EP4105366A1 - Method for coating a heat exchanger - Google Patents

Abstract

The present invention relates to a method for coating a heat exchanger (1) by means of electrophoretic deposition, the heat exchanger (1) comprising a bundle (4) with tubular bodies (2) and corrugated fins (3). An improved coating as well as an increased service life and durability of the heat exchanger (1) are achieved in that at least one body (14) is provided in the bundle (4) that is different from the tubular bodies (2) and corrugated fins (3), which is electrically conductive and is electrically connected to at least one tubular body (2) and/or at least one corrugated fin (3), the body (14) being electrically connected to a potential of an associated system (18) during the electrophoretic deposition.

The invention also relates to such a heat exchanger (1).

Description

The present invention relates to a method for coating a heat exchanger by means of electrophoretic deposition, the heat exchanger having tubular bodies and corrugated fins. The invention also relates to a heat exchanger coated in this way.

Heat exchangers are used to transfer heat between two fluids. For this purpose, the two fluids flow through the heat exchanger, fluidically separated from one another. Heat transfer between the fluids takes place within the heat exchanger. In order to define and separate the flow paths of the fluids within the heat exchanger, one of the flow paths usually leads through tube bodies of the heat exchanger which are spaced apart from one another. The tubular bodies are also arranged at a distance from one another in the flow path of the other fluid. The other flow path thus leads between the tubular bodies. In order to improve the heat transfer between the fluids, heat transfer-increasing structures are usually provided in the cavities formed between the tubular bodies, which are also referred to below as corrugated fins. Such corrugated fins are in heat-transferring contact with at least one of the tubular bodies.

The tubular bodies and the corrugated fins are generally electrically conductive. This is due in particular to the fact that increased heat transfer is achieved by manufacturing the tube bodies and/or corrugated fins from metals or metal alloys.

The heat exchanger, in particular the tube body, and/or the corrugated fins can be damaged due to operational reasons and/or due to general conditions and/or due to aging. At least one of the fluids flowing through the heat exchanger can also lead to damage to the heat exchanger, in particular corrosion of the heat exchanger.

In order to avoid or at least reduce such damage to the heat exchanger, it is known to coat the heat exchanger, in particular the tube body and the corrugated fins, with a protective layer.

A simple method for coating the heat exchanger that is advantageous in series production is electrophoretic deposition. In this case, corners of the assembled heat exchanger are usually electrically connected to an electrode of an associated system, ie to a corresponding electrical potential. The system also has a counter-electrode, so that particles flowing between the electrodes are deposited on surfaces of the heat exchanger during operation. In particular, cathodic dip painting is known, in which the heat exchanger is immersed in a bath as a cathode.

In particular in the case of more complex geometric configurations of heat exchangers, the surfaces of the heat exchanger are not coated, or not sufficiently coated, at least locally. As a result, there is an increased risk of said damage during operation of the heat exchanger, in particular corrosion of the uncoated or insufficiently coated surfaces. These can lead to a reduction in the service life of the heat exchanger. Leaks can also occur, in particular due to corrosion, which can lead to a failure of the heat exchanger.

The present invention is therefore concerned with the task of specifying improved or at least different embodiments for a method for coating a heat exchanger of the type mentioned at the beginning and for such a heat exchanger, which are characterized in particular by an improved coating and/or an increased service life of the heat exchanger.

According to the invention, this object is achieved by the subject matter of the independent claims. Advantageous embodiments are the subject matter of the dependent claims.

However, the complex structure of the heat exchanger leads to a change, in particular a disruption, of the electric field lines, in particular of the electric potential, on the heat exchanger during the separation.

The present invention is based on the general idea of coating a heat exchanger by means of electrophoretic deposition, with additional electrical contacting options being created within the heat exchanger, which are connected to a corresponding electrical potential in an associated system for coating the heat exchanger.

Here, the knowledge is used that the complex structure of the heat exchanger leads to a change, in particular a disruption, of the electric field lines, in particular of the electric potential, on the heat exchanger during the separation. With the additional electrical connections, a more uniform, in particular more homogeneous, distribution of electric field lines and/or a reduced drop in the electric potential in the heat exchanger is achieved. As a result, the surfaces of the Heat exchanger completely and homogeneously coated during the deposition process or at least reduces the risk of locally reduced or absent deposits. With a simplified implementation of the separation, this results in an improved resistance of the heat exchanger, in particular to corrosion. This leads to an increased service life of the heat exchanger and to avoiding or at least reducing leakages that occur during operation.

