The working principles of the embodiment: heat exchange medium such as refrigerant enters from the inlet 400 on the left end of the first collecting tube 100, flows downwards vertically to the side of the second collecting tube 200 with orifice plates 700 installed through the flat tubes of the first loop 610, and then flows to the middle side of the second collecting tube 200 without orifice plates 700 after throttling by orifice plates 700, afterwards, flows upwards into the first collecting tube 100 vertically through the flat tubes of the second loop 620, and then flows downwards vertically to the other side of the second collecting tube 200 without orifice plates 700 through the first collecting tube 100 and via the flat tubes of the third loop 630, finally flows out from the outlet 500.

As shown in FIG. 9, the thermogram in this embodiment shows that the refrigerant inside the microchannel parallel-flow heat exchanger exhinbits reasonable layout, effective supper-cooling degree control and high heat exchange efficiency.

Embodiment 4

The heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure in this embodiment is a three-loop single-row parallel-flow heat exchanger, and its refrigerant flow direction is designed for refrigeration use as a heat pump type indoor heat exchanger. As shown in FIG. 10, the heat exchanger is comprised of a first collecting tube 100, a second collecting tube 200 and several flat tubes 300 linking the first collecting tube 100 and the second collecting tube 200, wherein the flat tubes 300 are composed of extruded thin-wall aluminium profiles with the thickness of the flat tubes 300 from 1.3 mm to 2.0 mm.

In this embodiment, several flat tubes 300 are arranged in one row at vertical intervals in parallel mode; the first collecting tube 100 is located on the top of the whole heat exchanger, the second collecting tube 200 is at the bottom of the whole heat exchanger; the inlet 400 of heat exchange medium is located on the right end of the second collecting tube 200, the outlet 500 is located on the left end of the first collecting tube 100, the inlet 400 and outlet 500 are diagonally distributed. Baffles 110, 120, 210, 220 which (110, 120, 210, 220) isolate the whole heat exchanger into the first loop 610, the second loop 620 and the third loop 630 are set in the first collecting tube 100 and the second collecting tube 200 respectively. The volume of the first loop 610 takes up 55% of the total volume of loops, the volume of the second loop 620 covers 30% of the total volume of loops and the volume of the third loop 630 accounts for 15% of the total volume of loops. Three orifice plates 700 are configured in the second collecting tube 200 at certain intervals. Each orifice plate 700 is provided with orifices 710 to play a part of turbulence and spraying. The spacing distance between the orifice plates 700 is less than 80 mm, 50 mm preferably. The working principles of the embodiment: heat exchange medium such as refrigerant enters from the inlet 400 on the right end of the second collecting tube 200, flows upwards vertically to one side of the first collecting tube 100 through the flat tubes of the third loop 630, and then flows to the middle side of the first collecting tube 100 through the middle side of the first collecting tube 100 and the second loop 620, and then flows to the side of the second collecting tube 200 with orifice plates 700 installed, after the throttling by the orifice plates 700, flows upwards vertically into the first collecting tube 100 through the flat tubes of the first loop 610, finally flows out from the outlet 500.

Embodiment 5

The heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure in this embodiment is a double-loop single-row parallel-flow heat exchanger, and used for refrigeration and heating as a heat pump type indoor heat exchanger. As shown in FIGS. 11-13, the heat exchanger is comprised of a first collecting tube 100, a second collecting tube 200 and several flat tubes 300 linking the first collecting tube 100 and the second collecting tube 200, wherein the flat tubes 300 are composed of extruded thin-wall aluminium profiles with the thickness of the flat tubes 300 from 1.3 mm to 2.0 mm.

In this embodiment, several flat tubes 300 are arranged in a row at vertical intervals in parallel mode; the first collecting tube 100 is located on the top of the whole heat exchanger, the second collecting tube 200 is at the bottom of the whole heat exchanger; the inlet 400 and outlet 500 of heat exchange medium are located on the second collecting tube 200. Baffles 210 which (210) isolate the whole heat exchanger into the first loop 610 and the second loop 620 are set in the second collecting tube 200 respectively. The volume of the first loop 610 takes up 80% of the total volume of loops, the volume of the second loop 620 covers 20% of the total volume of loops.

The working principles of the embodiment: heat exchange medium such as refrigerant enters from the inlet 400 on the left side of the second collecting tube 200, flows upwards vertically to one side of the first collecting tube 100 through the flat tubes of the first loop 610, then flows to the other side of the first collecting tube 100, then flows upwards vertically to the other side of the second collecting tube 200 through the flat tubes of the second loop 620, and finally flows out from the outlet 500.

As shown in FIGS. 14 and 15, the fins 800 which are snake-shaped folding type are set between adjacent two flat tubes 300, wherein the window angle of fins at the wind speed of 2 M/s is 22°-45°, preferably 27°-33°. The pitch H of fins at the wind speed of 1.5 M/s-2 M/s is 2.0 mm-5.0 mm, preferably 2.2 mm-3.6 mm. When the abovementioned heat exchanger is applied in heat exchange systems without air blowers, windowless design is adopted and pitch H for the fins 800 is equal to the height of the fins 800.

The flat tubes 300 along draft direction adopt A° design to guide condensate water of the heat exchanger, wherein 30°≦A°°60°; the window length of the fins 800 is utilized to stop the formation of condensate water, the windowless length of fins, namely the distance from window bottom to the edge of fins B is no more than 0.3 mm, optimally from 0.10 mm to 0.15 mm.

Embodiment 6

The heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure in this embodiment is a single-loop single-row parallel-flow heat exchanger, and used as an evaporator or a condenser in water-cooling system. As shown in FIG. 16, the heat exchanger is comprised of a first collecting tube 100, a second collecting tube 200 and several flat tubes 300 linking the first collecting tube 100 and the second collecting tube 200, wherein the flat tubes 300 are composed of extruded thin-wall aluminium profiles with the thickness of the flat tubes 300 from 1.6 mm to 2.0 mm.

In this embodiment, several flat tubes 300 are arranged in one row at vertical interval in parallel mode; the first collecting tube 100 is located on the top of the whole heat exchanger, the second collecting tube 200 is at the bottom of the whole heat exchanger; the inlet 400 of heat exchange medium is located on the left end of the first collecting tube 100, the outlet 500 is on the right end of the second collecting tube 200, the inlet 400 and outlet 500 are diagonally distributed. The flat tubes 300 are twisted into spiral shape with the helix angle ≦68.2°, thread pitch ≦2.5 times of the width of the flat tubes 300. Wherein, the flat tube width refers to the dimension other than length and thickness among the three dimensions of a flat tube.

The working principles of the embodiment: heat exchange medium such as refrigerant enters from the inlet 400 on the left side of the first collecting tube 100, flows downwards vertically to the second collecting tube 200 through the flat tubes 300, and then flows out from the outlet 500.

Embodiment 7

The heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure in this embodiment is a single-loop single-row parallel-flow heat exchanger, and used as an evaporator or a condenser in water-cooling system. As shown in FIG. 16, the heat exchanger is comprised of a first collecting tube 100, a second collecting tube 200 and several flat tubes 300 linking the first collecting tube 100 and the second collecting tube 200, wherein the flat tubes 300 are composed of extruded thin-wall aluminium profiles with the thickness of the flat tubes 300 from 1.6 mm to 2.0 mm.

In this embodiment, several flat tubes 300 are arranged in one row at horizontal interval in parallel mode; the first collecting tube 100 is located on one side of the whole heat exchanger, the second collecting tube 200 is on the other side of the whole heat exchanger; the inlet 400 of heat exchange medium is located on the bottom end of the first collecting tube 100, the outlet 500 is on the top end of the second collecting tube 200, the inlet 400 and outlet 500 are diagonally distributed. The flat tubes 300 are twisted into spiral shape with the helix angle ≦68.2°, thread pitch ≦2.5 times of the width of the flat tubes 300.

