DE102015103177A1 - High-pressure refrigerant heat exchanger with multi-channel flat tubes - Google Patents

Abstract

The invention relates to a high-pressure refrigerant heat exchanger (1) with multi-channel flat tubes (2), which is characterized in that a plurality of multi-channel flat tubes (2) through which high-pressure refrigerant flows in the direction of water flow, coolant flow direction (11) one behind the other and transversely to the water, coolant flow direction (11 ) are arranged in a housing (3), wherein the multi-channel flat tubes (2) along its length are not flat and that no fins or ribs are provided.

Description

The invention relates to a high-pressure refrigerant heat exchanger with multi-channel flat tubes for heat transfer between a high pressure refrigerant circuit and a liquid circuit. Under a liquid circuit is primarily a water-coolant circuit understood, the water or the coolant may be both brine and heat transfer.

Generic heat exchangers are used for example in high-pressure refrigerant circuits in motor vehicle air conditioning systems as gas cooler or condensers or as an evaporator for the high-pressure refrigerant. As a heat or cold carrier is a liquid, such as water, a water-glycol mixture or similar liquid mixtures.

As high-pressure refrigerant, in addition to other possible refrigerants, primarily carbon dioxide is used as the refrigerant, which is characterized in that the refrigerant circuit operates on a relatively high pressure level compared to other refrigerants.

Typical water-coolant heat exchangers according to the prior art are predominantly designed as plate heat exchangers for use as evaporators or condensers. The working pressure and bursting pressure of air-refrigerant evaporators or air-refrigerant condensers is similar to liquid-refrigerant heat exchangers. A typical working and bursting pressure for an evaporator in motor vehicle air conditioners is 3 to 4 or 31 bar.

Capacitors have a working pressure of 6 to 30 bar and a bursting pressure of 60 bar. For the high pressure refrigerant carbon dioxide, R744, the burst pressure requirement is 260 bar for the evaporator and 340 bar for the gas cooler. A plate heat exchanger with a bursting pressure of more than 260 bar would, according to the current design, lead to an enormous increase in weight and costs. To achieve a bursting pressure of 260 bar with the conventional design, for example, the wall thickness of the panels must be increased by more than 300%. In addition to high weight and high costs, this high material usage also leads to difficulties in the soldering process.

High-pressure refrigerant heat exchangers are known in the art. From the DE 10 2011 007 784 A1 is a capacitor, in particular a cooling agent cooled condenser known, which consists of at least one tube / rib block with a plurality of flat tubes. Each flat tube has a plurality of flow channels running side by side in the tube transverse direction and defining a coolant-side hydraulic diameter. In the region of the flat tubes, a coolant-side hydraulic diameter-defining intermediate element is arranged.

The burst pressure in conventional refrigerant systems is approximately 31 bar on the low pressure side. A disadvantage of the known embodiments of Hochdruckkältemittelwärmeübertragern according to the prior art is that they meet either by very high use of materials, the extreme demands on the working and bursting pressure by thick wall thicknesses or that the heat exchanger with multi-channel flat tubes and fins for heat transfer to air as cold or heat transfer medium are designed and can not be used as a liquid heat exchanger.

The object of the invention is now to form a high-pressure refrigerant heat exchanger with multi-channel flat tubes, which can be manufactured with low costs in terms of material and manufacturing costs. Furthermore, the high-pressure refrigerant heat exchanger should be suitable for heat transfer to and from liquids, in particular for water or water-glycol mixtures.

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

In particular, the object of the invention is achieved by a high-pressure refrigerant heat exchanger which has a plurality of high-pressure refrigerant flow through Mehrkanalflachrohre, which are arranged in water, coolant flow direction behind the other and transverse to the water, coolant flow direction in a housing. The multi-channel flat tubes are not flat along their length and, unlike the prior art, have no fins or ribs.

An advantageous improvement further consists in that ribs are additionally provided, which are made of metal or plastic.

According to a preferred embodiment of the invention, the multichannel flat tubes are arranged on the narrow side forming the height of the multichannel flat tube in the high-pressure refrigerant heat exchanger. The water, coolant flow thus flows transversely to the multi-channel flat tube along the width of the multi-channel flat tube.