According to the idea of the invention, the heat exchanger has tubular bodies that are spaced apart from one another, as well as structures that increase heat transfer and are arranged between the tubular bodies. These structures are advantageously designed as corrugated ribs and are therefore generally referred to below as corrugated ribs. The tubular bodies and the corrugated ribs form a package or network through which fluid can flow, this package or network also being referred to below as a bundle. The heat exchanger thus includes a bundle of the tube bodies and the corrugated fins. The bundle extends between two opposite end faces. This means that the bundle extends in a vertical direction, a transverse direction running transversely to the vertical direction and a longitudinal direction running transverse to the vertical direction and transverse to the transverse direction, with the bundle having two opposite end faces in the vertical direction, in the transverse direction and in the longitudinal direction. The bundle is coated in a system using electrophoretic deposition. For this purpose, the bundle in the system is electrically connected to an electrode of the system, ie to a corresponding electrical potential. Thus, the bundle is connected as the electrode at deposition. According to the invention, at least one electrically conductive body is provided in the bundle, which body extends from one of the end faces in the direction of the opposite end face. The body is of the tubular bodies and the corrugated fins different and electrically connected to at least one of the tubular bodies and/or the corrugated fins. In this case, the at least one body is electrically connected to the electrical potential.

The tubular bodies expediently delimit a flow path of a first fluid, which flows through the heat exchanger during operation. The arrangement of the tubular bodies at a distance from one another also delimits a flow path for a second fluid, which flows through the tubular body in a fluidically separated manner from the first fluid. The corrugated fins are therefore arranged in the second flow path and the second fluid can flow through them.

At least one of the at least one body, preferably the respective body, is expediently arranged outside of the tubular body and thus in the second flow path. In particular, the body extends through the bundle differently than the corrugated ribs.

The tubular bodies and the corrugated fins are expediently electrically conductive. In particular, the tubular bodies and the corrugated fins are made of a metal or a metal alloy, for example sheet metal.

The electrophoretic deposition preferably takes place in such a way that the coating is a protective coating for the tube body and the corrugated fins, in particular against corrosion.

In the case of electrophoretic deposition, the entire heat exchanger, ie not just the bundle including at least one body, is preferably electrically connected to the potential and serves as a corresponding electrode during the deposition. The entire heat exchanger is advantageously coated by means of electrophoretic deposition.

Embodiments are preferred in which the electrophoretic deposition is implemented as cathodic dip painting, the potential being set in such a way that the bundle, in particular the heat exchanger, is connected as a cathode. This leads to a simplified coating of the heat exchanger that is particularly suitable for series production.

The bundle, in particular the heat exchanger, can in principle have any shape.

The bundle, in particular the heat exchanger, is advantageously of cuboid design. This simplifies both the production and the use of the heat exchanger.

In preferred embodiments, at least one of the at least one body has an electrical connection on at least one of the end faces between which it extends. The body is electrically connected to the potential via this electrical connection.

The electrical connection is advantageously a thread. The method for coating the heat exchanger can thus be implemented in a simplified manner, with a stable and reliable electrical connection of the body to the potential being provided at the same time.

In principle, only one such body can be provided in the bundle.

It is also conceivable that the bundle is provided with two or more such bodies. In this case, the bodies are expediently spaced apart from one another. In addition, it is preferred if the bodies are parallel to one another get lost. This leads to an advantageous course of electrical field lines within the bundle and thus to an improved coating. In addition, the bodies can be electrically connected to the potential in a simplified manner in this way.

In principle, the respective body can have any shape.

It is preferred if at least one of the bodies, particularly preferably the respective body, extends in an elongate manner. The body can thus be electrically connected to the tubular bodies and/or corrugated fins over a greater distance. This results in an improved coating of the heat exchanger.

Embodiments are preferred in which at least one of the at least one body, advantageously the respective body, is designed or provided as a profile. In addition to an advantageous electrical connection over a long distance, this leads to a reduced weight of the heat exchanger.

In principle, at least one of the at least one body can only be provided for the electrophoretic deposition on the bundle and then removed.

Likewise, at least one of the at least one body can be an integral part of the bundle. This leads to a simplified coating and/or simplified manufacture of the heat exchanger.

It is preferred if at least one of the at least one body extends from one of the end faces to the opposite end face, that is to say essentially over the entire extent of the bundle between the end faces. In this way, improved electrical contact of the body with the implemented at least one tubular body and/or the at least one corrugated fin. This results in an improved coating of the heat exchanger.