The working principles of the embodiment: heat exchange medium such as refrigerant enters from the inlet 400 on the bottom end of the first collecting tube 100, flows horizontally to the second collecting tube 200 through the flat tubes 300, and then flows out from the outlet 500.

Embodiment 8

The microchannel, all-aluminium single flat tube in this embodiment forms effective refrigerant flow channel and heat exchange space through bending and then is welded with high-efficiency heat exchange fins to form a single-loop single-row microchannel heat exchanger. It is used as an evaporator in cooling-only system. As shown in FIG. 18, the heat exchange part of the heat exchanger is formed by a flat tube 300 through multiple reciprocated bending vertically. The fins 800 which are snake-shaped folding type are set between adjacent two flat tubes 300, as shown in FIGS. 14 and 15, wherein the window angle of fins at the wind speed of 2 M/s A is 22°-45°, preferably 27°-33°; the pitch H of fins at the wind speed of 2 M/s is 2.0 mm-5.0 mm, preferably 2.2 mm-3.6 mm. When the abovementioned heat exchanger is applied in heat exchange systems without air blowers, windowless design is adopted and pitch H for the fins 800 is equal to the height of the fins 800.

The flat tube 300 is provided with the inlet 400 of heat exchange medium on one end and the outlet 500 of heat exchange medium on the other end.

The working principles of the embodiment: heat exchange medium such as refrigerant enters into the flat tube 300 from the inlet 400, and then flows out from the outlet 500 after heat exchange by the flat tube 300.

Embodiment 9

The heat exchanger with microchannel, all-aluminium single flat tube welding structure in this embodiment is a single-loop single-row heat exchanger. It is used as an evaporator in water-cooling system. As shown in FIGS. 19-21, the heat exchange part of the heat exchanger is formed by a flat tube 300 through multiple reciprocated bending vertically. The flat tube 300 is provided with the inlet 400 of heat exchange medium on one end and the outlet 500 of heat exchange medium on the other end. The flat tube 300 is twisted into spiral shape with the helix angle ≦68.2°, thread pitch ≦2.5 times of the width of the flat tube 300.

The working principles of the embodiment: heat exchange medium such as refrigerant enters into the flat tube 300 from the inlet 400, and then flows out from the outlet 500 after heat exchange by the flat tube 300.

Embodiment 10

The heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure in this embodiment is a double-loop single-row parallel-flow heat exchanger. It is used as a condenser for housing or commercial purposes. As shown in FIG. 22, the heat exchanger is comprised of a first collecting tube 100, a second collecting tube 200 and several flat tubes 300 linking the first collecting tube 100 and the second collecting tube 200, wherein the flat tubes 300 are composed of extruded thin-wall aluminium profiles with the thickness of the flat tubes 300 from 1.0 mm to 2.0 mm.

In this embodiment, several flat tubes 300 are arranged in one row at horizontal intervals in parallel mode; the first collecting tube 100 is located on one side of the whole heat exchanger, the second collecting tube 200 is on the other side of the whole heat exchanger; the inlet 400 and outlet 500 of heat exchange medium are located on the top end and bottom end of the first collecting tube 100.

The working principles of the embodiment: heat exchange medium such as refrigerant enters into the top side of the first collecting tube 100 from the inlet 400, flows into the top side of the second collecting tube 200 through the flat tubes 300 of the whole heat exchanger, and then flows downwards along the second collecting tube 200 and returns to the bottom side of the first collecting tube 100 through the flat tubes 300 at the bottom of the heat exchanger, and finally flows out from the outlet 500.

Embodiment 11

The microchannel, all-aluminium single flat tube in this embodiment forms an effective refrigerant flow channel and heat exchange space through bending and then is welded with high-efficiency heat exchange fins to form a single-loop single-row microchannel heat exchanger. It is used as a condenser in cooling-only system. As shown in FIGS. 23 and 24, the heat exchange part of the heat exchanger is formed by a flat tube 300 through multiple reciprocated bending horizontally. The fins 800 which are snake-shaped folding type are set between adjacent two flat tubes 300, as shown in FIGS. 14 and 15, wherein the window angle of fins at the wind speed of 2M/s A is 22°-45°, preferably 27°-33°; the pitch H of fins at the wind speed of 2M/s is 2.0 mm-5.0 mm, preferably 2.2 mm-3.6 mm. When the abovementioned heat exchanger is applied in heat exchange systems without air blowers, windowless design is adopted and pitch H for the fins 800 is equal to the height of the fins 800.

The flat tube 300 is provided with the inlet 400 of heat exchange medium on one end and the outlet 500 of heat exchange medium on the other end.

The working principles of the embodiment: heat exchange medium such as refrigerant enters into the flat tube 300 from the inlet 400, and then flows out from the outlet 500 after heat exchange by the flat tube 300.

Embodiment 12

The heat exchanger with microchannel, all-aluminium single flat tube welding structure in this embodiment is a single-loop single-row heat exchanger. It is used as a condenser in water-cooling system. As shown in FIG. 26, the heat exchange part of the heat exchanger is formed by a flat tube 300 through multiple reciprocated bending horizontally. The flat tube 300 is provided with the inlet 400 of heat exchange medium on one end and the outlet 500 of heat exchange medium on the other end. The flat tube 300 is twisted into spiral shape with the helix angle ≦68.2°, thread pitch ≦2.5 times of the width of the flat tube 300.

The working principles of the embodiment: heat exchange medium such as refrigerant enters into the flat tube 300 from the inlet 400, and then flows out from the outlet 500 after heat exchange by the flat tube 300.

Embodiment 13

The heat exchanger with microchannel, all-aluminium flat tube welding structure in this embodiment is a non-inverting parallel connection single-loop single-row heat exchanger. It is used as an evaporator. As shown in FIGS. 27-29, the heat exchange part of the heat exchanger is formed by two flat tubes 300 through multiple reciprocated bending horizontally and vertically. The fins 800 which are snake-shaped folding type are set between adjacent two flat tubes 300, as shown in FIGS. 14 and 15, wherein the window angle of fins at the wind speed of 2 M/s A is 22°-45°, preferably 27°-33°; the pitch H of fins at the wind speed of 2 M/s is 2.0 mm-5.0 mm, preferably 2.2 mm-3.6 mm. When the abovementioned heat exchanger is applied in heat exchange systems without air blowers, windowless design is adopted and pitch H for the fins 800 is equal to the height of the fins 800.

The two flat tubes 300 are provided with the inlet 400 of heat exchange medium in parallel connection on one end and the outlet 500 of heat exchange medium in parallel connection on the other end.

The working principles of the embodiment: heat exchange medium such as refrigerant enters into the two flat tubes 300 from the inlet 400, and then flows out from the outlet 500 after heat exchange by the two flat tubes 300.

Embodiment 14

The heat exchanger with microchannel, all-aluminium flat tube welding structure in this embodiment is a non-inverting parallel connection single-loop single-row heat exchanger. It is used as a condenser. As shown in FIG. 30, the heat exchange part of the heat exchanger is formed by two flat tubes 300 through multiple reciprocated bending horizontally and vertically. The fins 800 which are snake-shaped folding type are set between adjacent two flat tubes 300, as shown in FIGS. 14 and 15, wherein the window angle of fins at the wind speed of 2 M/s A is 22°-45°, preferably 27°-33°; the pitch H of fins at the wind speed of 2 M/s is 2.0 mm-5.0 mm, preferably 2.2 mm-3.6 mm. When the abovementioned heat exchanger is applied in heat exchange systems without air blowers, windowless design is adopted and pitch H for the fins 800 is equal to the height of the fins 800.

