FR2815895A1 - METHOD FOR MANUFACTURING A COPPER PLATE HEAT EXCHANGER, AND HEAT EXCHANGER OBTAINED BY THIS PROCESS - Google Patents

Abstract

The invention concerns a method for making a plate heat exchanger comprising a plurality of copper elements defining circuits for water circulation and assembled together by soldering. Said soldering results in the formation of a copper-silver-phosphorus solder. The invention is applicable to evaporators/condensers of air separating appliances.

Description

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 The invention relates to the field of heat exchangers manufactured by assembling copper plates.

 For several decades, the vaporizers / condensers of air separation devices have generally been made of aluminum or aluminum alloy by means of plates brazed together. They can also be made of various other brazable metals, in particular copper.

These exchangers generally consist of two or more circuits, defined by the configuration of the plates which constitute them, and possible elements for separating the plates such as heat exchange waves, which the exchanger can contain. The various fluid circulation circuits are connected to the rest of the installation by means of a system of pipes welded to the exchanger.

 The exchangers made from copper plates are generally assembled by brazing using a copper-silver eutectic alloy containing about 70% silver and 30% copper. Due to the very high proportion of silver contained by this eutectic alloy and the quantity of alloy required, this practice is very expensive. In addition, the high proportion of silver in the brazing alloy implies the realization of this brazing in a vacuum oven to avoid oxidation which would compromise the quality of the brazing.

 The object of the invention is to provide manufacturers of copper plate heat exchangers with an assembly method by brazing which is less costly than the conventional assembly method using copper-silver eutectic alloy.

 To this end, the subject of the invention is a method of manufacturing a plate heat exchanger of the type comprising a plurality of copper elements defining circuits for the circulation of fluids and assembled together by brazing, characterized in what said brazing results in the formation of a copper-silver-phosphorus brazing.

 Said brazing can be carried out after a step of depositing on the areas to be brazed a copper-based powder containing 4 to 16% silver and 4 to 8% phosphorus mixed with a binder.

 It can also be carried out after a step of depositing, on the zones of the plates to be brazed, sheets of a copper-based alloy containing 4 to 16% silver and 4 to 8% phosphorus.

 Said sheets can be co-laminated with said plates before said brazing.

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 Said brazing can also be carried out after a deposition step on the areas to be brazed with a layer of silver and a layer of phosphorus or a copper-phosphorus alloy separated. Said layers of silver and phosphorus or of copper-phosphorus alloy are then deposited in the form of sheets on said plates, and can be co-laminated with said plates before said brazing.

 Said layer of copper-phosphorus alloy can also be deposited in the form of sheets, and said silver layer can also be deposited electrolytically on said sheets. In these cases, the first step is to deposit on said plates sheets of phosphorus or copperphosphorus alloy and secondly the electrolytic deposition of silver on said sheets, or an electrolytic deposition of silver is successively carried out on sheets. of copper-phosphorus alloy and the deposition of said sheets on said plates.

 A co-laminating of said plates and of said sheets can be carried out before or after the electrolytic deposition of silver on said sheets.

 Said brazing can take place in an oven exposed to air, or in a vacuum oven.

 The invention also relates to a plate heat exchanger of the type comprising a plurality of copper plates defining circuits for the circulation of fluids and assembled together by brazing, characterized in that it is capable of being obtained by the previous process.

 As will be understood, the invention consists in obtaining, at the end of the brazing operation, a solder no longer based solely on copper and silver, but a solder based on a copper-silver-phosphorus alloy. This type of brazing provides as good results as the brazing usually performed with the copper-silver eutectic, and the lower silver content of the brazing alloy makes it possible to perform brazing in air. We can do without vacuum furnaces usually used in this kind of process.

 There is therefore no longer any obstacle to the use of large-size brazing ovens exposed to air, when it is desired to assemble exchangers with copper plates having a large volume.

 The preparatory operations for producing the solder itself can, according to the invention, be carried out according to different methods which will now be detailed.

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 The first method consists of depositing on the areas to be brazed a copper-based powder, containing 4 to 16% silver and 4 to 8% phosphorus, mixed with a binder. This powder must have a particle size suitable for its deposition by industrial processes, such as deposition by means of a gun. This particle size is, for example, 45 μm. The powder is most often deposited directly on the copper plates, but it can also be deposited on the heat exchange waves, when the exchanger contains them and they are placed between the plates before brazing.

 Instead of depositing the brazing alloy on plates by means of a powder, this deposition can also be carried out by applying to the areas to be brazed a copper-phosphorus-silver alloy having a composition similar to that of the powder which the 'we just quoted. This application can be carried out by depositing sheets of such an alloy, of thickness 100 μm.