The bundle, advantageously the heat exchanger, is expediently also electrically connected to the potential at points which are at a distance from the bodies and separate from the bodies.

This is advantageously done via at least one edge of the heat exchanger, which connects two consecutive end faces to one another. This results in an improved coating of the heat exchanger. The heat exchanger thus has edges connecting the end faces to one another, with at least one of the edges being electrically connected to the potential in addition to the at least one body.

In this case, embodiments are considered to be advantageous in which at least one electrical connection separate from the at least one body takes place via at least one corner of the heat exchanger. The respective edge thus extends from one corner of the heat exchanger to another corner, with at least one of the corners being electrically connected to the potential in addition to the at least one body. The coating can thus be implemented in a simplified manner. In addition, this results in advantageous electrical field lines within the heat exchanger and thus an improved coating.

Embodiments are preferred in which the system has a frame which serves as an electrode of the system. The bundle, in particular the heat exchanger, is electrically connected to the frame for coating. This results in a simplified and at the same time reliable coating of the heat exchanger.

In order to coat the heat exchanger, the frame can be moved through the system, in particular it can be immersed in a bath and pulled out of the bath.

Embodiments are preferred in which the heat exchanger is electrically connected to the frame with electrically conductive wires running between the heat exchanger, in particular the bundle, and the frame, the wires advantageously also keeping the heat exchanger floating in the frame. This means that the heat exchanger with the wires is arranged in a floating manner in the frame. The frame is expediently electrically conductive and electrically connected to the electrical potential, so it also serves as an electrode, so that the wires electrically connect the heat exchanger, in particular the bundle, to the potential.

It is advantageous if at least one of the at least one body is connected to an electrical conductor which is separate from the wires and which can also be in the form of a wire, the conductor also being electrically connected to the frame. As a result, the body is electrically connected to the potential via the conductor.

It goes without saying that, in addition to the method for coating the heat exchanger, a heat exchanger coated in this way also per se belongs to the scope of this invention.

In this case, the heat exchanger advantageously has at least one such body.

The heat exchanger can be used in any application in which heat transfer between two fluids is intended.

In particular, it is conceivable to use the heat exchanger in a circuit through which a coolant or refrigerant circulates during operation, with the coolant or refrigerant flowing through the heat exchanger via one of the flow paths and in the heat exchanger with another fluid, which flows through the other flow path flows through the heat exchanger, is tempered, ie cooled and/or heated. In particular, it is conceivable to use the heat exchanger in a motor vehicle.

Further important features and advantages of the invention result from the dependent claims, from the drawings and from the associated description of the figures with reference to the drawings.

It goes without saying that the features mentioned above and those still to be explained below can be used not only in the combination specified in each case, but also in other combinations or on their own, without departing from the scope of the present invention.

Preferred exemplary embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description, with the same reference numbers referring to identical or similar or functionally identical components.

Fig. 1

einen vereinfachten Schnitt durch einen Wärmeübertrager,

Fig. 2

eine isometrische, im Wesentlichen transparente Ansicht des Wärmeübertragers,

Fig. 3

eine isometrische, geschnittene Ansicht des Wärmeübertragers,

Fig. 4

eine isometrische Ansicht des Wärmeübertragers in einer Anlage zum Beschichten des Wärmeübertragers.

Show it, each schematically

1

a simplified section through a heat exchanger,

2

an isometric, essentially transparent view of the heat exchanger,

3

an isometric, sectional view of the heat exchanger,

4

an isometric view of the heat exchanger in a system for coating the heat exchanger.

A heat exchanger 1, as for example in the Figures 1 to 4 is shown, has a plurality of tubular bodies 2 spaced apart from one another, as well as structures 3 which are arranged between the tubular bodies 2 and increase the heat-transferring surface, which structures are also referred to below as corrugated fins 3 . The tubular body 2 and the corrugated fins 3 are only in this case figure 1 shown. The tubular body 2 and the corrugated fins 3 are part of a bundle 4 of the heat exchanger 1, which forms a network of the heat exchanger 1 through which a flow can flow. The tubular body 2 and the corrugated fins 3 are electrically conductive, for example made of a metal or a metal alloy, in particular sheet metal. In this case, a first flow path 5 for a first fluid leads through the tubular body 2 . Furthermore, a second flow path 6 for a second fluid is delimited between the tubular bodies 2 spaced apart from one another and is fluidically separated from the first flow path 5 . The corrugated fins 3 are arranged between the tubular bodies 2 and thus in the second flow path 6 and the second fluid flows through them during operation. at in figure 1 shown embodiment, the tubular body 2 parallel and are spaced from each other. at in figure 1 shown embodiment, the corrugated fins 3 are also arranged in parallel purely by way of example. The tubular body 2 and the corrugated fins 3 are each configured identically, purely by way of example.

