WO2016055458A1

WO2016055458A1 - Method for mounting a heat exchanger device and a heat exchanger device

Info

Publication number: WO2016055458A1
Application number: PCT/EP2015/073023
Authority: WO
Inventors: Uwe FÖRSTER; Wolfgang Geiger; Andreas König; Karl-Gerd Krumbach; David MAYOR-TONDA
Original assignee: Mahle International Gmbh
Priority date: 2014-10-08
Filing date: 2015-10-06
Publication date: 2016-04-14
Also published as: DE102014220403A1; US20170307262A1; EP3204709A1; EP3204709B1; CN106796064A; CN106796064B

Abstract

The invention relates to a method for mounting a heat exchanger device (16) of a refrigerating plant (10), wherein the heat exchanger device (16) comprises the following components: a housing (34), which has at least one cover (36) and a tubular shell (38), a heat exchanger coil (42), and a coolant collection container (32). Essential according to the invention is that the heat exchanger coil (42) is pushed over the coolant collection container (32) and fluidically connected to the at least one cover (36), that the tubular shell (38) is pushed over the heat exchanger coil (42), and that the tubular shell (38) is deformed radially inward. The invention further relates to a heat exchanger device (16) of a refrigerating plant (10) produced according to said method.

Description

Method for mounting a heat exchanger device and heat exchanger device

The invention relates to a method for mounting a heat exchanger device of a refrigeration system according to the preamble of claim 1. Furthermore, the invention relates to a heat exchanger device produced by this method.

Such heat exchanger devices are used in refrigeration systems, in particular in refrigeration systems of an air conditioning system, for example a vehicle air conditioning system. By using these heat exchanger devices, the efficiency of the refrigeration system, in particular when using CO ₂ (R744) as a refrigerant, can be improved. By means of the heat exchanger device, the low temperature level of the low-pressure region of the refrigeration circuit can be used to further cool the warmer refrigerant in the high-pressure region immediately after the gas cooler. In this case, the heat exchanger device can be combined with a refrigerant collecting container (accumulator). The integration of a heat exchanger coil with the refrigerant receiver in a component, however, is very complex and expensive.

From DE 10 2006 031 197 A1 an internal heat exchanger with accumulator for refrigerant circuits, in particular in motor vehicle air conditioners, known, comprising a housing of a pressure-bearing tubular cylinder jacket and a cover plate and a bottom plate, concentrically forming a gap in the housing arranged accumulator from a bad Heat conductive material, preferably made of plastic, for the liquid refrigerant at low pressure and a finned tube for the refrigerant at high pressure, which is helically arranged in the gap between the accumulator and the cylinder jacket. The cover plate and the bottom plate each have a connection plate Connections for refrigerant pipes, wherein in the accumulator a U-shaped suction tube with a steam inlet and a steam outlet for the refrigerant vapor and in the upper region of the accumulator a baffle device for the separation of the liquid and vapor phase of the refrigerant are provided. The steam inlet is protected from refrigerant liquid under the baffle device in the accumulator and the steam outlet outside the accumulator. The finned tube in turn is sealed at its ends via a thread in the cover plate and the bottom plate, whereby an internal heat exchanger with accumulator is to be provided, which can be produced cost-effectively.

The invention has for its object to provide a heat exchanger device that combines an internal heat exchanger with a refrigerant tank and their installation is simplified.

This object is achieved by the features of the independent claims. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the general idea to mount a housing of the heat exchanger device last, whereby the assembly of heat exchanger coil and refrigerant receiver is easier. In this case, the heat exchanger coil is pushed over the refrigerant collecting tank and fluidly connected to the at least one lid, pushed the rohrformige jacket over the heat exchanger coil and the rohrformige jacket deformed radially inwardly. Thereby, the assembly and the connection between the at least one lid and the heat exchanger coil are easy, since the rohrformige jacket of the housing does not obstruct access to the heat exchanger coil. Thus, the choice of the connection between heat exchanger coil and de min- at least not limited a lid. Furthermore, the connection of the refrigerant collecting tank to the at least one lid and to the heat exchanger coil is accordingly simplified.

