EP3165866A1 - Heat exchanger, in particular for high-pressure refrigerant - Google Patents

Abstract

The invention relates to a heat exchanger (1), in particular for high-pressure refrigerants, comprising a plurality of multichannel flat tubes (2) with intermediate lamellae, the ends of the multichannel flat tubes (2) being combined in one end region (11), characterized in that the multichannel flat tubes ( 2) at the two end regions (11) in connecting pieces (8) are combined and that adjacent Mehrkanalflachrohre (2) in several lamellae areas (9) between the connecting piece (8) to each other with spring blades (6, 7) spaced and thermally contacted, wherein the multi-channel flat tubes (2) are each formed meander-shaped.

Description

The invention relates to a heat exchanger, which is particularly suitable for heat transfer tasks between high pressure refrigerant and air.

High-pressure refrigerants are of interest for various applications in refrigeration. Especially for reasons of environmental compatibility, carbon dioxide, R744, plays an increasingly important role as a high-pressure refrigerant.
A disadvantage of high-pressure refrigerants in connection with the dimensioning and design of heat exchangers for these refrigerants is that adapted to the high process pressures special design principles and materials are required to meet the safety requirements of a variety of applications.

In the prior art, for example, from the DE 101 10 828 A heat exchanger for a CO ₂ vehicle air conditioning system is known, wherein the channels are formed by a plurality of smaller channels, which are arranged on or in heat transfer plates, wherein a plurality of layers of heat transfer plates are soldered or welded together.

From the DE 101 46 824 A1 goes with a heat exchanger flat tube block formed flat tube ends, with flat tubes with multiple, distributed over the tube cross-section channels form the flow path for the high-pressure refrigerant.

Such flat tubes are also referred to as multi-channel flat tubes and also go from the DE 102 41 635 A1 showing a flat tube heat exchanger and a manufacturing method for such disclosed.

Furthermore, from the DE 10 2005 044 754 A1 a multi-row heat exchanger and a corrugated fin for the same known, wherein the flat tubes of a row are arranged offset from the adjacent row and wherein between the flat tubes itself a corrugated fin for enlarging the surface on the air side of the heat exchanger is provided.

Difficulties in heat exchangers with flat tubes prepare experience according to the integration of the flat tubes in the header pipes and the arrangement of the flat tubes to the heat exchanger block with the connections to the slats for air-side heat transfer.

A particular disadvantage of heat exchanger designs with multichannel flat tubes from the prior art is that an economical production and a robust construction and the smallest possible dimensioning and high compactness of the heat exchanger is still not satisfactorily solved.

The object of the invention is therefore to provide a heat exchanger available, which is particularly suitable for high-pressure refrigerant and can be produced efficiently and has low construction dimensions.

The object of the invention is achieved by an article having the features according to claim 1. Further developments are specified in the dependent claims.

The object is achieved in particular by a heat exchanger, which is particularly suitable for high-pressure refrigerant and consists of a plurality of superimposed and mutually parallel multi-channel flat tubes and intervening fins. The multi-channel flat tubes each have an end region at the ends, in which the multi-channel flat tubes are combined in each case. At the two end portions of the multi-channel flat tubes connecting pieces are arranged, in which open the ends of the multi-channel flat tubes one side. On the other side of the connecting piece, there is a possibility of connection to generally standardized pipes, which lead the refrigerant out to the connecting piece or, on the other side, away from the connecting piece. The adjacent multi-channel flat tubes are spaced from each other with spring blades and thermally contacted in a plurality of slit regions divided between the connecting tubes to the length of the flat tubes. The majority of the multi-channel flat tubes are guided in sections parallel to each other and together in each case meander-shaped.

Preferably, adjacent multi-channel flat tubes in the lamellar region are arranged parallel and straight to one another and spaced from one another by spring lamellae. The design of the surface enlargement on the air side of the heat exchanger with spring blades represents a particularly cost-effective and efficient form of surface enlargement, which is very particularly advantageous to manufacture.

According to an advantageous embodiment of the invention, transition regions are arranged between the lamellar regions along the heat exchanger flat tubes, in which the adjacent multi-channel flat tubes are at least partially directly contacted with each other. From slat area to Lamella area is preferably a change in direction of the orientation of the multi-channel flat tubes, which is realized by the arrangement of a transition region.
A particularly well-to-produce and space-saving design is now that in the transition areas the Mehrkanalflachrohre directly thermally connected to each other standing on each other.

Particularly preferably, the transition areas between the slat areas are parallel and straight.

Particularly preferably, the lamellar areas and the transition area are each arranged alternately and offset by 90 ° to each other. In the way, a heat exchanger can be created, which has a generally rectangular and in particular even square air flow cross-section.

This is particularly preferably achieved by arranging three fin regions and two transition regions between the end regions of the multi-channel flat tubes of the heat exchanger.

A preferred embodiment of the invention is that eight multi-channel flat tubes of the same length are arranged in the heat exchanger.