The heat exchanger 1 can have other components in addition to the bundle 4 . In the embodiment of figure 1 the heat exchanger 1 includes, in addition to the bundle 4, two boxes 7 for distributing the through the tubular body 2 flowing fluid in the tubular body or collecting the fluid from the tubular bodies 2 on. The heat exchanger 1 and thus the bundle 4 extend in three mutually transverse directions 8, 9, 10, which are referred to below as the vertical direction 8, the transverse direction 9 and the longitudinal direction 10. The heat exchanger 1 and thus the bundle 4 have two opposite end faces 11 along the respective direction 8 , 9 , 10 . In the exemplary embodiment shown, the tubular bodies 2 extend in the longitudinal direction 10, purely by way of example.

How in particular figure 2 can be removed, the heat exchanger 1 of the illustrated embodiments is cuboid, the heat exchanger 1 in the figures 2 and 4 is shown in a greatly simplified manner with its outline as a cuboid. How in particular figure 2 can also be seen, adjacent end faces 11 are connected to each other via edges 12, the respective edge running between two associated corners 13.

As can be seen from the figures, bundle 4 has at least one electrically conductive body 14 that is different from tubular bodies 2 and corrugated fins 3 and extends from one of end faces 11 in the direction of opposite end face 11 . The respective body 14 is electrically connected to at least one tubular body 2 and/or at least one corrugated fin 3. In particular, the body 14 bears against at least one corrugated rib 3 and/or at least one tubular body 2 . In the exemplary embodiments shown, three such bodies 14 are provided purely by way of example, which are spaced apart from one another and run parallel, and which are of identical design purely by way of example. In the exemplary embodiments shown, the bodies 14 extend purely by way of example in the transverse direction 9 and further from one of the end faces 11 lying opposite in the transverse direction 9 to the opposite end face 11. The bodies 14 thus extend into the The respective body 14 is thus electrically connected to at least one tubular body 12 and/or at least one corrugated fin 3 over its entire extent running between the end faces 11. The body 14 preferably extends elongate, ie between the associated end faces 11 elongate. Advantageously, at least one of the bodies 14, preferably the respective body 14, is a profile 15.

In figure 2 a view can be seen in which only the outlines of the heat exchanger 1 can be seen, with the bodies 14 being shown inside the heat exchanger 1 .

figure 3 shows an isometric section through the heat exchanger 1 in the area of the body 14.

Like the one in particular Figures 1 and 2 can be removed, the body 14 of the embodiments shown are centered in the bundle 4 and spaced apart, arranged equidistantly in the embodiments shown. In the exemplary embodiments shown, the tubular bodies are arranged centrally in the bundle 4 in the vertical direction 8, extend in the transverse direction 9 over the entire extent of the bundle 4 and are arranged in the longitudinal direction 10, preferably equidistant from one another.

According to the invention, the heat exchanger 1 is coated by means of electrophoretic deposition. in the in figure 4 shown embodiment, this is done by cathodic dip painting. For this purpose, the heat exchanger 1 is connected to an electrode 17 functioning as a cathode 16 of a system 18 for coating the heat exchanger 1 . The system 18 also has an anode (not shown) as a counter-electrode. how figure 4 can be removed, in this case the bodies 14 are each electrically connected to the cathode 16 . how figure 4 can also be seen, the heat exchanger 1 is also electrically connected to the cathode 16 via points spaced apart from the bodies 14 . The heat exchanger 1 is thus connected overall to a corresponding electrical potential of the cathode 16 and thus functions as a cathode 16 during cathodic dip painting.

At the in figure 4 The embodiment shown is the electrical connection of the heat exchanger 1 to the cathode 16, which is additional to the bodies 14, via the edges 12, the electrical connection being realized at the corners 13 of the heat exchanger 1 in the embodiment shown. in the in figure 4 The exemplary embodiment shown is connected to the respective corner 13 via a wire 19 with the cathode 16 . In addition, the bodies 14 are electrically connected on at least one of the associated end faces 11, in the exemplary embodiment shown on one of the end faces 11, via an associated electrical conductor 20, which is different from the wires 19 and can also be a wire the cathode 16 connected. Thus, during electrophoretic deposition, in particular during cathodic dip painting, a corresponding electrical potential is established across the surfaces of the heat exchanger 1, which leads to advantageous electric field lines across the entire heat exchanger 1.