It is advantageous if the housing of the heat exchanger device has two covers, the heat exchanger coil is pushed over the refrigerant receiver and fluidly connected to the two covers, the rohrformige jacket is pushed over at least one of the two covers and the heat exchanger coil, and then the rohrformige jacket radially to is deformed inside. By using two lids, the flow paths in the heat exchanger device can be simplified. After mounting the heat exchanger coil and the refrigerant collecting container with the two covers then the rohrformige jacket is pushed over at least one of the two covers and deformed radially inwardly. Thus, although the sheath must fit over at least one of the two lids, it may still have a smaller functional diameter after being deformed radially inwardly. Thus, according to the invention, the assembly of the heat exchanger device can be improved without affecting the function of the heat exchanger device.

An advantageous solution provides that the rohrformige jacket is deformed radially inwardly such that it rests against the heat exchanger coil. Because the tubular jacket rests against the heat exchanger coil, a helical sealing surface is formed, which delimits a, in particular helical, fluid channel between the refrigerant receiver and the tubular jacket. The helical fluid channel thereby extends the residence time in the heat exchanger device and thereby improves the heat exchange. A further advantageous solution provides that the tubular jacket is deformed radially inwardly hydraulically or pneumatically. In particular, a hydraulic or pneumatic deformation process causes a uniform force on the tubular shell and thus a uniform deformation process. Such a deformation process can be flexibly applied to different components, whereby tool costs can be reduced.

A particularly advantageous solution provides that the tubular jacket is deformed radially inwardly by means of a molding tool. By using a mold to deform the tubular shell, the deformation can be accurately controlled. In particular, it can be better ensured in this way that the tubular jacket rests against the heat exchanger coil, without damaging them.

An advantageous possibility provides that the tubular jacket is deformed more radially inwardly in the region of the heat exchanger coil than in the region of the lid. In this way, the advantages of the solution according to the invention can be exploited particularly favorable.

Another advantageous possibility provides that the tubular jacket is deformed more radially inward in the region of the heat exchanger coil than in the region of the at least one cover. In this way, the advantages of the solution according to the invention can be exploited particularly favorable.

A further advantageous possibility provides that before the sliding of the tubular jacket of the refrigerant collecting container is connected to the two lids. As a result, the advantages according to the invention can also be utilized in the connection of the refrigerant collecting container with the two lids. A favorable alternative provides that, prior to deforming the rohrformigen shell this is at least tightly connected to the at least one lid. In this way, the lid and the tubular jacket can form a fluid-tight housing. Furthermore, any type of connection between the cover and the rohrformigen coat can be used.

Another favorable alternative provides that prior to deforming the rohrformigen shell this is at least tightly connected to both lids. In this way, the two covers and the tubular jacket can form a fluid-tight housing. Furthermore, any type of connection between the two covers and the rohrformigen coat can be used.

An advantageous alternative provides that the tubular shell is at least tightly connected to the at least one cover by the deformation of the tubular jacket. As a result, the tubular jacket and the at least one cover form a fluid-tight housing, without having to provide further connection means.

A further favorable alternative provides that the tubular jacket is at least tightly connected to both lids by the deformation of the tubular jacket. As a result, the tubular jacket and the two covers form a fluid-tight housing, without having to provide any further connection means.

Furthermore, the object is achieved by a heat exchanger device of a refrigeration system with a housing having at least a lid and a rohrformigen jacket, with a heat exchanger coil and a refrigerant receiver, wherein the tubular jacket is connected to the at least one lid, and wherein the tubular jacket in one Rich between two ends of the tubular shell is at least unilaterally tapered. This configuration enables the heat exchanger device to be assembled according to the above method, so that the advantages of the method described above also extend to the heat exchanger device.

In the specification and the appended claims, "tapered in a region" is understood to mean that the article in this region has a smaller diameter, in particular inner diameter, than in any other region of the article.

An advantageous variant provides that an inner diameter of the tubular shell in a region between two axial ends of the tubular shell is smaller than an inner diameter of the tubular shell on at least one of the two axial ends of the tubular shell. This embodiment also enables the heat exchanger device to be mounted according to the above method, so that the advantages of the method described above also extend to the heat exchanger device.