The lamellar regions are preferably formed by arranging a plurality of intertwined spring lamellae of spiral springs between the multi-channel flat tubes. The lamellae can thus be made particularly cost-effective from standard metalworking products, the spiral springs, which leads overall to cost-effective solutions in the production of Hochdruckruckmeübertragern.

Preferably, three intertwined and interpenetrated spring plates are arranged between adjacent multi-channel flat tubes in the lamellar region, wherein the orientation alternately the adjacent coil springs changes. This means that the middle of the three coil springs has a different orientation than the two adjacent outer coil springs. Under the orientation of the coil springs is to be understood that they are executed accordingly once left and another time turned right.

Particularly advantageous for the heat transfer tasks and the efficient production of heat exchangers, the connection between the multi-channel flat tubes and the spring blades is performed with thermosetting adhesive. This eliminates the need for soldering and welding the slats to the multi-channel flat tubes.

The invention relates conceptually a heat exchanger in a modified structure with respect to the pipe run of Mehrkanalflachrohre. Particularly noteworthy is that only two connection points of the multi-channel flat tubes with each other and to the connecting pieces located in each case in the end regions exist. This well controllable concentration of potential leaks favors the use of heat exchangers in stationary and mobile applications.

The heat exchanger design is compact and universally designed, and heat exchangers of the proposed design can replace almost any conventional heat exchanger, with smaller dimensions required for the same performance.
Also, the heat exchanger is suitable for higher pressures and thus is a use in high-pressure refrigerant circuits with CO ₂ as a refrigerant possible.

In a preferred embodiment, the heat exchanger consists of eight multi-channel flat tubes, which have dimensions of 1.8 mm in height and 16 mm in width. The multi-channel flat tubes are bent meander-shaped and each have an equal length. At the inlet and outlet of the fluid flowing through the multi-channel flat tubes, these are bundled together in the end regions.

The multi-channel flat tubes are received at these end of each pipe receiving with adapter and connected by laser welding, for example, tightly together and the pipe receiving. Adapters are connected to the tube receptacles, which have corresponding connection dimensions for integration into the circuit of the air conditioning system.

Between the broadside mutually arranged Mehrkanalflachrohren three interlaced coil springs made of aluminum are inserted according to a preferred embodiment, to ensure a spacing of the Mehrkanalflachrohre each other and a best possible heat transfer to the air flowing through the Mehrkanalflachrohren. Of these three coil springs, the middle one is wound in the opposite direction to ensure interfitting. The geometry of the three intertwined springs ensures a good turbulence of the air flow and achieved over conventional fins a much higher stability. The connection between the multi-channel flat tubes and the coil springs is, as mentioned, made by a thermosetting adhesive, which is fused at a temperature of about 180 to 190 degrees Celsius.

The dimensions of the embodiment according to the invention are 278 mm x 278 mm and are thus of square flow cross-section for the air. The length of the multi-channel flat tubes is in each case 1065 mm. To be particularly advantageous is to emphasize that the heat exchanger has a very compact design, in which there are only two connection points of the multi-channel flat tubes. The joints are designed much more stable than comparable collector constructions according to the prior art and thus provide the entire heat exchanger a significantly higher resistance to mechanical influences. Due to its robust design principle, the heat exchanger can withstand application-induced impacts or deformations, as may occur, for example, in light accidents in the area of the heat exchanger when used in vehicles.

Another advantage is that costly soldering for the integration of each individual Mehrkanalflachrohres omitted in a collector, since all Mehrkanalflachrohre open at their ends in each case only one connection point, which can be accurately sealed by laser welding machine. The connecting elements, consisting for example of adapter and pipe receiving, are easy to produce molded parts, which promotes economic production of the heat exchanger. The design principle and the parallel guidance of the multi-channel flat tubes ensured a continuous liquefaction of the refrigerant when using the heat exchanger as a condenser and there is no additional wet steam area. This is due to the fact that the length of the individual multi-channel flat tubes differs significantly from the conventional heat exchanger tubes.

In summary, there are several advantages of the invention. The meandering shape of the multi-channel flat tubes allows a compact design of the heat exchanger with the same power. The introduction of spring blades between the multi-channel flat tubes causes a higher turbulence of the air flow and thus contributes to the improvement of the mode of action. The spring blades themselves are clearly more stable than conventional lamellas made of thin aluminum sheet due to their interlaced construction and the thermosetting compound. The construction of spring blades allows a significantly better cleaning ability, which is particularly interesting when using the heat exchanger as a condenser and associated pollution.
The selection of suitable multi-channel flat tubes for the heat exchanger also allows the operation of the refrigerant circuits at much higher pressures and in particular the use of CO ₂ as a refrigerant with this heat exchanger type is possible.