Preferably, the multi-channel flat tubes along their length with bends to waves, Mäandern, trapezes or folds formed, whereby the heat-transmitting outer surface of the Mehrkanalflachrohre is increased accordingly with respect to a plane along its length designed embodiment of Mehrkanalflachrohre.

A high-pressure refrigerant heat exchanger is advantageously produced by using a wide heat exchanger extruded profile, from which the relevant sections are formed by punching according to the requirements.

Advantageously, the Mehrkanalflachrohre along their length with bending angles between 0 ° and 90 ° deformed.

In this case, bending radii between 5 mm and 15 mm are preferably carried out.

An advantageous embodiment of the invention is that the multi-channel flat tubes have a bending height between 1 mm and 10 mm.

The multi-channel flat tubes preferably have a bending height of between 1 and 4 mm.

Particularly preferably, the bends, corrugations or convolutions in water, coolant flow direction of successively arranged Mehrkanalflachrohre offset from each other, so that the fluid flow of the water or coolant in a flow damage strikes several narrow sides of Mehrkanalflachrohre and thus turbulence of the flow can be achieved.

An advantageous development of the invention consists in that the dividing walls are provided in several levels of the high-pressure refrigerant heat exchanger, which predetermine or generate a flow path of the water and coolant through the high-pressure refrigerant heat exchanger.

Advantageously, horizontal partitions are arranged in the high pressure refrigerant exchanger, resulting in a flow path for a vertical cross countercurrent.

According to a further embodiment of the invention, vertical partitions are provided in the high pressure refrigerant heat exchanger, thereby forming a flow path for a horizontal cross countercurrent.

Advantageously, the housing of the high pressure refrigerant heat exchanger is made of aluminum or plastic. Of particular note is the suitability of using a high-pressure refrigerant heat exchanger as a gas cooler / condenser or as a cooler in carbon dioxide refrigerant circuits and in particular for use of this component for motor vehicle air conditioners.

According to the concept of the invention, the high burst pressure requirements for R744 carbon dioxide cycles in high pressure refrigerant installations are met by using extruded microchannel tubes, also referred to as multi-channel flat tubes, from known R744 evaporators or gas coolers. The heat or brine side for liquid, especially water or water-glycol mixture is designed without ribs or fins, which positively reduces the flow resistance but negatively reduces the heat transfer performance also. The multi-channel flat tube is bent and reshaped and acts through the resulting shape at the same time as heat exchanger tube and flow installation, the latter is also referred to as a turbulator. The design according to the invention can be used very particularly advantageously in high-pressure refrigerant circuits as gas coolers according to the cross-countercurrent principle.

The entire heat exchanger is surrounded by a housing made of aluminum or plastic. Embodiments of the high-pressure refrigerant heat exchanger with partitions allow the formation of a plurality of flow paths within a heat exchanger. It is particularly advantageous if the water or the liquid flows as a heat or cold carrier in the cross counterflow. Ribs or lamellae and turbulators are not required because the multi-channel flat tube provides by its shapes by bending a turbulent flow.

The heat exchanger design is lightweight, resulting in low material and handling costs in manufacturing and energy savings during ongoing operation in the motor vehicle. Also advantageous is the variability by the provision of partitions with respect to the flow guides in the heat exchanger and also the choice of the housing, which is preferably made of plastic or metal. The dimensioning of the housing can be adapted to the pressure of the fluid circuit, ie at a relatively low level, since the high-pressure refrigerant circulates only within the multi-channel flat tube.

Particular advantages continue to be that the high-pressure refrigerant heat exchanger can also be used for supercritical heat transfer with a temperature slide as a gas cooler or evaporator, which is advantageous in particular for use in R744 carbon dioxide refrigerant circuits.

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. Show it:

1 : Perspective schematic view of a high pressure refrigerant heat exchanger as a vertical cross countercurrent,

2 : Detail multi-channel flat tubes with a refrigerant collector as a plane of a high-pressure refrigerant heat exchanger,

3 : High-pressure refrigerant heat exchanger in the embodiment of a horizontal cross-countercurrent,

4a : Multi-channel flat tube as bent in waveform,

4b : Multi-channel flat tube folded along the length and

4c : Multi-channel flat tube folded as trapezoid.