Furthermore, it is favorable if the housing of the heat exchanger device has two covers, when the tubular jacket is connected to the two covers, and if the shell-shaped jacket is tapered at least on one side in a region between the two covers. This configuration enables a heat exchanger device with two lids to be assembled according to the above method, so that the advantages of the method described above also extend to the heat exchanger device. Furthermore, the above-mentioned embodiment of the heat exchanger device allows almost any type of connection between the rohrformigen coat and the two covers, since the junction is easily accessible.

A further advantageous variant provides that the inner diameter of the tubular jacket in a region between two axial ends of the tubular jacket is smaller than the inner diameter of the tubular jacket at both axial ends of the tubular jacket. This embodiment also makes it possible to mount a heat exchanger device with two lids in accordance with the above method, so that the advantages of the method described above also extend to the heat exchanger device.

A favorable solution provides that the tubular jacket is in contact with at least one of the two covers or with the at least one cover exclusively with an inner side of the tubular jacket. In this way, on the one hand, the corresponding lid can be made simpler. On the other hand, the outside of the rohrformigen coat can be carried out regardless of restrictions by the connectability to the lid. Thus, costs can be saved.

A particularly favorable possibility provides that a refrigerant or a heat exchanger fluid, in particular under high pressure, is passed through the heat exchanger coils, and that the heat exchanger coil surrounds the refrigerant receiver at least in sections in a helical manner. Thereby, a second fluid passage, which is different from the fluid passage within the heat exchanger coil, is formed. In particular, this fluid passage is formed between the refrigerant receiver and the tubular jacket. Due to the helical course of the heat exchanger coil has this Fluid passage also a helical course. So that the heat exchanger coil and this fluid passage are guided within the heat exchanger unit a relatively long distance to each other. Thereby, heat can be exchanged particularly well between the fluid flowing in the heat exchanger coil and fluid flowing in the fluid passage.

A favorable possibility provides that the at least one cover or both covers have an outer diameter which is larger than an inner diameter of the tubular shell in a region between axial ends of the tubular shell. As a result, the two covers have a large cross-sectional area that can be used to attach refrigerant inlets and outlets and / or attachment means.

A particularly advantageous alternative provides that at least one of the two covers has an outer diameter which is smaller than an inner diameter of the tubular jacket before deforming the same. Thereby, the rohrformige jacket can be pushed over this cover, so that it is possible first to connect the heat exchanger coil, the refrigerant tank and the two covers together and then postpone the tubular jacket and connect with the remaining components.

It is particularly advantageous if the heat exchanger device has been mounted according to the method described above. The advantages of the method are thus transferred to the heat exchanger device, to the above description of which reference is made. Other important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated figure description with reference to the drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be described in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

It show, each schematically

1 is a schematic diagram of a refrigeration system,

2 is a sectional view through a heat exchanger device during assembly and before a tubular jacket is pushed,

3 shows a sectional view of the heat exchanger device from FIG. 2, with the tubular jacket pushed on,

4 shows a sectional view of the heat exchanger device from FIG. 3 after a deformation of the tubular jacket, FIG. 5 is a sectional view of the heat exchanger device with arrows for identifying the refrigerant flow,

Fig. 6 is a perspective view of a heat exchanger coil

Fig. 7 is an illustration of two possible cross-sections of a tube of

Heat exchanger coil and

8 shows an illustration of two further possible cross sections of a tube of the heat exchanger coil.