Fig. 1:

Wärmeübertrager im Querschnitt

Fig. 2:

Anschlussstutzen und Adapter für die Mehrkanalflachrohre im Endbereich

Fig. 3:

Federlamellen

Further details, features and advantages of embodiments of the invention will become apparent from the following description of exemplary embodiments with reference to the accompanying drawings. It demonstrate:

Fig. 1:

Heat exchanger in cross section

Fig. 2:

Connecting pieces and adapters for multi-channel flat pipes in the end area

3:

spring blades

In Fig. 1 a heat exchanger 1 is shown in cross-section, which is composed of a plurality of multi-channel flat tubes 2. Between the multi-channel flat tubes 2 are spring blades 3, in part on the left side of FIG. 1 represented, arranged. The ends of the multi-channel flat tubes 2 each form an end region 11, in which the ends of the multi-channel flat tubes 2 are combined. The ends of the multi-channel flat tubes 2 open into a tube receiving 5, which forms the connecting piece 8 with an adapter 4. The adapter 4 has the corresponding geometric dimensions towards the lines outside the heat exchanger 1. Preferably, the adapter 4 is designed replaceable, so that the heat exchanger 1 is adaptable to different piping systems. Alternatively, adapter 4 and pipe receiving 5 are designed as one component, which simplifies the production and further reduces the susceptibility to leakage.

On the way between the two end regions 11, the multi-channel flat tubes 2 have different areas. From the end region 11, the multichannel flat tubes 2 pass over into a lamellar region 9 and then after directional deflection by 90 °, the multichannel flat tubes 2 merge into a transitional region 10, in which the multichannel flat tubes 2 are contacted at least partially directly with one another.
From the transition region 10, the multi-channel flat tubes 2 are in turn deflected to a lamellar region 9 and, after a further deflection, pass into a transition region 10. From the transition region 10, the multi-channel flat tubes 2, after renewed deflection, pass into the end region 11 and are guided therein to the connecting piece 8. The two Connecting pieces 8 are in two planes in the opposite direction.

In Fig. 2 is a view in the axial direction of the multi-channel flat tubes 2 on the adapter 4 and the raw receptacle 5 is shown. The multi-channel flat tubes 2 are welded in this fixation in the tube receiving 5 by laser welding. The multi-channel flat tubes 2 are flowed through in this configuration from one end portion 11 to the other in parallel with refrigerant.

In Fig. 3 three spring blades 3 are shown, which are designed as spring blades 7 with a winding in left orientation and as a spring blades 6 with a winding in the right orientation. The spring blades 6, 7 are made of aluminum because of the good heat transfer properties and intertwined under mechanical stress. The coil springs are mechanically very robust and hold in shape also mechanically demanding cleaning method, for example by means of high-pressure cleaner, in contrast to slats of aluminum sheet according to the prior art stood.

LIST OF REFERENCE NUMBERS

1

Heat exchanger

2

Multichannel flat tube

3

spring blades

4

adapter

5

tube support

6

Spring plate wound right

7

Spring plate wound left

8th

spigot

9

slat area

10

Transition area

11

end

Claims (9)

Heat exchanger (1), in particular for high-pressure refrigerant, from a plurality of multi-channel flat tubes (2) with intermediate slats, wherein the ends of the multi-channel flat tubes (2) in each case an end region (11) are combined, characterized in that the multi-channel flat tubes (2) to the both end areas (11) are combined in connecting pieces (8) and that adjacent multi-channel flat pipes (2) are spaced apart and thermally contacted with spring blades (6, 7) in a plurality of blade areas (9) between the connecting pieces (8), wherein the plurality of multi-channel flat pipes (2) are guided in sections parallel to each other and jointly meander-shaped and between the lamellar regions (9) transition regions (10) are arranged, in which the adjacent Mehrkanalflachrohre (2) are at least partially contacted directly with each other. Heat exchanger (1) according to claim 1, characterized in that adjacent Mehrkanalflachrohre (2) in the lamellar region (9) arranged parallel to each other and with spring blades (6, 7) are spaced from each other. Heat exchanger (1) according to one of claims 1 to 2, characterized in that the transition regions (10) between the slat regions (9) are made parallel. Heat exchanger (1) according to one of claims 1 to 3, characterized in that lamellar region (9) and transition region (10) each arranged alternately and offset by 90 ° to each other are. Heat exchanger (1) according to one of claims 1 to 4, characterized in that three fin regions (9) and two transition regions (10) between the end regions (11) are arranged. Heat exchanger (1) according to one of claims 1 to 5, characterized in that eight Mehrkanalflachrohre (2) of the same length in the heat exchanger (1) are arranged. Heat exchanger (1) according to one of claims 1 to 6, characterized in that the lamellar regions (9) are formed with a plurality of intertwined spring blades (6, 7) of coil springs. Heat exchanger (1) according to claim 7, characterized in that three spring blades (6, 7) are arranged, alternately changing the orientation of the coil springs. Heat exchanger (1) according to one of claims 1 to 8, characterized in that the connection between the multi-channel flat tubes (2) and the spring blades (6, 7) is formed with thermosetting adhesive.

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