In 1 a high-pressure refrigerant heat exchanger is shown in perspective and schematically. The high pressure refrigerant heat exchanger 1 contains multi-channel flat tubes 2 in a housing 3 are placed. The multi-channel flat tubes 2 are flowed through by the high pressure refrigerant. Inside the case 3 become the multi-channel flat tubes 2 flows through a fluid flow, in particular a water or coolant or heat transfer medium. The high pressure refrigerant heat exchanger 1 is in three levels by horizontal dividing walls 8th segmented. In the embodiment shown according to 1 is the water, coolant flow direction 11 indicated by an arrow. At the water, coolant inlet 6 the fluid flows into the lower heat exchanger segment and thereby occurs in the direction transverse to the water-coolant flow direction 11 arranged multi-channel flat tubes 2 on the narrow side and then flows along the width of the flat tubes, the Mehrkanalflachrohr 2 , In the illustrated embodiment are two multi-channel flat tubes 2 in the flow direction 11 arranged one behind the other, so that the fluid flow in succession first flows around a first and / or a second / third / fourth etc. multichannel flat tube. At the bottom of the lower level is a water-coolant diverting area 9 formed in which the fluid is deflected and directed into the overlying level. There flows through the water coolant in the flow direction 11 this level forward, again with passage of the two consecutively arranged Mehrkanalflachrohre 2 , Finally, the water-coolant flow is again in a deflection region 9 redirected and finally redirected to the third vertical overlying plane, after which the water-coolant stream after passage of the uppermost level the high-pressure refrigerant heat exchanger 1 at the water, coolant outlet 7 leaves. The high-pressure refrigerant enters the refrigerant inlet 4 in the high pressure refrigerant heat exchanger 1 and flows along the length of the multi-channel flat tube 2 , The multi-channel flat tube 2 is extended by U-shaped transformations. At the end of the upper level becomes the multi-channel flat tube 2 deflected and guided in the middle level, this finally flows through the entire width of the Hochdruckkältemittelwärmeübertragers 1 , The multi-channel flat tube 2 Finally, it is led to the lowest level and, after flowing through the lower level, the high-pressure refrigerant leaves the refrigerant outlet 5 the high pressure refrigerant heat exchanger 1 ,

In 2 is the multi-channel flat tube 2 in a refrigerant collector pipe 10 fixed and the refrigerant collecting pipe 10 forms with the three illustrated multi-channel flat tubes 2 a plane of a heat exchanger. Within the plane, a water or coolant flows from an entrance 6 to an exit 7 and flows around in the side view as a trapezoid 14 shaped multi-channel flat tubes 2 , In this illustration it is also shown that the multi-channel flat tubes 2 in a plane offset with their transformations are arranged to each other, which in each case for each flow path a different flow situation from one to the next Mehrkanalflachrohr 2 gives, what turbulence and thus a better heat transfer between the multi-channel flat tube 2 and the water coolant stream.

In 3 a high-pressure refrigerant heat exchanger is shown which does not have partitions in a horizontal plane 8th but in a vertical plane a partition 8th has indicated schematically. This is necessary if the maximum required / required refrigerant mass flow and the resulting pressure loss is too high. For this purpose, the refrigerant is passed in parallel through the different heat exchanger tube levels.

The water, coolant inlet 6 lies in this embodiment on the same side of this Hochdruckkältemittelwärmeübertragers 1 like the water, coolant outlet 7 , being between the entrance and the exit 6 . 7 the partition 8th is arranged. After flowing through the high-pressure refrigerant heat exchanger 1 takes place at the end in the deflection area 9 a deflection of the water and coolant to the lying in the same plane backflow and then to the output 7 , The refrigerant inlet 4 the multi-channel flat tubes 2 is schematically indicated on the page shown, wherein no refrigerant collecting pipes are provided in this embodiment.

In 4a , b, c are multi-channel flat tubes 2 shown with different transformations in the side view from the direction of the flowing water, coolant.

4a shows it next to the trimmed refrigerant collector tube 10 two multi-channel flat tubes 2 as waves 12 extending along the length of the multi-channel flat tube 2 extend across the width of the Hochdruckkältemittelwärmeübertragers. In 4a are the two multi-channel flat tubes 2 offset from one another, whereby in this side view the multi-channel flat tubes 2 as superimposed serpentine lines are shown.