The two flat tubes 300 are provided with the inlet 400 of heat exchange medium in parallel connection on one end and the outlet 500 of heat exchange medium in parallel connection on the other end.

The working principles of the embodiment: heat exchange medium such as refrigerant enters into the two flat tubes 300 from the inlet 400, and then flows out from the outlet 500 after heat exchange by the two flat tubes 300.

Embodiment 15

The heat exchanger with microchannel, parallel flow, and all-aluminum flat tube welding structure in this embodiment is a double-row double-exchange parallel-flow heat exchanger. It is used as a heat pump type evaporator or condenser. As shown in FIGS. 31˜33, the heat exchanger is comprised of a first collecting tube 100, a second collecting tube 200, a third collecting tube 100a, a fourth collecting tube 200a and several flat tubes 300, wherein the flat tubes 300 are composed of extruded thin-wall aluminum profiles, the thickness of the flat tubes in heat pump type heat exchanger is 1.3 mm-2.0 mm preferably, and the section of single hole flow channel in the perforated microchannel in the flat tubes is 0.36 mm²-1.00 mm² preferably. Several flat tubes 300 are arranged in two rows at vertical intervals in parallel mode, wherein the upper end of the first row of the flat tubes 300 is connected with the first collecting tube 100, the lower end of the first row of the flat tubes 300 is connected with the second collecting tube 200, the upper end of the second row of the flat tubes 300 is connected with the third collecting tube 100a, the lower end of the second row of the flat tubes 300 is connected with the fourth collecting tube 200a. The first collecting tube 100 and the third collecting tube 100a are parallel to each other and facing the same direction of the two rows of the flat tubes 300, on the top of the whole heat exchanger, wherein the two tubes are not directly connected, and only connected by the flat tubes 300 according to the flow direction of heat exchange medium. The second collecting tube 200 and the fourth collecting tube 200a are parallel to each other and facing the same direction of the two rows of the flat tubes 300, on the top of the whole heat exchanger, wherein the two tubes are communicated according to the flow direction of heat exchange medium.

The fins 800 which are snake-shaped folding type are set between adjacent two flat tubes 300, as shown in FIGS. 14 and 15, wherein the window angle of fins at the wind speed of 1.5 M/s-2 M/s A is 22°-45°, preferably 27°-33°. The pitch H of fins at the wind speed of 2 M/s is 2.0 mm-5.0 mm, 2.2 mm-2.8 mm preferably in high-efficiency heat exchanger, 2.6 mm-3.0 mm preferably when stressing both high-efficiency heat exchange and dehumidification, 3.6 mm-5.0 mm preferably in freezing & refrigeration or dehumidification-only or sand-dust regions. When the abovementioned heat exchanger is applied in heat exchange systems without air blowers, windowless design is adopted and pitch H for the fins 800 is equal to the height of the fins 800.

As shown in FIGS. 34 and 35, when the heat exchanger in this embodiment is applied in refrigeration places, there are two inlets 400 of heat exchange medium which are arranged on the right side of the first collecting tube 100. There are three outlets 500 of heat exchange medium which are placed on the left side of the first collecting tube 100 and distributed at equal intervals. A baffle 110 is set between the right side and left side of the first collecting tube 100, and an orifice plate 700 is set between the right side and left side of the second collecting tube 200, wherein the orifice plate 700 is provided with orifices 710. A baffle 210a is configured between the left side and right side of the fourth collecting tube 200a. The baffle 210a, orifice plate 700 and baffle 110 are all in the same plane. The right side of the second collecting tube 200 and that of the fourth collecting tube 200a are directly connected, such as through small holes (not shown in the drawings). The left side of the second collecting tube 200 and that of the fourth collecting tube 200a are directly collected, such as through small holes (not shown in the drawings). The working principles of the embodiment during refrigeration: heat exchange medium enters into the right side of the first collecting tube 100 through two inlets 400, and then flows downwards to the right side of the second collecting tube 200 along part of the flat tubes 300. One part of liquid phase entering into the right side of the second collecting tube 200 flows into the left side of the second collecting tube 200 through the orifices 710 in the orifice plates 700 so as to balance the gas and liquid phases on the left side of the second collecting tube 200, the other part of liquid phase flows into the right side of the fourth collecting tube 200a transversely. The liquid phase entering into the right side of the fourth collecting tube 200a flows upwards into the right side of the third collecting tube 100a along part of flat tubes 300, while the liquid phase entering into the right side of the third collecting tube 100a axially flows into the left side of the third collecting tube 100a through the third collecting tube 100a, and then flows into the left side of the fourth collecting tube 200a along part of flat tubes 300. At this time, the heat exchange medium flowing into the left side of the fourth collecting tube 200a is gas and liquid phases. Under the action of gravity, the two phases are difficult to be divided into layers. The gas and liquid phases then transversely flow into the left side of the second collecting tube 200, and flow upwards into the left side of the first collecting tube 100 along part of flat tubes after mixing with the liquid from orifice plates 700, and then flow out from the three outlets 500. Since the orifice plates 700 are set in the second collecting tube 200 and area of the superheat degree for the entire heat exchanger is small (see FIG. 36) compared to the existing technology, close to a small area of the outlet 500 only, high-efficiency conversion of energy in the parallel-flow heat exchanger system can be realized.

As shown in FIGS. 37 and 38, when the heat exchanger in this embodiment is applied in refrigeration places, there are three inlets 400 of heat exchange medium which are arranged on the left side of the first collecting tube 100 and distributed at equal intervals. There are two outlets 500 of heat exchange medium which are placed on the right side of the first collecting tube 100. A baffle 110 is set between the right side and left side of the first collecting tube 100, and an orifice plate 700 is set between the right side and left side of the second collecting tube 200, wherein the orifice plate 700 is provided with orifices 710. A baffle 210a is configured between the left side and right side of the fourth collecting tube 200a. The baffle 210a, orifice plate 700 and baffle 110 are all in the same plane. The right side of the second collecting tube 200 and that of the fourth collecting tube 200a are directly connected, such as through small holes (not shown in the drawings). The left side of the second collecting tube 200 and that of the fourth collecting tube 200a are directly collected, such as through small holes (not shown in the drawings). The working principles of the embodiment during heating: heat exchange medium enters into the left side of the first collecting tube 100 through three inlets 400, and then flows downwards to the left side of the second collecting tube 200 along part of the flat tubes 300. One part of gas phase entering into the right side of the second collecting tube 200 flows into the right side of the second collecting tube 200 through the orifices 710 in the orifice plates 700 so as to balance the gas and liquid phases on the right side of the second collecting tube 200, the other part of gas phase flows into the left side of the fourth collecting tube 200a transversely. The gas phase entering into the left side of the fourth collecting tube 200a flows upwards into the left side of the third collecting tube 100a along part of flat tubes 300, while the gas phase entering into the left side of the third collecting tube 100a axially flows into the right side of the third collecting tube 100a through the third collecting tube 100a, and then flows into the right side of the fourth collecting tube 200a along part of flat tubes 300. At this time, the heat exchange medium flowing into the left side of the fourth collecting tube 200a is gas and liquid phases. Under the action of gravity, the two phases are difficult to be divided into layers. The gas and liquid phases then transversely flow into the right side of the second collecting tube 200, and flow upwards into the right side of the first collecting tube 100 along part of flat tubes after mixing with the gas from orifice plates 700, and then flow out from the two outlets 500. Since the orifice plates 700 are set in the second collecting tube 200 and area of the supercooling degree for the whole heat exchanger is small (see FIG. 37) compared to the existing technology, close to a small area of the outlet 500 only, high-efficiency conversion of energy in the parallel-flow heat exchanger system can be realized.

