DE202013011854U1 - Internal heat exchanger for an air conditioner - Google Patents

Abstract

An internal heat exchanger (1) for an air conditioner (2), comprising an outer tube (3) and a conduit structure (4) disposed inside said outer tube (3), said conduit structure (4) including a first flow channel (5) and between outer tubes (3). 3) and line structure (4), a second flow channel (6) is formed, characterized in that the first flow channel (5) is meander-shaped.

Description

The invention relates to an internal heat exchanger for an air conditioner, comprising an outer tube and a pipe structure arranged within the outer pipe, wherein the pipe structure includes a first flow channel and wherein between the outer pipe and the pipe structure, a second flow channel is formed.

Such an internal heat exchanger is from the DE 10 2007 015 186 A1 known. By incorporating an internal heat exchanger into the refrigerant circuit of an air conditioner, the efficiency of an air conditioner can be increased by transferring heat of the refrigerant from its high pressure side to the low pressure side. In this case, the coolant is liquid on the high pressure side and gaseous on the low pressure side, wherein the coolant is passed on the high pressure side through the first flow channel and the coolant on the low pressure side through the second flow channel. The guided through the second flow channel coolant has due to the low pressure and the gaseous state, a comparatively small heat receiving capacity, which limits the transmission capacity of the internal heat exchanger as a whole.

In most cases, both outer tube and the arranged inside the outer tube line structure are tubular with a circular cross-section, wherein the length of outer tube and tubular conduit structure are identical.

In addition, the size, in particular the length of the internal heat exchanger is limited when it is designed for mounting in a mobile air conditioning system, such as a vehicle.

The invention has for its object to provide an internal heat exchanger having a high heat transfer performance in a compact design.

This object is achieved with the features of claim 1. In advantageous embodiments, the dependent claims relate.

To solve the problem of the first flow channel is meander-shaped. It is advantageous that the usable in the heat exchange effective tube length can be significantly increased within the internal heat exchanger. This increases at the same time low overall length of the heat exchanger whose heat transfer performance. At the same time results from the meandering configuration of the first flow channel a particularly compact design of the internal heat exchanger, so that it is particularly suitable for mounting in a mobile air conditioning, such as a vehicle.

The line structure may have heat-conducting ribs on the outside. The heat-conducting ribs preferably extend in the direction of the inner wall of the outer tube, starting from the first flow channel arranged centrally in the outer tube. By the heat-conducting ribs, the outer surface of the line structure increases, thereby improving the heat transfer performance. The heat-conducting ribs are connected in the same material as the first flow channel, so that a direct heat transfer from the fluid guided in the first flow channel to the heat-conducting ribs can take place. The heat-conducting fins extend in the radial direction and along the outer tube, so that the fluid guided in the second flow channel flow along the heat-conducting fins and absorb the heat emitted by the heat-conducting fins.

The heat-conducting ribs can extend into the region of the inner wall of the outer tube. However, in order to simplify the assembly, the heat-conducting ribs are designed so that the inner wall of the outer tube is not touched. Preferably, a gap results between the heat-conducting ribs and the inner wall of the outer tube, wherein the gap width is preferably between 0.5 mm and 2.5 mm, preferably 1.5 mm. In this embodiment, it is particularly advantageous that the heat conducting ribs extend almost completely through the second flow channel. As a result, channels form between the heat-conducting ribs and a particularly effective heat transfer is effected. At the same time, however, the heat-conducting ribs and, as a result, the line structure are so spaced from the inner wall of the outer tube, so that the line structure can be easily installed by insertion.

The line structure may be formed in several parts. This improves the manufacturability of the line structure, since the first flow channel is formed complex due to its meandering configuration.

The line structure may have shells provided with heat-conducting ribs, which are connected to one another via channel elements. To produce such a line structure, the shells are first provided and manufactured for example by means of extrusion. The heat-conducting ribs are of the same material and integrally formed on the shell. One side of the shell forms in sections an inner wall of the first flow channel. Thus, the shape of the side of the shell determines the shape of the flow channel.

The channel elements are preferably comb-shaped. Preferably, two channel elements are provided which on the one hand predetermine the meander shape and on the other hand also form lateral boundary walls of the first flow channel. The channel elements have a base portion forming the lateral boundary walls on which needle-shaped projections are arranged. To produce the line structure and the first flow channel, two channel elements are arranged opposite each other, wherein the projections face each other. By lateral displacement of the channel elements creates the meandering structure.

The elements of the line structure may be formed of metallic material. Particularly easy to process materials with high thermal conductivity into consideration. Such advantageous materials are for example aluminum alloys, which on the one hand have a high thermal conductivity and on the other hand can be processed by extrusion, so that the line structure is simple and inexpensive to produce.