A refrigeration system 10 shown schematically in FIG. 1 comprises a compressor 12, a gas cooler 14, a heat exchanger device 16, a throttle or an expansion valve 18 and an evaporator 20. The refrigeration system 10 operates on the known principle of the refrigeration cycle. A refrigerant 22 passes through a circuit 28 which is driven by the compressor 12. First, the refrigerant 22 is compressed in the compressor 12, whereby the temperature of the refrigerant 22 increases. From the compressor 12, the refrigerant 22 is passed into the gas cooler 14, where it can give off heat due to the increased by the compression temperature heat to the environment. From the gas cooler 14, the refrigerant 22 is passed, via an internal heat exchanger 30, to the throttle / expansion valve 18, which throttles the flow of the refrigerant 22 and separates a low pressure area 24 from a high pressure area 26. After the throttle / expansion valve 18, the refrigerant 22 flows into the evaporator 20, in which it expands and thereby cools. Due to the fact that the refrigerant 22 in the high-pressure region 26 can deliver heat to the environment, the temperature of the refrigerant 22 in the evaporator 20 is lower than it was when the refrigerant 22 entered the compressor 12. The evaporator 20 has a second flow path for a medium to be cooled. medium, such as air, so that the refrigeration system 10 can absorb heat from the medium to be cooled. Downstream of the evaporator 20, a refrigerant collecting tank 32 is arranged, from which the refrigerant 22 is conducted to the compressor 12 via the internal heat exchanger 30. The refrigeration system 10 is used for example in air conditioning systems of motor vehicles.

Due to its lower greenhouse activity compared to other refrigerants, the refrigerant used is 22 CO ₂ (R744). In particular, when using CO ₂ as the refrigerant 22, the use of the internal heat exchanger 30 is favorable for the efficiency of the refrigeration system 10. About the inner heat exchanger 30 is heat from the refrigerant 22 in the high-pressure region 26, in particular downstream of the gas cooler 14, to the refrigerant 22 in the low pressure region 24, in particular downstream of the throttle / expansion valve 18 transmitted. Thereby, the temperature of the refrigerant 22 at the / the throttle / expansion valve 18 can be further reduced, so that the efficiency of the refrigeration system 10 improves.

For this purpose, the refrigeration system 10, the heat exchanger device 16 according to the invention, which includes the inner heat exchanger 30 and the refrigerant collecting tank 32. Both are arranged in a housing 34 which has at least one, for example two, cover 36 and a tubular jacket 38. Within the housing 34 extend two fluid channels. A first fluid idkanal 40 is formed by the inner heat exchanger 30, in particular by a heat exchanger coil 42 of the inner heat exchanger 30. A second fluid channel 44 extends within the housing 34 and thereby passes through the refrigerant collecting tank 32 and through a region between the refrigerant collecting tank 32 and the tubular shell 38. In this area also runs the heat exchanger coil 42 of the inner heat exchanger 30 (see FIG. 5). The two fluid channels 40, 44 are connected such that in the region between the refrigerant collecting tank 32 and the tubular jacket 38, the two fluid channels 40, 44 are traversed in countercurrent, and so the heat can be transmitted from the one fluid channel to the other fluid channel particularly effective ,

For example, the first fluid channel 40 and thus the heat exchanger coil 42 are flowed through by refrigerant 22 coming from the high-pressure region 26 from the gas cooler 14, while the second fluid channel 44 is flowed through by refrigerant 22 from the low-pressure region 24 coming from the evaporator 20 or the refrigerant receiver 32. Thus, the heat of the refrigerant 22 may be discharged from the high-pressure region 26 to the refrigerant 22 on the low-pressure side.

The heat exchanger coil 42 extends at least in sections helically through the housing 34 of the heat exchanger device 16. In particular, the heat exchanger coil 42 extends helically in a cylindrical jacket-shaped region between the refrigerant receiver 32 and the tubular jacket 38. Preferably, the heat exchanger coil 42 is applied to the tubular jacket 38, so that a helical sealing surface between the heat exchanger coil 42 and the tubular jacket 38 is formed.

The heat exchanger coil 42 thereby surrounds the refrigerant receiver 32. The heat exchanger coil 42 may also abut against the refrigerant receiver 32 so that the second fluid channel 44 extends helically between the refrigerant receiver 32 and the tubular jacket 38 and thus has a long length and the refrigerant 22 relatively has a lot of time to absorb heat from the heat exchanger coil 42. Alternatively, a distance between the heat exchanger coil 42 and the cooling consist medium container 32. Thereby, the second fluid passage 44 is not made helical in the area between the refrigerant receiver 32 and the tubular jacket 38, however, the heat exchanger coil 42 generates the ribbed or corrugated surface so that the fluid 22 when swirling through the second fluid passage 44 is swirled and thereby can absorb effective heat from the heat exchanger coil 42. This second variant has a lower flow resistance than the first variant. However, the thermal coupling between the second fluid channel 44 and the first fluid channel 40 is correspondingly lower. It is possible to optimally adapt the heat coupling and flow resistance to the respective requirements.