The heat exchanger can be also horizontally placed: the collecting tubes, flat tubes and fins form a plane parallel to the ground during system installation, this design solves the problem of gas-liquid separation caused by gravity of refrigerant in the heat exchanger, and the condensate water discharge problem can be addressed by means of hydrophilic treatment of fins of the parallel-flow heat exchanger fin+self gravity of condensate water.

Embodiment 16

The heat exchanger with microchannel, parallel flow, and all-aluminum flat tube welding structure in this embodiment is a double-row double-exchange parallel-flow heat exchanger. It is used as an evaporator. As shown in FIGS. 40-41, the heat exchanger is comprised of a first collecting tube 100, a second collecting tube 200 and several flat tubes 300 with thickness of the flat tubes 300 from 1.6 mm to 2.0 mm. Each flat tube 300 is bent into a U shape and each U-shaped flat tube is arranged into one row at vertical intervals in parallel mode. Both ends of each U-shaped flat tube are connected with the first collecting tube 100 and the second collecting tube 200, wherein the first collecting tube 100 and the second collecting tube 200 are parallel to each other and located on the top of the whole heat exchanger. The two tubes (100, 200) are not directly connected, and only connected by the flat tubes 300 according to the flow direction of heat exchange medium. The fins 800 which are snake-shaped folding type are set between two adjacent flat tubes 300, as shown in FIGS. 14 and 15, wherein the window angle of fins at the wind speed of 2 M/s A is 22°-45°, preferably 27°-33°; the pitch H of fins at the wind speed of 2 M/s is 2.0 mm-5.0 mm, preferably 2.2 mm-3.6 mm. When the abovementioned heat exchanger is applied in heat exchange systems without air blowers, windowless design is adopted and pitch H for the fins 800 is equal to the height of the fins 800. The inlet 400 and outlet 500 are alternately set on the first collecting tube 100.

The working principles of this embodiment: heat exchange medium flows into the left side of the first collecting tube 100 through the inlet 400, and flows into the left side of the second collecting tube 200 from the left side of the whole heat exchanger; the heat exchange medium entering into the second collecting tube 200 axially flows into the right side of the second collecting tube 200 along the second collecting tube 200, and then flows into the right side of the first collecting tube 100 from the right side of the whole heat exchanger, and finally flows out from the outlet 500.

Embodiment 17

The heat exchanger in this embodiment is basically the same as that in Embodiment 16. As shown in FIGS. 43-45, the flat tubes 300 are twisted into spiral shapes with the helix angle ≦68.2°, thread pitch ≦2.5 times of the width of the flat tubes 300. The fins 800 are not provided between two adjacent flat tubes 300.

Embodiment 18

The heat exchanger with microchannel, parallel flow, and all-aluminum flat tube welding structure in this embodiment is a double-row double-exchange parallel-flow heat exchanger. It is used as an evaporator or condenser. As shown in FIG. 46, the heat exchanger is comprised of a first collecting tube 100, a second collecting tube 200, a third collecting tube 100a, a fourth collecting tube 200a and several flat tubes 300, wherein the flat tubes 300 are composed of extruded thin-wall aluminum profiles, the thickness of the flat tubes 300 is 1.6 mm-2.5 mm. Several flat tubes 300 are arranged in two rows at vertical intervals in parallel mode, wherein the upper end of the first row of the flat tubes 300 is connected with the first collecting tube 100, the lower end of the first row of the flat tubes 300 is connected with the second collecting tube 200, the upper end of the second row of the flat tubes 300 is connected with the third collecting tube 100a, the lower end of the second row of the flat tubes 300 is connected with the fourth collecting tube 200a. The first collecting tube 100 and the third collecting tube 100a are parallel to each other and facing the same direction, on the top of the whole heat exchanger; the second collecting tube 200 and the fourth collecting tube 200a are parallel to each other and facing the same direction of the two rows of the flat tubes 300, at the bottom of the heat exchanger. The outlet is set on one end of the third collecting tube 100a. The inlet 400 and outlet 500 are located on the same side of the top of the whole heat exchanger. Baffles 110, 110a are configured in the middle of the first collecting tube 100 and the third collecting tube 100a. The inlet 400 of heat exchange medium is set on one end of the first collecting tube 100. The baffles 110, 110a isolate the flow channel of the whole heat exchanger into the first loop 610, the second loop 620, the third loop 630 and the fourth loop 640, wherein the side of the first collecting tube 100 and the third collecting tube 100a away from the inlet 400 and outlet 500 is directly connected through small holes 900, the second collecting tube 200 and the fourth collecting tube 200a are not directly connected.

The working principles of this embodiment: the heat exchange medium enters into the side of the first collecting tube 100 close to the inlet 400 through the inlet 400, and then flows downwards into one side of the second collecting tube 200 along the first loop 610 under the action of the baffle 110; the heat exchange medium flowing into one side of the second collecting tube 200 axially flows into the other side of the second collecting tube 200 along the second collecting tube 200, and then flows upwards to the side of the first collecting tube 100 away from the inlet 400 through the second loop 620; the heat exchange medium flowing into the side of the first collecting tube 100 away from the inlet 400 flows into the side of the third collecting tube 100a away from the outlet 500 through small holes 900; the heat exchange medium entering into the side of the third collecting tube 100a away from the outlet 500 flows downwards into one side of the fourth collecting tube 200a along the flat tubes 300 in the third loop 630 due to the blocking of the baffle 110a, and the heat exchange medium flowing into one side of the fourth collecting tube 200a axially flows into the other side of the fourth collecting tube 200a along the fourth collecting tube 200a, afterwards, flows upwards into the side of the third collecting tube 100a close to the outlet 500 through the flat tubes 300 in the fourth loop 640, and finally flows out from the outlet 500.

The heat exchanger can be also horizontally placed: the collecting tubes, flat tubes and fins form a plane parallel to the ground when system installation, this design solves the problem of gas-liquid separation caused by gravity of refrigerant in the heat exchanger, and condensate water discharge problem can be addressed by means of hydrophilic treatment of fins of the parallel-flow heat exchanger fin+self gravity of condensate water.

Embodiment 19

The heat exchanger with microchannel, parallel flow, and all-aluminum flat tube welding structure in this embodiment is a double-row double-exchange parallel-flow heat exchanger. It is used as an evaporator or condenser. As shown in FIG. 47, the heat exchanger in this embodiment is comprised of a first collecting tube 100, a second collecting tube 200, a third collecting tube 100a, a fourth collecting tube 200a and several flat tubes 300, wherein the flat tubes 300 are composed of extruded thin-wall aluminum profiles, the thickness of the flat tubes is 1.6 mm-2.5 mm. Several flat tubes 300 are arranged in two rows at vertical intervals in parallel mode, wherein the upper end of the first row of the flat tubes 300 is connected with the first collecting tube 100, the lower end of the first row of the flat tubes 300 is connected with the second collecting tube 200, the upper end of the second row of the flat tubes 300 is connected with the third collecting tube 100a, the lower end of the second row of the flat tubes 300 is connected with the fourth collecting tube 200a. The first collecting tube 100 and the third collecting tube 100a are parallel to each other and facing the same direction of the two rows of the flat tubes 300, on the top of the whole heat exchanger; the second collecting tube 200 and the fourth collecting tube 200a are parallel to each other and facing the same direction of the two rows of the flat tubes 300, at the bottom of the heat exchanger. The outlet is set on one end of the third collecting tube 100a. The inlet 400 and outlet 500 are located on the same side of the top of the whole heat exchanger. Baffles 110, 110a are configured in the middle of the first collecting tube 100 and the third collecting tube 100a. The inlet 400 of heat exchange medium is set on one end of the first collecting tube 100. The baffles 110, 110a isolate the flow channel of the whole heat exchanger into the first loop 610, the second loop 620, the third loop 630 and the fourth loop 640, wherein the side of the first collecting tube 100 and the third collecting tube 100a away from the inlet 400 and outlet 500 is directly connected through small holes 900, the second collecting tube 200 and the fourth collecting tube 200a are not directly connected. Three orifice plates 700 are set in the second collecting tube 200 and the fourth collecting tube 200a respectively with each orifice plate 700 provided with the orifices 710.