In 4b is a multi-channel flat tube 2 in a structure with bends in the manner of wrinkles 13 along the length of the multi-channel flat tube 2 represented and finally becomes in 4c a folding in the manner of a trapezoid 14 along the length of the multi-channel flat tube 2 shown.

LIST OF REFERENCE NUMBERS

1

 High-pressure refrigerant heat exchangers

2

 Multichannel flat tube

3

 casing

4

 Refrigerant input

5

 Refrigerant output

6

 Water, coolant inlet

7

 Water, coolant outlet

8th

 partition wall

9

 Water, coolant deflection area

10

 Refrigerant collector pipe

11

 Water, coolant flow direction

12

 Waves along the length of the multi-channel flat tube

13

 Fold along the length of the multi-channel flat tube

14

 Trapezoid along the length of the multi-channel flat tube

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102011007784 A1 [0006]

Claims (15)

High-pressure refrigerant heat exchanger ( 1 ) with multi-channel flat tubes ( 2 ), characterized in that a plurality of multichannel flat tubes through which high-pressure refrigerant can flow ( 2 ) in the water, coolant flow direction ( 11 ) one behind the other and transverse to the water, coolant flow direction ( 11 ) in a housing ( 3 ), wherein the multi-channel flat tubes ( 2 ) are not flat along their length and that no fins or ribs are provided. High-pressure refrigerant heat exchanger ( 1 ) according to claim 1, characterized in that in addition ribs of metal or plastic are provided. High-pressure refrigerant heat exchanger ( 1 ) according to claim 1 or 2, characterized in that the multi-channel flat tubes ( 2 ) on its the height of the multi-channel flat tube ( 2 ) forming the narrow side in the high-pressure refrigerant heat exchanger ( 1 ) and along the width of the multi-channel flat tube ( 2 ) are flowed around by the water, coolant flow. High-pressure refrigerant heat exchanger ( 1 ) according to one of claims 1 to 3, characterized in that the multi-channel flat tubes ( 2 ) are formed along their length with bends to waves, meanders, trapezoids or folds. High-pressure refrigerant heat exchanger ( 1 ) according to one of claims 1 to 4, characterized in that a broad heat exchanger extruded profile is used, from which the respective sections are produced by punching according to the requirements. High-pressure refrigerant heat exchanger ( 1 ) according to one of claims 1 to 5, characterized in that the multi-channel flat tubes ( 2 ) have bending angles between 0 ° and 90 ° along their length. High-pressure refrigerant heat exchanger ( 1 ) according to one of claims 1 to 6, characterized in that the multi-channel flat tubes ( 2 ) Have bending radii between 5 mm and 15 mm. High-pressure refrigerant heat exchanger ( 1 ) according to one of claims 1 to 7, characterized in that the multi-channel flat tubes ( 2 ) have a bending height between one mm and ten mm. High-pressure refrigerant heat exchanger ( 1 ) according to one of claims 1 to 8, characterized in that the multi-channel flat tubes ( 2 ) have a bending height between one mm and four mm. High-pressure refrigerant heat exchanger ( 1 ) according to one of claims 1 to 9, characterized in that the bends, waves or folds in the water, coolant flow direction ( 11 ) arranged in succession Mehrkanalflachrohre ( 2 ) are offset from one another. High-pressure refrigerant heat exchanger ( 1 ) according to one of claims 1 to 10, characterized in that partitions ( 8th ) in multiple levels of the high-pressure refrigerant heat exchanger ( 1 ) are provided, which a flow path of the water, coolant through the high-pressure refrigerant heat exchanger ( 1 ) form. High-pressure refrigerant heat exchanger ( 1 ) according to claim 11, characterized in that horizontal partitions ( 8th ) in the high-pressure refrigerant heat exchanger ( 1 ) and form a flow path for a vertical cross countercurrent. High-pressure refrigerant heat exchanger ( 1 ) according to claim 11, characterized in that vertical partitions ( 8th ) in the high-pressure refrigerant heat exchanger ( 1 ) are arranged and form a flow path for a horizontal cross countercurrent. High-pressure refrigerant heat exchanger ( 1 ) according to one of claims 1 to 13, characterized in that the housing ( 3 ) is formed of aluminum or plastic. Use of a high-pressure refrigerant heat exchanger according to one of the preceding claims as a gas cooler / condenser or as a cooler in carbon dioxide refrigerant circuits.

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