At the in figure 4 The embodiment shown has the system 18 on a frame 21 which is connected as an electrode 17, ie as a cathode 16 in the embodiment shown. The heat exchanger 1 is arranged hanging or floating in the frame 21 via the wires 19 .

As for example in the Figures 2 to 4 indicated, the respective body 14 in the exemplary embodiments shown has an electrical connection 22 , for example a thread 23 , on at least one of the end faces 11 . In this case, the electrical conductor 20 is connected to the electrical connection 22 . The body 14 is therefore in particular a profile 15 with a front connection 22, in particular a thread 23.

The method according to the invention and the heat exchanger 1 according to the invention thus result in a uniform and reliable coating of the heat exchanger 1. As a result, damage, in particular corrosion, of the heat exchanger 1 caused by a lack of coating is avoided or at least reduced. The service life of the heat exchanger 1 and the durability of the heat exchanger 1 are thus improved.

Claims (11)

Process for coating a heat exchanger (1), - wherein a heat exchanger (2) is provided, • wherein the heat exchanger (1) has a bundle (4) which runs in a vertical direction (8), in a transverse direction (9) running transversely to the vertical direction (8) and in a transverse direction to the vertical direction (8) and transverse to the transverse direction (9 ) running longitudinal direction (10) each having two opposite end faces (11), • wherein the bundle (4) has tubular bodies (2) spaced apart from one another and corrugated ribs (3) arranged between the tubular bodies (2) and connected to the tubular bodies (2) in a heat-transferring manner, - wherein the heat exchanger (1) is coated in a system (18) by electrophoretic deposition, - wherein the bundle (4) is electrically connected to an electrical potential in the system, so that the bundle (4) is connected as an electrode (17) during the deposition, characterized, - that at least one of the tubular bodies (2) and the corrugated ribs (3) and electrically conductive body (14) is provided in the bundle, which extends from one of the end faces (11) in the direction of the opposite end face (11) and electrically with is connected to at least one tubular body (2) and/or at least one corrugated fin (3), - That the at least one body (14) is electrically connected to the electrical potential. Method according to claim 1,
characterized,
that at least one of the at least one body (14) has an electrical connection (22) on at least one of the end faces (11), via which the body (14) is electrically connected to the potential. Method according to claim 2,
characterized,
that the bundle (4) is provided with at least two such bodies (14) which are spaced apart and parallel. Method according to one of claims 1 to 3,
characterized,
that at least one of the bodies (14) is provided in the bundle (4) in such a way that it extends from one end face (11) to the opposite end face (11) and over its entire extent between the end faces (11) with at least one tubular body (2) and/or at least one corrugated fin (3) is electrically connected. Method according to one of claims 1 to 4,
characterized,
that at least one such body (14) is provided in the bundle, which extends longitudinally between the end faces (11) and/or is designed as a profile (15). Method according to one of claims 1 to 5,
characterized, - that the heat exchanger (1) in the system is coated by cathodic dip painting, - That the potential is adjusted in such a way that the bundle (4) is connected as a cathode (16). Method according to one of claims 1 to 6,
characterized, - that the heat exchanger (1) has edges (12) connecting the end faces (11) to one another, - that at least one of the edges (12) is electrically connected to the potential in addition to the at least one body (14), - that the at least one body (14) is provided at a distance from the edges (12). Method according to claim 7,
characterized, - that the respective edge (12) extends from one corner (13) to another corner (13), - That at least one of the corners (13) is electrically connected to the potential. Method according to one of claims 1 to 8,
characterized , - the system (18) has a frame (21), - that the heat exchanger (1) is arranged floating in the frame (21) with electrically conductive wires (19) running between the heat exchanger (1) and the frame (21) and is electrically connected to the frame (21), - That the frame (21) is electrically conductive and electrically connected to the electrical potential, so that the wires (19) the Connect the heat exchanger (1) electrically to the potential. Method according to claim 9,
characterized,
that at least one of the at least one body (14) is connected to an electrical conductor (20) separate from the wires (19), the conductor (20) also being electrically connected to the frame (21) so that the body (14) is electrically connected to the potential via the conductor (20). Heat exchanger (1) which is coated according to a method according to any one of claims 1 to 10, wherein the heat exchanger (1) has at least one of the at least one body (14).

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