The working principles of this embodiment: the heat exchange medium enters into the side of the first collecting tube 100 close to the inlet 400 through the inlet 400, and then flows downwards into one side of the second collecting tube 200 along the first loop 610 under the action of the baffle 110; the heat exchange medium flowing into one side of the second collecting tube 200 axially flows into the other side of the second collecting tube 200 along the second collecting tube 200 after throttling by the three orifice plates 700 in the second collecting tube 200, and then flows upwards to the side of the first collecting tube 100 away from the inlet 400 through the second loop 620; the heat exchange medium flowing into the side of the first collecting tube 100 away from the inlet 400 flows into the side of the third collecting tube 100a away from the outlet 500 through small holes 900; the heat exchange medium entering into the side of the third collecting tube 100a away from the outlet 500 flows downwards into one side of the fourth collecting tube 200a along the flat tubes 300 in the third loop 630 due to the blocking of the baffle 110a, and the heat exchange medium flowing into one side of the fourth collecting tube 200a axially flows into the other side of the fourth collecting tube 200a along the fourth collecting tube 200a after throttling by the three orifice plates 700 in the second collecting tube 200, afterwards, flows upwards into the side of the third collecting tube 100a close to the outlet 400 through the flat tubes 300 in the fourth loop 640, finally flows out from the outlet 400.

The heat exchanger can be also horizontally placed: the collecting tubes, flat tubes and fins form a plane parallel to the ground when system installation, this design solves the problem of gas-liquid separation caused by gravity of refrigerant in the heat exchanger, and condensate water discharge problem can be addressed by means of hydrophilic treatment of fins of the parallel-flow heat exchanger fin+self gravity of condensate water.

Embodiment 20

The heat exchanger with microchannel, parallel flow, and all-aluminum flat tube welding structure in this embodiment is a double-row double-exchange parallel-flow heat exchanger. It is used as an evaporator or condenser. As shown in FIG. 48, the heat exchanger in this embodiment is comprised of a first collecting tube 100, a second collecting tube 200, a third collecting tube 100a, a fourth collecting tube 200a and several flat tubes 300, wherein the flat tubes 300 are composed of extruded thin-wall aluminum profiles, the thickness of the flat tubes is 1.6 mm-2.5 mm. Several flat tubes 300 are arranged in two rows at vertical intervals in parallel mode, wherein the upper end of the first row of the flat tubes 300 is connected with the first collecting tube 100, the lower end of the first row of the flat tubes 300 is connected with the second collecting tube 200, the upper end of the second row of the flat tubes 300 is connected with the third collecting tube 100a, the lower end of the second row of the flat tubes 300 is connected with the fourth collecting tube 200a. The first collecting tube 100 and the third collecting tube 100a are parallel to each other and facing the same direction of the two rows of the flat tubes 300, on the top of the whole heat exchanger; the second collecting tube 200 and the fourth collecting tube 200a are parallel to each other and facing the same direction of the two rows of the flat tubes 300, at the bottom of the heat exchanger.

The first collecting tube 100 and the third collecting tube 100a are not directly connected, and the second collecting tube 200 and the fourth collecting tube 200a are partially connected in a direct manner, in this way, the first collecting tube 100, the second collecting tube 200, the third collecting tube 100a, the fourth collecting tube 200a and flat tubes 300 constitute the whole heat exchange flow channel of the embodiment. The inlet 400 and outlet 500 of heat exchange medium for the whole heat exchange flow channel are set on the side tube wall of the first collecting tube 100.

A baffle 110 and a baffle 210 are set in the first collecting tube 100 and the second collecting tube 200 respectively, wherein the baffles 110 and 210 isolate the flat tubes 300 between the first collecting tube 100 and the second collecting tube 200 into N1-row flow channel and N2+N3-row flow channel, the baffles 110 and 210 are in the same plane.

A baffle 210a is set inside the fourth collecting tube 210a, an orifice plate 700 is set in side the third collecting tube 110a, wherein the baffle 210a and orifice plate 700 isolate the flat tubes 300 between the third collecting tube 100a and the fourth collecting tube 200a into N1+N2-row flow channel and N3-row flow channel. The N1-row flow channel in the second collecting tube 200 and the N1+N2-row flow channel in the fourth collecting tube 210a are communicated through the small holes 910 between the second collecting tube 200 and the fourth collecting tube 210a. The N2+N3-row flow channel in the second collecting tube 200 and the N3-row flow channel in the fourth collecting tube 210a are communicated through small holes 920 between the second collecting tube 200 and the fourth collecting tube 210a. The flat tubes 300 of the N1-row flow channel between the first collecting tube 100 and the second collecting tube 200 constitute the first loop 610. The flat tubes 300 of the N1+N2-row flow channel between the third collecting tube 100a and the fourth collecting tube 200a form the second loop 620. The flat tubes 300 of the N3-row flow channel between the third collecting tube 100a and the fourth collecting tube 200a constitute the third loop 630. The flat tubes 300 of N2+N3-row flow channel between the first collecting tube 100 and the second collecting tube 200 constitute the fourth loop 640.

The flow direction of the refrigerant in the whole flow channel is as below: enter into the N1-row flow channel of the first collecting tube 100 through the inlet 400, flow downwards into the N1-row flow channel of the second collecting tube 200 along the flat tubes 130 of the first loop, and then transversely flow into the N1+N2-row flow channel of the fourth collecting tube 200a through the small holes 910, afterwards rise to the N1+N2-row flow channel of the third collecting tube 100a along the flat tubes 300 of the second loop. The refrigerant entering into the N1+N2-row flow channel of the third collecting tube 100a axially flows into the N3-row flow channel of the third collecting tube 100a along the third collecting tube 100a through the orifice plates 700, and then flows downwards into the N3-row flow channel of the fourth collecting tube 100a along the flat tube 300 of the third loop 630, afterwards, transversely flows into the N2+N3-row flow channel of the second collecting tube 200 through the small holes 920. The refrigerant flowing into the N2+N3-row flow channel of the second collecting tube 200 flows upwards into the N2+N3-row flow channel of the first collecting tube 100 along the flat tubes 300 in the fourth loop 640, and finally flows out from the outlet 500.

The flowing process of the whole refrigerant includes four loops, namely the first loop 610, the second loop 620, the third loop 630 and the fourth loop 640. The volumes of the four loops of the refrigerant during flowing are in the ascending trend, namely, the volumes of various flow channels are: the first loop 610<the second loop 620<the third loop 630<the fourth loop 640, wherein the volume of the second loop 620 is more than 40-50% of that of the first loop 610, the volume of the third loop 630 is more than 40-50% of that of the second loop 620, the volume of the fourth loop 640 is more than 40-50% of that of the third loop 630 and the volume of the fourth loop 640 is 2.5 times of that of the first loop 610.

As shown in FIG. 48, the length of the refrigerant axially flowing in the fourth collecting tube 200a along the fourth collecting tube 200a is N1+N2 at most, while the axially flowing length in the third collecting tube 110a is N2+N3. Since the length of N3 is more than N1, the length of the refrigerant axially flowing in the third collecting tube 100a is more than the axially flowing length in the fourth collecting tube 200a along the fourth collecting tube 200a.