The elements of the line structure can be materially interconnected. In this context, it is particularly possible to connect the elements by means of gluing or soldering together. The integral connection allows a tight and permanent connection of the elements, so that leaks can be avoided. Furthermore, the method is simple and inexpensive.

The line structure can be inserted into the outer tube. This results in a particularly easy manufacturability of the internal heat exchanger.

At the end faces of the pipe structure pipe socket can be arranged, wherein the pipe socket are connected in flow-conducting manner with the first flow channel. In turn, the lines of the high pressure side of the air conditioner are connected to the pipe socket. Thus, the pipe sockets form connecting elements for integrating the internal heat exchanger in the air conditioner.

The outer tube can be closed at its end faces in each case with a lid, wherein the lid have pipe connections, which are connected to the first flow channel and the second flow channel. Preferably, the cover has a passage opening for the pipe socket connected to the first flow channel. In this case, the passage opening is designed so that no leakage occurs, can escape through the fluid from the low pressure side. Furthermore, the cover has connection element for the integration of the fluid guided in the second flow channel into the air conditioning circuit.

The inner diameter of the outer tube is preferably between 25 mm and 35 mm. The width of the first flow channel is preferably between 3.5 mm and 5.5 mm. These dimensions result in a particularly compact internal heat exchanger, which is particularly suitable for integration into a mobile air conditioning system of a vehicle. At the same time, however, the heat transfer capacity, starting from a length of the heat exchanger of about 500 mm with about 600 W high.

The first flow channel may have an at least partially rectangular cross-section. Such a channel is easy to manufacture and has a larger area than a circular channel.

The internal heat exchanger according to the invention is preferably used in a mobile air conditioning system, in particular in vehicle air conditioning. Due to the compact design, the rohrfömigen shape and the high heat transfer performance of the internal heat exchanger according to the invention is particularly suitable for integration into a mobile air conditioning system of a vehicle.

Some embodiments of the internal heat exchanger according to the invention are described below with reference to the figures. These show, in each case schematically:

1 the air conditioning circuit of a mobile air conditioning system with internal heat exchanger;

2 the internal heat exchanger in section;

3 a first exploded view of the internal heat exchanger;

4 a second exploded view of the internal heat exchanger;

5 a third exploded view of the internal heat exchanger;

6 a fourth exploded view of the internal heat exchanger;

7 the internal heat exchanger in a spatial representation.

1 schematically shows the air conditioning circuit of a mobile air conditioning 16 , in particular the air conditioning of a vehicle. The air conditioner exists from a closed circuit in which a coolant circulates. The coolant is compressed by a compressor and then enters a condenser 18 where the coolant is liquefied. After exiting the evaporator, the coolant is liquid and has a temperature of 30 ° C to 50 ° C at a pressure of 7 bar to 15 bar. The liquefied coolant is now in the second flow channel 5 the internal heat exchanger according to the invention 1 fed where that from the condenser 18 escaping coolant heat to the from the evaporator 20 emits escaping gaseous coolant. Thereafter, the liquid refrigerant flows into the expansion valve 19 where the pressure of the coolant is lowered. In the evaporator 20 The coolant absorbs heat, where it is evaporated and then gaseous. The heated gaseous coolant has a temperature of -1 ° C to 15 ° C at a pressure of 2.5 bar to 4 bar. The gaseous coolant flows through the internal heat exchanger through the second flow channel 6 and absorbs heat from the liquid coolant carried on the other side.

2 shows a sectional view of the internal heat exchanger 1 for an air conditioner 2 in particular for a mobile air conditioning system for use in a vehicle. The internal heat exchanger 1 is tubular and includes an outer tube 3 and one inside the outer tube 3 arranged line structure 4 , Here is the management structure 4 in the outer tube 3 inserted. The management structure 4 closes a first flow channel 5 one and between outer tube 3 and management structure 4 a second flow channel forms 6 out. Here is the management structure 4 designed such that the first flow channel 5 is meander-shaped. The inner diameter of the outer tube 3 is 30 mm and the width of the first flow channel 5 is 4.5 mm.

The 3 to 6 each show exploded views of the internal heat exchanger according to the invention 1 in different assembly stages. In the figures, it can be seen that the line structure 4 on the outside, heat-conducting ribs 7 which, starting from the first flow channel 5 into the area of the inner wall 8th of the outer tube 3 extend. The heat-conducting ribs 7 extend in the radial direction and along the flow direction of the second flow channel 6 so that through the second flow channel 6 Guided coolant on the heat-conducting ribs 7 flows along and absorbs heat. The distance between heat conducting ribs 7 and inner wall 8th of the outer tube 3 is chosen so that the line structure 4 is easy to install by insertion. The distance is 1.5 mm in this embodiment.