The heat exchanger coil 42 is connected to refrigerant connections in the lids 36. So that the refrigerant 22 can be passed through the refrigerant ports in the lids 36 through the heat exchanger coil 42.

The heat exchanger coil 42, as shown for example in Fig. 6, 7 and 8, have different cross sections, in particular, the heat exchanger coil 42 may have circular, oval or elliptical cross sections. Alternatively or additionally, the heat exchanger coil 42 may also have a relatively flat profile with a plurality of smaller individual channels 50 within the heat exchanger coil 42.

The refrigerant receiver 32 serves to trap and collect gaseous or liquid refrigerant 22 from the refrigerant gas flow, thus forming a kind of cold reservoir. For this purpose, the refrigerant collecting tank 32 has a cylindrical base body, through which the refrigerant 22 is introduced from the evaporator 20 approximately axially. On the same side there is another opening through which the gaseous refrigerant 22 which can flow out of the refrigerant collecting tank 32. As a result, after flowing into the refrigerant collecting tank 32, the refrigerant 22 must pass through an arc through which liquid or solid portions of the refrigerant 22 are separated.

Accordingly, the refrigerant receiver 32 is connected to at least one of the lids 36 so that refrigerant 22 can flow through a refrigerant inlet in the refrigerant receiver 32.

The assembly of the refrigerant collecting tank 32 and the heat exchanger coil 42 to the lid 36 would be difficult if the tubular shell 38 would be already connected to one of the cover 36. For this reason, the tubular shell 38 is formed so that it can be mounted as the last part of the heat exchanger device 16.

Thereby, the connection between the covers 36 and refrigerant collecting tank 32 and the connection between the covers 36 and the heat exchanger coil 42 can be made very simple, so that also favorable and / or otherwise particularly advantageous connection possibilities can be applied. In particular, there is no restriction on the type of connection between the covers 36 with the heat exchanger coil 42 and with the refrigerant receiver 32.

The tubular jacket 38 initially has an inner diameter 46 which is larger than an outer diameter 48 of the cover 36 (see FIG. 3). As a result, the tubular jacket 36 can be pushed over the two covers 36. It is sufficient if the tubular jacket 38 is slidable only about one of the two covers 36. Consequently, one of the two covers 36 a Outer diameter 48 which is greater than the inner diameter 46 of the tubular shell 38th

Alternatively or additionally, an embodiment of the heat exchanger device 16 with only one lid, which has all the necessary refrigerant connections, and a tubular jacket 38 which is closed on one side. It is sufficient if the inner diameter 46 of the tubular jacket 38 is greater than an outer diameter of the heat exchanger coil 42, so that the raw-shaped jacket 38 can be pushed over the heat exchanger coil 42 and on the cover 36.

Since the tubular jacket 38 is intended to be in contact with the heat exchanger coil 42, the tubular jacket 38 is deformed radially inward after being pushed onto the heat exchanger device 16 (see FIG. 4). As a result of this radial deformation process, the tubular jacket 38 can also be connected to the lids 36 in a fluid-tight manner. Alternatively, the tubular jacket 38 may also be connected to the covers 36 prior to the radial deformation process.

The radial deformation of the tubular jacket 38 can be achieved for example by hydraulic or pneumatic pressure, which is applied from the outside to the tubular jacket 38. Alternatively or additionally, the radial deformation of the tubular shell 38 can be effected by a molding tool.

By this sequence of assembly, the connection of the cover 36 with the heat exchanger coil 42 and the refrigerant collecting tank 32 is not disturbed by the tubular jacket 38 and facilitates the installation of the heat exchanger device 16 considerably. After radially deforming the tubular shell 38, the inner diameter 46 of the tubular shell 38 is reduced in a region 45 between two axial ends 47 of the tubular shell 38. As a result, the tubular jacket 38 can rest against the heat exchanger coil 42. The diameter 48 of the at least one cover 36 is greater than the diameter of the heat exchanger coil 42. Consequently, the inner diameter 46 of the tubular jacket 38 is greater at the axial ends 47 than in the region 45 between the axial ends 47.