After depositing these sheets, it is advantageous for the good performance of the assembly to carry out a co-laminating of the plates and sheets before carrying out the assembly of the exchanger and the actual brazing operation. This co-lamination can be carried out in one or more stages, the first of these stages being able to be carried out hot.

 Another method of implementing the invention can also consist either of depositing a homogeneous brazing material containing both copper, silver and phosphorus, but of depositing these elements separately. Their mixing takes place during the soldering operation itself, so as to obtain a solder having the desired composition.

Thus, one can deposit, on the areas to be brazed, successively a layer of silver and a layer of copper-phosphorus alloy, or even only a layer of silver and a layer of phosphorus, expecting that the copper of the plate will provide itself the amount of copper needed in the solder during brazing.

 According to a first variant of this implementation of the invention, both the silver layer and the phosphorus or copperphosphorus alloy layer are successively deposited in the form of sheets on the copper plates. Again, it is possible to carry out a co-laminating of these sheets on said plates prior to the soldering operation itself.

 According to another variant of this embodiment of the invention, the silver layer is no longer deposited in the form of sheets,

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 but in the form of an electrolytic deposit. For this purpose, one proceeds first to the deposition of copper-phosphorus alloy sheets on the copper plates, and then to the electrolytic deposition of silver on said sheets. As a variant, it is also possible to electrolytically deposit silver on said sheets prior to depositing these sheets on the copper plates. Again, on all the deposits made, a co-laminating of the deposits and copper plates can be carried out before the brazing is carried out. The main advantage of electrolytic silver deposition is that it makes it possible to obtain a thickness of the deposit that is both small and regular, which makes it possible to minimize the amount of silver used.

 The brazing is carried out by introducing the assembled exchanger into an oven at a temperature of 830 to 840oC which can be evacuated as in the prior art, but which can also be maintained simply under a normal ventilated atmosphere. The relatively low silver content of the brazing material is, in fact, not sufficient to compromise the quality of the brazing if an oxidation phenomenon occurs.

 The invention is applicable to any type of exchanger with copper plates assembled by brazing, whatever its application, the vaporizerscondensers of air separation devices being only one preferred example of application.

Claims (15)

 CLAIMS 1. Method for manufacturing a plate heat exchanger, of the type comprising a plurality of copper elements defining circuits for the circulation of fluids and assembled together by brazing, characterized in that said brazing has for consequently the formation of a copper-silver-phosphorus solder.  2. Method according to claim 1, characterized in that said brazing is carried out after a step of depositing on the areas to be brazed a copper-based powder containing silver and phosphorus mixed with a binder.  3. Method according to claim 2, characterized in that said powder contains from 4 to 16% of silver and from 4 to 8% of phosphorus.  4. Method according to claim 1, characterized in that said brazing is carried out after a step of depositing on the areas of the plates to be brazed with sheets of a copper-based alloy containing 4 to 16% silver and 4 8% phosphorus.  5. Method according to claim 4, characterized in that said sheets are colaminated with said plates before said brazing.  6. Method according to claim 1, characterized in that said brazing is carried out after a deposition step on the areas to be brazed with a layer of silver and a layer of phosphorus or a copper-phosphorus alloy separated.  7. Method according to claim 6, characterized in that said layers of silver and phosphorus or copper-phosphorus alloy are deposited in the form of sheets on said plates.  8. Method according to claim 7, characterized in that said sheets are colaminated with said plates before said brazing.  9. The method of claim 6, characterized in that said layer of copper-phosphorus alloy is deposited in the form of sheets, and in that said silver layer is deposited electrolytically on said sheets.  10. Method according to claim 9, characterized in that firstly the deposition on said plates of phosphor or copper-phosphorus alloy sheets and secondly the electrolytic deposition of silver on said sheets.  11. Method according to claim 9, characterized in that an electrolytic deposition of silver is successively carried out on copper-phosphorus alloy sheets and the deposition of said sheets on said plates. <Desc / Clms Page number 6>  12. Method according to one of claims 9, 10 or 11, characterized in that the deposition of said sheets is carried out on said plates, and in that a co-rolling of said plates and of said leaves is carried out before or after electrolytic deposition of silver on said sheets.  13. Method according to one of claims 1 to 12, characterized in that said brazing takes place in an oven exposed to air.  14. Method according to one of claims 1 to 12, characterized in that said brazing takes place in a vacuum oven.  15. Plate heat exchanger of the type comprising a plurality of copper plates defining circuits for the circulation of fluids and assembled together by brazing, characterized in that it is capable of being obtained by the process according to the invention. 'one of claims 1 to 14.