The length of the refrigerant axially flowing in the third collecting tube 110a can be set as long as possible, taking up 70% of the summation of the refrigerant axially flowing length in the first collecting tube 100 and the third collecting tube 100a along the first collecting tube 100 and the third collecting tube 100a as well as the axially flowing length in the second collecting tube 200 and the fourth collecting tube 200a along the second collecting tube 200 and the fourth collecting tube 200a; while the axially flowing length in the fourth collecting tube 200a along the fourth collecting tube 200a can be as short as possible, accounting for 30% of the summation of the refrigerant axially flowing length in the first collecting tube 100 and the third collecting tube 100a along the first collecting tube 100 and the third collecting tube 100a as well as the axially flowing length in the second collecting tube 200 and the fourth collecting tube 200a along the second collecting tube 200 and the fourth collecting tube 200a.

The heat exchanger can be also horizontally placed: the collecting tubes, flat tubes and fins form a plane parallel to the ground when system installation, this design solves the problem of gas-liquid separation caused by gravity of refrigerant in the heat exchanger, and condensate water discharge problem can be addressed by means of hydrophilic treatment of fins of the parallel-flow heat exchanger fin+self gravity of condensate water.

Embodiment 21

The heat exchanger with microchannel, parallel flow, and all-aluminum flat tube welding structure in this embodiment is a double-row double-exchange parallel-flow heat exchanger. It is used as an evaporator or condenser. As shown in FIG. 49, the heat exchanger in this embodiment is comprised of a first collecting tube 100, a second collecting tube 200, a third collecting tube 100a, a fourth collecting tube 200a and several flat tubes 300, wherein the flat tubes 300 are composed of extruded thin-wall aluminum profiles, the thickness of the flat tubes is 1.6 mm-2.5 mm. Several flat tubes 300 are arranged in two rows at vertical intervals in parallel mode, wherein the upper end of the first row of the flat tubes 300 is connected with the first collecting tube 100, the lower end of the first row of the flat tubes 300 is connected with the second collecting tube 200, the upper end of the second row of the flat tubes 300 is connected with the third collecting tube 100a, the lower end of the second row of the flat tubes 300 is connected with the fourth collecting tube 200a. The first collecting tube 100 and the third collecting tube 100a are parallel to each other and facing the same direction of the two rows of the flat tubes 300, on the top of the whole heat exchanger; the second collecting tube 200 and the fourth collecting tube 200a are parallel to each other and facing the same direction of the two rows of the flat tubes 300, at the bottom of the heat exchanger.

The first collecting tube 100 and the third collecting tube 100a are not directly connected, and the second collecting tube 200 and the fourth collecting tube 200a are partially connected in a direct manner, in this way, the first collecting tube 100, the second collecting tube 200, the third collecting tube 100a, the fourth collecting tube 200a and flat tubes 300 constitute the whole heat exchange flow channel of the embodiment. The inlet 400 of heat exchange medium for the whole heat exchange flow channel is set on one end of the third collecting tube 100a, and the outlet 500 is set on one end of the first collecting tube 100.

Two baffles 210 and 220 are set in the second collecting tube 200, wherein the baffles 210 and 220 isolate the second collecting tube 200 into N1-row flow channel, N2-row flow channel and N3+N4-row flow channel; a baffle 110 and an orifice plate 700 are set in the first collecting tube 100, wherein the baffle 110 and orifice plate 700 isolate the first collecting tube 100 into N1-row flow channel, N2-row flow channel and N3+N4-row flow channel.

Two baffles 210 and 220 are set in the fourth collecting tube 200a, wherein the two baffles 210 and 220 isolate the fourth collecting tube 100a into N1-row flow channel, N2+N3-row flow channel and N4-row flow channel; a baffle 110 and an orifice plate 700 are set in the third collecting tube 100a, wherein the baffle 110 and orifice plate 700 isolate the third collecting tube 100a into N1-row flow channel, N2+N3-row flow channel and N4-row flow channel. A guide tube 410 is inserted into the third collecting tube 100a. Its entrance is connected with the inlet 400 and an exit is located within the N1-row flow channel of the third collecting tube 100a.

The N1-row flow channel in the second collecting tube 200 and the N1-row flow channel in the fourth collecting tube 200a are communicated through the small holes 910 between the second collecting tube 200 and the fourth collecting tube 200a. The N2-row flow channel in the second collecting tube 200 and the N2+N3-row flow channel in the fourth collecting tube 200a are communicated through small holes 920 between the second collecting tube 200 and the fourth collecting tube 200a. The N3+N4-row flow channel in the second collecting tube 200 and the N4-row flow channel in the fourth collecting tube 200a are communicated through the small holes 930 between the second collecting tube 200 and the fourth collecting tube 200a.

The flat tubes 300 of the N1-row flow channel between the third collecting tube 100a and the fourth collecting tube 200a constitute the first loop 610. The flat tubes 300 of the N1-row flow channel between the second collecting tube 200 and the first collecting tube 100 form the second loop 620. The flat tubes 300 of the N2-row flow channel between the first collecting tube 100 and the second collecting tube 200 constitute the third loop 630. The flat tubes 300 of N2+N3-row flow channel between fourth collecting tube 200a and the third collecting tube 100a constitute the fourth loop 640. The flat tubes 300 of the N4-row flow channel between the third collecting tube 100a and the fourth collecting tube 200a form the fifth loop 650. The flat tubes 300 of the N4-row flow channel between the second collecting tube 200 and the first collecting tube 100 constitute the sixth loop 660.

The flow direction of the refrigerant in the whole flow channel is as below: enter into the guide tube 410 through the inlet 400, and then flow into the N1-row flow channel in the third collecting tube 100a from the guide tube 410, flow downwards to the N1-row flow channel of the fourth collecting tube 100a along the flat tube 230 of the first loop 610, afterwards, transversely flow into the N1-row flow channel of the second collecting tube 200 through small holes 122, and flow upwards into the N1-row flow channel of the first collecting tube 100 along the second loop 620. The refrigerant entering into the N1-row flow channel of the first collecting tube 100 axially flows along the first collecting tube 100, and then flows into the N2-row flow channel of the first collecting tube 100 through the orifice plates 700.

The refrigerant entering into the N2-row flow channel of the first collecting tube 100 flows into the N2-row flow channel of the second collecting tube 200 along the flat tubes of the third loop 630, and then transversely flows into the N2+N3-row flow channel of the fourth collecting tube 100a through the small holes 123. The refrigerant entering into the N2+N3-row flow channel of the fourth collecting tube 200a flows upwards into the N2+N3-row flow channel of the third collecting tube 100a along the flat tubes 300 of the fourth loop 640.

The refrigerant entering into the N2+N3-row flow channel of the third collecting tube 100a axially flows into the N4-row flow channel of the third collecting tube 100a along the third collecting tube 100a through the orifice plates 700, and then flows downwards into the N4-row flow channel of the fourth collecting tube 100a along the flat tube 300 of the fifth loop 650. Afterwards, the refrigerant entering into the N4-row flow channel of the fourth collecting tube 200a transversely flows into the N4-row flow channel of the second collecting tube 200 through the small holes 935, and then flows upwards into the N3+N4-row flow channel of the first collecting tube 100 along the flat tubes 300 in the sixth loop 660, and finally flows out from the outlet 500.

The flowing process of the whole refrigerant includes six loops, namely the first loop 610, the second loop 620, the third loop 630, the fourth loop 640, the fifth loop 650 and the sixth loop 660. The volumes of the six loops of the refrigerant during flowing are in the ascending trend, namely, the volumes of various loops are: the first loop 610<the second loop 620<the third loop 630<the fourth loop 640<the fifth loop 650<the sixth loop 660, wherein the volume of the second loop 620 is more than 40-50% of that of the first loop 610, the volume of the third loop 630 is more than 40-50% of that of the second loop 620, the volume of the fourth loop 640 is more than 40-50% of that of the third loop 630, the volume of the fifth loop 650 is more than 40-50% of that of the fourth loop 640, the volume of the sixth loop 660 is more than 40-50% of that of the fifth loop 650 and the volume of the sixth loop 660 is 2.5 times that of the first loop 610.