Claims

claims

1 . Method for mounting a heat exchanger device (16) of a refrigeration system (10), wherein the heat exchanger device (16) comprises the following components; a housing (34) having at least one cover (36) and a tubular jacket (38), a heat exchanger coil (42) and a refrigerant receiver (32),

characterized in that

- The heat exchanger coil (42) is pushed over the refrigerant collecting container (32) and fluidly connected to the at least one lid (36),

- The tubular jacket (38) is pushed over the heat exchanger coil (42) and

- The tubular jacket (38) is deformed radially inwardly.

2. The method according to claim 1,

characterized in that

the housing (34) of the heat exchanger device (16) has two covers (36),

- The heat exchanger coil (42) is pushed over the refrigerant collecting container (32) and fluidly connected to the two covers (36),

- The tubular jacket (38) over at least one of the two covers (36) and the heat exchanger coil (42) is pushed, and thereon

- The tubular jacket (38) is deformed radially inwardly.

3. The method according to claim 1 or 2,

characterized in that

the tubular shell (38) is deformed radially inwardly so as to abut the heat exchanger coil (42).

4. The method according to any one of claims 1 to 3,

characterized in that

the tubular jacket (38) is deformed radially inwardly hydraulically, pneumatically or by means of a forming tool.

5. The method according to any one of claims 1 to 4,

characterized in that

the tubular jacket (38) is deformed more radially inward in the region of the heat exchanger coil (42) than in the region of the at least one cover or the cover (36).

6. The method according to any one of claims 1 to 5,

characterized in that

- The tubular shell (38) is at least tightly connected to both covers (36) or the at least one cover (36) before deformation, or

- The tubular jacket (38) during deformation at least tightly connected to both covers (36) or the at least one cover (36).

7. heat exchanger device of a refrigeration system (10) having a housing (34) with at least one cover (36) and a tubular jacket (38), a heat exchanger coil (42) and with a refrigerant collecting container (32), characterized

- That the tubular jacket (38) is connected to the at least one cover (36), - That the tubular jacket (38) is tapered at least on one side in a region between two ends of the tubular jacket (38).

8. Heat exchanger device according to claim 7,

characterized,

an inner diameter (46) of the tubular jacket (38) in a region (45) between two axial ends (47) of the tubular jacket (38) is smaller than an inner diameter (46) of the tubular jacket (38) on at least one of the two axial ends (47) of the tubular jacket (38).

9. Heat exchanger device according to claim 7 or 8,

characterized,

- That the housing (34) of the heat exchanger device (16) has two covers (36),

- That the tubular jacket (38) with the two covers (36) is connected, and

- That the raw-shaped jacket (36) is tapered in at least one side in an area between the two covers (36).

10. heat exchanger device according to 9,

characterized,

in that the inner diameter (46) of the tubular jacket (38) in a region (45) between two axial ends (47) of the tubular jacket (38) is smaller than the inner diameter (46) of the tubular jacket (38) at both axial ends (38). 47) of the tubular jacket (38).

1 1. Heat exchanger device according to one of claims 7 to 10,

characterized, in that the tubular jacket (38) is in contact with the at least one or at least one of the two covers (36) exclusively with an inner side of the tubular jacket (38).

12. Heat exchanger device according to one of claims 7 to 1 1,

characterized,

in that a refrigerant (22) or a heat exchanger fluid, in particular under high pressure, flows in the heat exchanger coil (42),

- That the heat exchanger coil (42) at least partially helically surrounds the refrigerant collecting container (32).

13. Heat exchanger device according to one of claims 7 to 12,

characterized,

the at least one cover (36) or both covers (36) have an outer diameter (48) which is greater than an inner diameter (46) of the tubular jacket (38) in a region (45) between the axial ends (47) of the tubular jacket (38).

14. Heat exchanger device according to one of claims 7 to 13, which was mounted by the method according to one of claims 1 to 6.