The first flow channel 5 has a rectangular cross-section.

Furthermore, it can be seen that the line structure 4 is formed in several parts and two with heat-conducting ribs 7 provided cups 9 which has two channel elements 10 connected to each other. The channel elements 10 are comb-shaped and on the upper and lower sides with the shells 9 connected. The channel elements 10 have protrusions 16 on, with the channel element 10 are offset with each other with the shells that the meandering structure of the first flow channel 5 results.

The elements, that is the bowls 9 and the channel element 10 the management structure 4 are formed of metallic material, formed in this embodiment of an aluminum alloy. The shaping took place by means of extrusion. The Elements 9 . 10 the management structure 4 are interconnected by means of a solder connection cohesively.

At the front ends 11 the management structure 4 are pipe sockets 12 arranged, with the pipe socket 12 flow-conducting with the first flow channel 5 are connected. Furthermore, the outer tube 3 on its front sides 13 with lids 14 is closed, with the lids 14 pipe connections 15 have, with the first flow channel 5 and the second flow channel 6 are connected. Both pipe sockets 12 as well as lids are cohesive with a line structure 4 or outer tube 3 connected.

7 shows the internal heat exchanger 1 in spatial representation. The internal heat exchanger 1 is tubular and has a heat transfer capacity of 600W with a diameter of 40mm and a length of 130mm (PLEASE CHECK). This makes the internal heat exchanger suitable 1 for integration into a mobile air conditioning system 2 ,

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 102007015186 A1 [0002]

Claims (18)

Internal heat exchanger ( 1 ) for an air conditioner ( 2 ), comprising an outer tube ( 3 ) and one within the outer tube ( 3 ) arranged line structure ( 4 ), the line structure ( 4 ) a first flow channel ( 5 ) and wherein between outer tube ( 3 ) and management structure ( 4 ) a second flow channel ( 6 ), characterized in that the first flow channel ( 5 ) is meander-shaped. Internal heat exchanger according to claim 1, characterized in that the first flow channel ( 5 ) has a serpentine shape. Internal heat exchanger according to claim 1, characterized in that the line structure ( 4 ) outside heat-conducting ribs ( 7 ) having. Internal heat exchanger according to claim 3, characterized in that the heat-conducting fins ( 7 ) to the area of the inner wall ( 8th ) of the outer tube ( 3 ). Internal heat exchanger according to one of claims 1 to 4, characterized in that the line structure ( 4 ) is formed in several parts. Internal heat exchanger according to one of claims 1 to 5, characterized in that the line structure ( 4 ) at least with heat-conducting ribs ( 7 ) provided trays ( 9 ), which via channel elements ( 10 ) are interconnected. Internal heat exchanger according to claim 6, characterized in that the channel elements ( 10 ) are comb-shaped, wherein the projections of the channel elements ( 10 ) form a series of parallel wall sections followed by semicircular wall sections. Internal heat exchanger according to claim 7, characterized in that the projection of the channel element is positioned between projections of the other channel element. Internal heat exchanger according to one of claims 1 to 8, characterized in that the elements ( 9 . 10 ) of the management structure ( 4 ) are formed of metallic material. Internal heat exchanger according to one of claims 1 to 9, characterized in that the elements ( 9 . 10 ) of the management structure ( 4 ) are cohesively connected to each other. Internal heat exchanger according to one of claims 1 to 10, characterized in that the line structure ( 4 ) in the outer tube ( 3 ) is inserted. Internal heat exchanger according to one of claims 1 to 11, characterized in that on the end faces ( 11 ) of the management structure ( 4 ) Pipe socket ( 12 ) are arranged, wherein the pipe socket ( 12 ) flow-conducting with the first flow channel ( 5 ) are connected. Internal heat exchanger according to one of claims 1 to 12, characterized in that the outer tube ( 3 ) at its end faces ( 13 ) each with a lid ( 14 ) is closed, the lids ( 14 ) Pipe connections ( 15 ), which communicate with the first flow channel ( 5 ) and the second flow channel ( 6 ) are connected. Internal heat exchanger according to one of claims 1 to 13, characterized in that the inner diameter of the outer tube ( 3 ) is between 25 mm and 35 mm. Internal heat exchanger according to one of claims 1 to 14, characterized in that the width of the first flow channel ( 5 ) is between 3.5 mm and 5.5 mm. Internal heat exchanger according to one of claims 1 to 15, characterized in that the first flow channel ( 5 ) has an at least partially rectangular cross-section. Internal heat exchanger according to one of claims 1 to 16, characterized in that the first flow channel ( 5 ) has a rectangular cross-section. Internal heat exchanger according to one of Claims 1 to 17, characterized in that it is intended for use in a mobile air conditioning system ( 2 ) is trained.

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