As shown in FIG. 49, the refrigerant almost does not make axial movement in the fourth collecting tube 200a and the second collecting tube 200, but the axially flowing length in the third collecting tube 100a along the third collecting tube 100a is N4+N3+N2+N1+N2+N3+N4, and the axially flowing length in the first collecting tube 100 along the first collecting tube 100 is N1+N2+N4. Therefore, it is far more than the length of the refrigerant axially flowing in the fourth collecting tube 200a and the second collecting tube 200.

The length of the refrigerant axially flowing in the third collecting tube 100a along the third collecting tube 100a and the axially flowing length in the first collecting tube 100 along the first collecting tube 100 can be set as long as possible, taking up 70% of the summation of the refrigerant axially flowing length in the first collecting tube 100 and the third collecting tube 100a along the first collecting tube 100 and the third collecting tube 100a as well as the axially flowing length in the second collecting tube 200 and the fourth collecting tube 200a along the second collecting tube 200 and the fourth collecting tube 200a; while the axially flowing length in the second collecting tube 200 and the fourth collecting tube 200a along the second collecting tube 200 and the fourth collecting tube 200a can be as short as possible, accounting for below 30% of the summation of the refrigerant axially flowing length in the first collecting tube 100 and the third collecting tube 100a along the first collecting tube 100 and the third collecting tube 100a as well as the axially flowing length in the second collecting tube 200 and the fourth collecting tube 200a along the second collecting tube 200 and the fourth collecting tube 200a.

To prevent overheating, the guide tube 410 is provided with holes in section of the N3-row flow channel and N4-row flow channel in the third collecting tube 100a. The holes supplement refrigerant to the N3-row flow channel and N4-row flow channel in the third collecting tube 100a, wherein the refrigerant amount supplemented to N4-row flow channel takes up 15-20% of the total amount of the refrigerant.

The heat exchanger can be also horizontally placed: the collecting tubes, flat tubes and fins form a plane parallel to the ground when system installation, this design solves the problem of gas-liquid separation caused by gravity of refrigerant in the heat exchanger, and condensate water discharge problem can be addressed by means of hydrophilic treatment of fins of the parallel-flow heat exchanger fin+self gravity of condensate water.

As shown in FIG. 50, the collecting tube a in the existing technology is round tube structure, forms high flow resistance after connection with the flat tubes 300 (See FIG. 51). The collecting tube adopted by the present invention in the abovementioned embodiments is D-shaped collecting tube b which can further reduce the loss of heat exchange medium in the collecting tube after connection with the flat tubes 300 (See FIG. 53).

As shown in FIGS. 54 and 55, to increase the intensity of the collecting tubes, reinforcing ribs b1 are configured on the three sides of tube walls of the D-shaped collecting tubes without connecting the flat tubes along collecting tube length direction alternately, with the intervals of two adjacent reinforcing ribs b1 being 25.4 mm, wherein the reinforcing ribs b1 are semicircular concave bars with the depth of 1 mm, radius of R1.

In these embodiments, the flat tubes are all Zinc-coated with the thickness of zinc coating of 12˜18 g/m² so as to prolong the service life.

The abovementioned heat exchanger with microchannel, parallel flow, all-aluminum flat tube welding structure can be applied in air conditioners for housing and commercial use, and many other specialized heat exchange systems, and in particular, in rooms and similar-purpose air conditioning systems, freezing and refrigeration systems, air conditioning systems for refrigeration and dehumidification, heat pump heating and water cooling/heating and air conditioning systems, computer cooling modules in IT industry and cooling systems equipment.

The abovementioned displays and describes the basic principles, main features and advantages of the present invention. The technical personnel in this art shall be aware that the embodiments and the specification above only explain the principles of the present invention and are not intended to limit the present invention in that the invention is subject to modifications and improvements, without departing from the spirit and scope of the present invention. Such modifications and improvements are intended to be within the protection scope of the present invention defined by the Claims and the equivalents attached.

Claims

1. A heat exchanger with microchannel, parallel flow, all-aluminium flat tube welding structure, characterized in that the heat exchange part of the heat exchanger is formed by flat tubes composed of extruded thin-wall aluminium profiles in parallel arrangement.

2. The heat exchanger as claimed in claim 1, characterized in that there is one or two flat tubes which form the heat exchange part of the heat exchanger by multiple reciprocated bending horizontally or vertically.

3. The heat exchanger as claimed in claim 1, characterized in that there are over two flat tubes which are arranged in one row at horizontal or vertical intervals in parallel mode, and the heat exchanger formed by such arrangement is placed vertically or horizontally or at an included angle of 15°˜25° with the horizontal ground; the heat exchanger further comprises a first collecting tube connecting one end of the over two flat tubes and a second collecting tube connecting the other end of the over two flat tubes, wherein one end of the flat tubes is the inlet of heat exchange medium and the other end of the flat tubes is the outlet of heat exchange medium.

4. The heat exchanger as claimed in claim 3, characterized in that when the length of the connecting tube with the inlet or outlet for the heat exchange medium is no less than 300 mm, the inlet or outlet of the heat exchange medium is multiple, the distance between two adjacent inlets of heat exchange medium or two adjacent outlets of heat exchange medium is less than 150 mm, and all inlets or outlets of the heat exchange medium are distributed at equal spacing.

5. The heat exchanger as claimed in claim 3, characterized in that several orifice plates are configured in the collecting tubes at certain intervals, each orifice plate being provided with an orifice; the spacing distance between the orifice plates is less than 80 mm.

6. The heat exchanger as claimed in claim 3, characterized in that the section of the collecting tubes is D-shaped; reinforcing ribs are configured on the three sides of tube walls of the D-shaped collecting tubes without connecting the flat tubes along collecting tube length direction, with the intervals of two adjacent reinforcing ribs being 25.4 mm.

7. The heat exchanger as claimed in claim 1, characterized in that there are over two flat tubes which are arranged in two rows at horizontal or vertical intervals in parallel mode, and the heat exchanger formed by such arrangement is placed vertically or horizontally or at an included angle of 15°˜25° with the horizontal ground; the heat exchanger further comprises a first collecting tube connecting one end of the first row of the flat tubes, a second collecting tube connecting the other end of the first row of the flat tubes, a third collecting tube connecting one end of the second row of the flat tubes, and a fourth collecting tube connecting the other end of the second row of the flat tubes; wherein the first collecting tube and the third collecting tube are facing the same direction of the two rows of the flat tubes, parallel to each other, and communicated according to the flow direction of heat exchange medium; the second collecting tube and the fourth collecting tube are facing the same direction of the two rows of the flat tubes, parallel to each other, and communicated according to the flow direction of heat exchange medium; one end of the flat tubes is the inlet of heat exchange medium and the other end of the flat tubes is the outlet of heat exchange medium.

8. The heat exchanger as claimed in claim 7, characterized in that when the length of the connecting tube with the inlet or outlet for the heat exchange medium is no less than 300 mm, the inlet or outlet of the heat exchange medium is multiple, the distance between two adjacent inlets of heat exchange medium or two adjacent outlets of heat exchange medium is less than 150 mm, and all inlets or outlets of the heat exchange medium are distributed at equal spacing.

9. The heat exchanger as claimed in claim 7, characterized in that several orifice plates are configured in the collecting tubes at certain intervals, each orifice plate being provided with an orifice; the spacing distance between the orifice plates is less than 80 mm.

10. The heat exchanger as claimed in claim 7, characterized in that the section of the collecting tubes is D-shaped; reinforcing ribs are configured on the three sides of tube walls of the D-shaped collecting tubes without connecting the flat tubes along collecting tube length direction, with the intervals of two adjacent reinforcing ribs being 25.4 mm.

11. The heat exchanger as claimed in claim 1, characterized in that there are over two U-shaped flat tubes which are arranged in one row at horizontal or vertical intervals in parallel mode, both ends of each U-shaped flat tube are connected by a first collecting tube and a second collecting tube respectively, the first and the second collecting tubes are parallel to each other and communicated according to the flow direction of heat exchange medium, wherein one end of the U-shaped flat tubes is the inlet of heat exchange medium, the other end of the flat tubes is the outlet of heat exchange medium.

12. The heat exchanger as claimed in claim 11, characterized in that when the length of the connecting tube with the inlet or outlet for the heat exchange medium is no less than 300 mm, the inlet or outlet of the heat exchange medium is multiple, the distance between two adjacent inlets of heat exchange medium or two adjacent outlets of heat exchange medium is less than 150 mm, and all inlets or outlets of the heat exchange medium are distributed at equal spacing.

13. The heat exchanger as claimed in claim 11, characterized in that the section of the collecting tubes is D-shaped; reinforcing ribs are configured on the three sides of tube walls of the D-shaped collecting tubes without connecting the flat tubes along collecting tube length direction, with the intervals of two adjacent reinforcing ribs being 25.4 mm.

14. The heat exchanger as claimed in claim 1, characterized in that the thickness of the flat tubes is 1.0 mm-2.5 mm.

15. The heat exchanger as claimed in claim 14, characterized in that the thickness of the flat tubes in cooling-only condensers is 1.0 mm-2.0 mm; the thickness of the flat tubes in cooling-only evaporators is 1.6 mm-2.5 mm; the thickness of the flat tubes in heat pump type indoor-outdoor heat exchangers is 1.3 mm-2.0 mm.

16. The heat exchanger as claimed in claim 14, characterized in that the flat tubes are twisted into spiral shape with the helix angle≦68.2°, thread pitch≦2.5 times of the width of the flat tubes.

17. The heat exchanger as claimed in claim 3, characterized in that baffles are set inside the collecting tubes to isolate the inside of the heat exchanger into several loops which are connected in series; the heat exchanger is an odd-loop single-row parallel-flow heat exchanger or an even-loop single-row parallel-flow heat exchanger; with regard to odd-loop single-row parallel-flow heat exchanger, the inlet and outlet of heat exchange medium are set on the ends of the first collecting tube and the second collecting tube respectively in diagonal distribution; when the heat exchanger is used as an evaporator, the inlet of the heat exchange medium is set at the bottom of the heat exchanger, while the outlet is set on the top of the heat exchanger; when the heat exchanger is used as a condenser, the inlet of the heat exchange medium is set on the top of the heat exchanger, the outlet is set at the bottom of the heat exchanger; in even-loop single-row parallel-flow heat exchanger, the inlet and outlet of the heat exchange medium are both located on the first collecting tube or the second collecting tube, and at the bottom of the heat exchanger.

18. The heat exchanger as claimed in claim 3, characterized in that baffles are set inside the collecting tubes to isolate the inside of the heat exchanger into several loops which are connected in series; the volume of the latter loop is 20-60% higher than the volume of the former loop along the heat exchange medium flow direction, but the volume of the last loop is no more than 2.5 times of the volume of the first loop.

19. The heat exchanger as claimed in claim 18, characterized in that a feeder for supplementing heat exchange medium to the last two loops is set on the two loops, wherein the heat exchange medium supplemented to the last loop is 15-20% of the weight of total heat exchange medium.

20. The heat exchanger as claimed in claim 18, characterized in that when the heat exchanger is a double-loop single-row parallel-flow heat exchanger, the volume of the first loop is 80% of the total volume of loops, and the volume of the second loop is 20% of the total volume of loops; when the heat exchanger is a three-loop single-row parallel-flow heat exchanger, the volume of the first loop is 55% of the total volume of loops, the volume of the second loop is 30% of the total volume of loops, and the volume of the third loop is 15% of the total volume of loops; when the heat exchanger is a four-loop single-row parallel-flow heat exchanger, the volume of the first loop is 40% of the total volume of loops, the volume of the second loop is 27% of the total volume of loops, the volume of the third loop is 20% of the total volume of loops, and the volume of the fourth loop is 13% of the total volume of loops; when the heat exchanger is a five-loop single-row parallel-flow heat exchanger, the volume of the first loop is 34% of the total volume of loops, the volume of the second loop is 24% of the total volume of loops, the volume of the third loop is 18% of the total volume of loops, the volume of the fourth loop is 13% of the total volume of loops, and the volume of the fifth loop is 13% of the total volume of loops; when the heat exchanger is a six-loop single-row parallel-flow heat exchanger, the volume of the first loop is 30% of the total volume of loops, the volume of the second loop is 20% of the total volume of loops, the volume of the third loop is 17% of the total volume of loops, the volume of the fourth loop is 14% of the total volume of loops, the volume of the fifth loop is 10% of the total volume of loops, and the volume of the sixth loop is 9% of the total volume of loops; the loops are isolated by baffles set in the first collecting tube or the second collecting tube.

21. The heat exchanger as claimed in claim 7, characterized in that the length of heat exchange medium axially flowing in the first collecting tube and the third collecting tube is more than that of heat exchange medium axially flowing in the second collecting tube and the fourth collecting tube, and the axially flowing length in the first collecting tube and the third collecting tube is as long as possible, while the axially flowing length in the second collecting tube and the fourth collecting tube is as short as possible.

22. The heat exchanger as claimed in claim 21, characterized in that the length of heat exchange medium axially flowing in the first collecting tube and the third collecting tube takes up over 70% of the length of heat exchange medium axially flowing in the first, second, third and fourth collecting tubes, while the length of the heat exchange medium axially flowing in the second collecting tube and the fourth collecting tube accounts for less than 30% of the length of heat exchange medium axially flowing in the first, second, third and fourth collecting tubes.

23. The heat exchanger as claimed in claim 7, characterized in that the first collecting tube and the third collecting tube are not directly interconnected, while the second collecting tube and the fourth collecting tube are directly interconnected via a part; the axially flowing of heat exchange medium is all completed in the first collecting tube and the third collecting tube, while the flowing of heat exchange medium between the first row of the flat tubes and the second row of the flat tubes is all completed via the part interconnecting the second collecting tube and the fourth collecting tube.

24. The heat exchanger as claimed in claim 1, characterized in that fins are set between the flat tubes, the window angle of fins at the wind speed of 1.5 M/s-2 M/s is 22°-45° and the pitch of fins is 2.0 mm-5.0 mm.

25. The heat exchanger as claimed in claim 24, characterized in that the pitch of fins is 2.2 mm-2.8 mm in high-efficiency heat exchanger; the pitch of fins is 2.6 mm-3.0 mm for both high-efficiency heat exchange and dehumidification use; the pitch of fins is 3.6 mm-5.0 mm for freezing and refrigeration or dehumidification-only use or in sand-dust regions; when the heat exchanger is applied in heat exchange systems without air blowers, windowless design is adopted, wherein the pitch of fins is equal to the height of fins.

26. The heat exchanger as claimed in claim 24, characterized in that the windowless length of fins is ≦0.3 mm.

27. The heat exchanger as claimed in claim 1, characterized in that the flat tubes along draft direction adopt A° design to guide condensate water of the heat exchanger, wherein 30°≦A°≦60°.

28. Application of the heat exchanger with microchannel, parallel flow, all-aluminium flat tube welding structure as claimed in claim 1 in air conditioners for housing and commercial use, and many other specialized heat exchange systems.